ENDONUCLEASE SYSTEMS

SEQUENCE LISTING

The instant application contains a Sequence Listing which has been submitted electronically in XML format and is hereby incorporated by reference in its entirety. Said XML copy, created on May 20, 2024, is named 55921-741.301 Sequence Listing.xml and is 1,897,990 bytes in size.

BACKGROUND

Cas enzymes along with their associated Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) guide ribonucleic acids (RNAs) appear to be a pervasive (˜45% of bacteria, ˜84% of archaea) component of prokaryotic immune systems, serving to protect such microorganisms against non-self nucleic acids, such as infectious viruses and plasmids by CRISPR-RNA guided nucleic acid cleavage. While the deoxyribonucleic acid (DNA) elements encoding CRISPR RNA elements may be relatively conserved in structure and length, their CRISPR-associated (Cas) proteins are highly diverse, containing a wide variety of nucleic acid-interacting domains. While CRISPR DNA elements have been observed as early as 1987, the programmable endonuclease cleavage ability of CRISPR/Cas complexes has only been recognized relatively recently, leading to the use of recombinant CRISPR/Cas systems in diverse DNA manipulation and gene editing applications. Owing to the utility of these enzymes, they are being repurposed for a wide variety of biotechnology, gene editing, and therapeutic applications. Due to their single-effector architecture, the majority of systems currently being repurposed for genome engineering belong to the CRISPR Class 2 category.

SUMMARY

The large size (greater than ca. 1200 amino acids) of many class 2 Cas effectors makes delivery for therapeutic applications challenging. Accordingly, described herein are methods, compositions, and systems relating to novel putative guided dsDNA nucleases referred to as SMART (SMall ARchaeal-associaTed) nuclease systems. These endonuclease effectors are defined by their small size (about 400 aa to about 1050 aa), the presence of RuvC and HNH catalytic domains, and other predicted protein features that together suggest novel biochemical mechanisms.

In some aspects, the present disclosure provides for an engineered nuclease system, comprising: (a) an endonuclease comprising a RuvC domain and an HNH domain, wherein the endonuclease is derived from an uncultivated microorganism; and (b) an engineered guide ribonucleic acid structure configured to form a complex with the endonuclease comprising: (i) a guide ribonucleic acid sequence configured to hybridize to a target deoxyribonucleic acid sequence; and (ii) a ribonucleic acid sequence configured to bind to the endonuclease; wherein the endonuclease has a molecular weight of about 96 kDa or less, about 80 kDa or less, about 70 kDa or less, or about 60 kDa or less, and wherein: (1) the endonuclease comprises an arginine rich region or a domain with PF14239 homology with at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to an arginine rich region or a domain with PF14239 homology from any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof; (2) the endonuclease comprises a REC domain with at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to a REC domain from any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof; or (3) the endonuclease comprises a sequence with at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof. In some embodiments, (1) the endonuclease comprises an arginine rich region or a domain with PF14239 homology with at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to an arginine rich region or a domain with PF14239 homology from any one of SEQ ID NOs: 674-675, 975-1002, or 1260-1321, or a variant thereof; (2) the endonuclease comprises a REC domain with at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to a REC domain from any one of SEQ ID NOs: 674-675, 975-1002, or 1260-1321, or a variant thereof; or (3) the endonuclease comprises a sequence with at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity sequence identity to any one of SEQ ID NOs: 674-675, 975-1002, or 1260-1321, or a variant thereof. In some embodiments, the endonuclease is an Archaeal endonuclease. In some embodiments, the endonuclease comprises a sequence with at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321. In some embodiments, the endonuclease further comprises an arginine-rich region comprising an RRxRR motif or a domain with PF14239 homology. In some embodiments, the arginine rich region or the domain with PF14239 homology has at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to the arginine rich region or the domain with PF14239 homology of any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321. In some embodiments, the endonuclease further comprises a REC (recognition) domain. In some embodiments, the REC domain has at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to a REC domain of any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321. In some embodiments, the endonuclease further comprises a BH (bridge helix) domain, a WED (wedge) domain, or a PI (PAM interacting) or TI (TAM interacting) domain. In some embodiments, the WED domain, or the PI domain has at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to a BH domain, a WED domain, or a PI domain of any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321.

In some aspects, the present disclosure provides for an engineered nuclease system comprising: (a) an endonuclease comprising a RuvC-I domain and an HNH domain; and (b) an engineered guide ribonucleic acid structure configured to form a complex with the endonuclease comprising: (i) a guide ribonucleic acid sequence configured to hybridize to a target deoxyribonucleic acid sequence; and (ii) a ribonucleic acid sequence configured to bind to the endonuclease, wherein the endonuclease comprises a sequence with at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 674-675, 975-1002, 1260-1321, or a variant thereof. In some embodiments, the endonuclease is an archaeal endonuclease. In some embodiments, the endonuclease further comprises an arginine-rich region comprising an RRxRR motif or a domain with PF14239 homology. In some embodiments, the arginine rich region or the domain with PF14239 homology has at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to an arginine rich region of any one of SEQ ID NOs: 674-675, 975-1002, 1260-1321. In some embodiments, the endonuclease further comprises a REC (recognition) domain. In some embodiments, the REC domain having at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to a REC domain of any one of SEQ ID NOs: 674-675, 975-1002, 1260-1321. In some embodiments, the endonuclease further comprises a BH domain, a WED domain, and a PI domain. In some embodiments, the BH domain, the WED domain, or the PI domain has at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to a BH domain, a WED domain, or a PI domain of any one of SEQ ID NOs: 674-675, 975-1002, 1260-1321. In some embodiments, the endonuclease is derived from an uncultivated microorganism. In some embodiments, the ribonucleic acid sequence configured to bind the endonuclease comprises a sequence with at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 199-200, 460-461, or 669-673, or a sequence with at least 80% sequence identity to the non-degenerate nucleotides of any one of SEQ ID NOs: 201-203, 613-616, 677-686, 1003-1022, or 1231-1259. In some embodiments, the guide nucleic acid structure comprises a sequence with at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to the non-degenerate nucleotides of any one of SEQ ID NOs: 201-203, 613-616, 677-686, 1003-1022, or 1231-1259.

In some aspects, the present disclosure provides for an engineered nuclease system comprising, (a) an engineered guide ribonucleic acid structure comprising: (i) a guide ribonucleic acid sequence configured to hybridize to a target deoxyribonucleic acid sequence; and (ii) a ribonucleic acid sequence configured to bind to an endonuclease, wherein the ribonucleic acid sequence comprises a sequence with at least 80% sequence identity to any one of SEQ ID NOs: 199-200, 460-461, or 669-673, or a sequence with at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to nonvariable nucleotides of any one of SEQ ID NOs: 677-686, 1006-1012, or 1231-1259; and (b) an RNA-guided endonuclease configured to bind to the engineered guide ribonucleic acid. In some embodiments, the RNA-guided endonuclease is an Archaeal endonuclease. In some embodiments, the endonuclease has a molecular weight of about 120 kDa or less, 100 kDa or less, 90 kDa or less, or 60 kDa or less. In some embodiments, the engineered guide ribonucleic acid structure comprises at least two ribonucleic acid polynucleotides. In some embodiments, the engineered guide ribonucleic acid structure comprises a single ribonucleic acid polynucleotide comprising the guide ribonucleic acid sequence and the ribonucleic acid sequence configured to bind the endonuclease. In some embodiments, the guide ribonucleic acid sequence is complementary to a prokaryotic, bacterial, archaeal, eukaryotic, fungal, plant, mammalian, or human genomic sequence. In some embodiments, the guide ribonucleic acid sequence is from about 14 to about 28 nucleotides in length, from about 18 to about 26 nucleotides in length, from about 22 to about 26 nucleotides in length, or from about 24 nucleotides in length. In some embodiments, the guide ribonuclease acid sequence comprises a sequence with at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 462, 676, or 1229-1230. In some embodiments, the endonuclease comprises one or more nuclear localization sequences (NLSs) proximal to an N- or C-terminus of the endonuclease. In some embodiments, the NLS comprises a sequence selected from any one of SEQ ID NOs: 205-220. In some embodiments, the system further comprises a single- or double-stranded DNA repair template comprising from 5′ to 3′: a first homology arm comprising a sequence of at least 20 nucleotides 5′ to the target deoxyribonucleic acid sequence, a synthetic DNA sequence of at least 10 nucleotides, and a second homology arm comprising a sequence of at least 20 nucleotides 3′ to the target sequence. In some embodiments, the first or second homology arm comprises a sequence of at least 40, 80, 120, 150, 200, 300, 500, or 1,000 nucleotides. In some embodiments, the system further comprises a source of Mg²⁺. In some embodiments, the endonuclease and the ribonucleic acid sequence configured to bind the endonuclease are derived from distinct species within a same phylum. In some embodiments, the endonuclease comprises a sequence with at least 70% sequence identity to any one of SEQ ID NOs: 2-24 and the guide RNA structure comprises an RNA sequence predicted to comprise a hairpin comprising a stem and a loop, wherein the stem comprises at least 10 pairs of ribonucleotides and an intervening multiloop. In some embodiments, the guide RNA structure further comprises a second stem and a second loop, wherein the second stem comprises at least 5 pairs of ribonucleotides. In some embodiments, the guide RNA structure further comprises an RNA structure comprising at least two hairpins. In some embodiments, a) the endonuclease comprises a sequence having at least 70%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof; and b) the guide RNA structure comprises a sequence having at least 70%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 199-200, 460-461, or 669-673, or the nonvariable nucleotides of any one of SEQ ID NOs: 201-203, 613-616, 677-686, 1006-1012, or 1231-1259. In some embodiments, a) the endonuclease comprises a sequence at least 70%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321; and b) the guide RNA structure comprises a sequence at least 70%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to a class 2, type II sgRNA or tracr sequence. In some embodiments, the sequence identity is determined by a BLASTP, CLUSTALW, MUSCLE, MAFFT, or CLUSTALW with parameters of the Smith-Waterman homology search algorithm. In some embodiments, the sequence identity is determined by the BLASTP homology search algorithm using parameters of a wordlength (W) of 3, an expectation (E) of 10, and a BLOSUM62 scoring matrix setting gap costs at existence of 11, extension of 1, and using a conditional compositional score matrix adjustment. In some embodiments, the endonuclease is not a Cas9 endonuclease, a Cas14 endonuclease, a Cas12a endonuclease, a Cas12b endonuclease, a Cas 12c endonuclease, a Cas12d endonuclease, a Cas12e endonuclease, a Cas13a endonuclease, a Cas13b endonuclease, a Cas13c endonuclease, or a Cas 13d endonuclease. In some embodiments, the endonuclease has less than 80% identity to a Cas9 endonuclease.

In some aspects, the present disclosure provides for an engineered nuclease system comprising: (a) an endonuclease configured to be selective for a target adjacent motif (TAM) sequence comprising any one of ANGG (SEQ ID NO: 1029), NARAA (SEQ ID NO: 1030), ATGAAA (SEQ ID NO: 1031), ATGA (SEQ ID NO: 1032), or WTGG (SEQ ID NO: 1033), wherein the endonuclease comprises a TAM interacting domain having at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to a TAM interacting domain of any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321; and (b) an engineered guide RNA, wherein the engineered guide RNA is configured to form a complex with the endonuclease and the engineered guide RNA comprises a spacer sequence configured to hybridize to a target nucleic acid sequence. In some embodiments, the TAM-interacting domain comprises a sequence having at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to a TAM-interacting domain of SEQ ID NO: 674 or a variant thereof or at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to a TAM-interacting domain of SEQ ID NO: 675 or a variant thereof. In some embodiments, the endonuclease system comprises a sequence complementary to a eukaryotic, fungal, plant, mammalian, or human genomic polynucleotide sequence. In some embodiments, the guide RNA is 30-280 nucleotides in length. In some embodiments, the system further comprises a single- or double-stranded DNA repair template comprising from 5′ to 3′: a first homology arm comprising a sequence of at least 20 nucleotides 5′ to the target deoxyribonucleic acid sequence, a synthetic DNA sequence of at least 10 nucleotides, and a second homology arm comprising a sequence of at least 20 nucleotides 3′ to the target sequence. In some embodiments, the first or second homology arm comprises a sequence of at least 40 nucleotides. In some embodiments, the first and second homology arms are homologous to a genomic sequence of a eukaryote. In some embodiments, the single- or double-stranded DNA repair template comprises a transgene donor. In some embodiments, the system further comprises a DNA repair template comprising a double-stranded DNA segment flanked by one or two single-stranded DNA segments. In some embodiments, the single-stranded DNA segments are conjugated to the 5′ ends of the double-stranded DNA segment. In some embodiments, the single stranded DNA segments are conjugated to the 3′ ends of the double-stranded DNA segment. In some embodiments, the single-stranded DNA segments have a length from 4 to 10 nucleotide bases. In some embodiments, the single-stranded DNA segments have a nucleotide sequence complementary to a sequence within the spacer sequence. In some embodiments, the double-stranded DNA sequence comprises a barcode, an open reading frame, an enhancer, a promoter, a protein-coding sequence, a miRNA coding sequence, an RNA coding sequence, or a transgene. In some embodiments, the double-stranded DNA sequence is flanked by a nuclease cut site.

In some aspects, the present disclosure provides for an engineered nuclease system comprising: (a) an endonuclease configured to be selective for a protospacer adjacent motif (PAM) sequence comprising NRR, wherein the endonuclease comprises a PAM interacting domain having at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to a PAM interacting domain of any one of SEQ ID NOs: 1313-1318; and (b) an engineered guide RNA, wherein the engineered guide RNA is configured to form a complex with the endonuclease and the engineered guide RNA comprises a spacer sequence configured to hybridize to a target nucleic acid sequence. In some embodiments, the TAM-interacting domain comprises a sequence having at least 80% sequence identity to a TAM-interacting domain of SEQ ID NO: 674 or a variant thereof or at least 80% sequence identity to a TAM-interacting domain of SEQ ID NO: 675 or a variant thereof. In some embodiments, the endonuclease system comprises a sequence complementary to a eukaryotic, fungal, plant, mammalian, or human genomic polynucleotide sequence. In some embodiments, the guide RNA is 30-280 nucleotides in length. In some embodiments, the system further comprises a single- or double-stranded DNA repair template comprising from 5′ to 3′: a first homology arm comprising a sequence of at least 20 nucleotides 5′ to the target deoxyribonucleic acid sequence, a synthetic DNA sequence of at least 10 nucleotides, and a second homology arm comprising a sequence of at least 20 nucleotides 3′ to the target sequence. In some embodiments, the first or second homology arm comprises a sequence of at least 40 nucleotides. In some embodiments, the first and second homology arms are homologous to a genomic sequence of a eukaryote. In some embodiments, the single- or double-stranded DNA repair template comprises a transgene donor. In some embodiments, the system further comprises a DNA repair template comprising a double-stranded DNA segment flanked by one or two single-stranded DNA segments. In some embodiments, the single-stranded DNA segments are conjugated to the 5′ ends of the double-stranded DNA segment. In some embodiments, the single stranded DNA segments are conjugated to the 3′ ends of the double-stranded DNA segment. In some embodiments, the single-stranded DNA segments have a length from 4 to 10 nucleotide bases. In some embodiments, the single-stranded DNA segments have a nucleotide sequence complementary to a sequence within the spacer sequence. In some embodiments, the double-stranded DNA sequence comprises a barcode, an open reading frame, an enhancer, a promoter, a protein-coding sequence, a miRNA coding sequence, an RNA coding sequence, or a transgene. In some embodiments, the double-stranded DNA sequence is flanked by a nuclease cut site.

In some aspects, the present disclosure provides for an engineered single guide ribonucleic acid polynucleotide comprising: a) a DNA-targeting segment comprising a nucleotide sequence that is complementary to a target sequence in a target DNA molecule; and b) a protein-binding segment comprising two complementary stretches of nucleotides that hybridize to form a double-stranded RNA (dsRNA) duplex, wherein the two complementary stretches of nucleotides are covalently linked to one another with intervening nucleotides, and wherein the engineered guide ribonucleic acid polynucleotide is configured to form a complex with an endonuclease comprising a variant having at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 674-675, 975-1002, 1260-1321, or a variant thereof. In some embodiments, the DNA-targeting segment is positioned 5′ of both of the two complementary stretches of nucleotides. In some embodiments: a) the protein binding segment comprises a sequence having at least at least 70%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 199-200, 460-461, or 669-673; or b) the protein binding segment comprises a sequence having at least 70%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to the nonvariable nucleotides of any one of SEQ ID NOs: 201-203, 613-616, 677-686, 1003-1022, or 1231-1259. In some embodiments, a) the endonuclease comprises a sequence having at least 70%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 674-675, 975-1002, 1260-1321, or a variant thereof; and b) the guide RNA structure comprises a sequence having at least 70%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to a class 2, type II sgRNA. In some embodiments, the endonuclease further comprises a base editor or a histone editor coupled to the endonuclease. In some embodiments, the base editor is an adenosine deaminase. In some embodiments, the adenosine deaminase comprises ADAR1 or ADAR2. In some embodiments, the base editor is a cytosine deaminase. In some embodiments, the cytosine deaminase comprises APOBEC1, APOBEC2, APOBEC3A, APOBEC3B, APOBEC3C, APOBEC3D, APOBEC3F, APOBEC3G, APOBEC3H, or APOBEC4.

In some aspects, the present disclosure provides for a deoxyribonucleic acid polynucleotide encoding any of the engineered guide ribonucleic acid polynucleotides described herein.

In some aspects, the present disclosure provides for a nucleic acid comprising an engineered nucleic acid sequence optimized for expression in an organism, wherein the nucleic acid encodes an endonuclease comprising a RuvC domain and an HNH domain, wherein the endonuclease is derived from an uncultivated microorganism, and wherein the endonuclease has a molecular weight of about 120 kDa or less, 100 kDa or less, 90 kDa or less, 60 kDa or less, or 30 kDa or less, and wherein the endonuclease comprises SEQ ID NO: 674-675, 975-1002, 1260-1321, or a variant thereof having at least 70%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity thereto. In some embodiments, the endonuclease further comprises a sequence encoding one or more nuclear localization sequences (NLSs) proximal to an N- or C-terminus of the endonuclease. In some embodiments, the NLS comprises a sequence selected from SEQ ID NOs: 205-220. In some embodiments, the organism is prokaryotic, bacterial, eukaryotic, fungal, plant, mammalian, rodent, or human. In some embodiments, the organism is prokaryotic or bacterial, and the organism is a different organism from an organism from which the endonuclease is derived. In some embodiments, the organism is not the uncultivated microorganism.

In some aspects, the present disclosure provides for a vector comprising a nucleic acid sequence encoding an RNA-guided endonuclease comprising a RuvC-I domain and an HNH domain, wherein the endonuclease is derived from an uncultivated microorganism, and wherein the endonuclease has a molecular weight of about 120 kDa or less, 100 kDa or less, 90 kDa or less, or 60 kDa or less, wherein the RNA-guided endonuclease is optionally archaeal, and wherein the RNA-guided endonuclease comprises SEQ ID NO: 674-675, 975-1002, 1260-1321, or a variant thereof having at least 70%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity thereto. In some embodiments, the endonuclease further comprises an arginine-rich region comprising an RRxRR motif or a domain with PF14239 homology. In some embodiments, the endonuclease further comprises a REC (recognition) domain. In some embodiments, the endonuclease further comprises a BH domain, a WED domain, and a target adjacent motif (TAM)-interacting (TI) domain. In some embodiments, the TI domain comprises a TI domain of any one of SEQ ID NO: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321.

In some aspects, the present disclosure provides for a vector comprising any of the nucleic acids described herein. In some embodiments, the vector further comprises a nucleic acid encoding an engineered guide ribonucleic acid structure configured to form a complex with the endonuclease, the engineered guide ribonucleic acid structure comprising: a) a guide ribonucleic acid sequence configured to hybridize to a target deoxyribonucleic acid sequence; and b) a ribonucleic acid sequence configured to bind to the endonuclease. In some embodiments, vector is a plasmid, a minicircle, a CELiD, an adeno-associated virus (AAV) derived virion, or a lentivirus.

In some aspects, the present disclosure provides for a cell comprising any of the vectors described herein. In some embodiments, the cell is a bacterial, archaeal, fungal, eukaryotic, mammalian, or plant cell. In some embodiments, the cell is a bacterial cell.

In some aspects, the present disclosure provides for a method of manufacturing an endonuclease, comprising cultivating any of the cells described herein.

In some aspects, the present disclosure provides for a method for binding, cleaving, marking, or modifying a double-stranded deoxyribonucleic acid polynucleotide, comprising: (a) contacting the double-stranded deoxyribonucleic acid polynucleotide with an RNA-guided archaeal endonuclease in complex with an engineered guide ribonucleic acid structure configured to bind to the endonuclease and the double-stranded deoxyribonucleic acid polynucleotide; (b) wherein the double-stranded deoxyribonucleic acid polynucleotide comprises a protospacer adjacent motif (PAM); and wherein the endonuclease comprises a variant with at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 674-675, 975-1002, 1260-1321. In some embodiments, the endonuclease cleaves the double-stranded deoxyribonucleic acid polynucleotide, wherein the PAM comprises NGG. In some embodiments, the endonuclease cleaves the double-stranded deoxyribonucleic acid polynucleotide 6-9 or 7 nucleotides from the PAM. In some embodiments, the endonuclease is not a Cas9 endonuclease, a Cas14 endonuclease, a Cas12a endonuclease, a Cas12b endonuclease, a Cas 12c endonuclease, a Cas12d endonuclease, a Cas12e endonuclease, a Cas13a endonuclease, a Cas13b endonuclease, a Cas13c endonuclease, or a Cas 13d endonuclease. In some embodiments, the endonuclease is derived from an uncultivated microorganism. In some embodiments, the double-stranded deoxyribonucleic acid polynucleotide is a prokaryotic, archaeal, bacterial, eukaryotic, plant, fungal, mammalian, rodent, or human double-stranded deoxyribonucleic acid polynucleotide. In some embodiments, the double-stranded deoxyribonucleic acid polynucleotide is a prokaryotic, archaeal, or bacterial double-stranded deoxyribonucleic acid polynucleotide from a species other than a species from which the endonuclease was derived.

In some aspects, the present disclosure provides for a method of modifying a target nucleic acid locus, the method comprising delivering to the target nucleic acid locus any of the engineered nuclease systems described herein, wherein the endonuclease is configured to form a complex with the engineered guide ribonucleic acid structure, and wherein the complex is configured such that upon binding of the complex to the target nucleic acid locus, the complex modifies the target nucleic locus. In some embodiments, the target nucleic acid locus comprises binding, nicking, cleaving, or marking the target nucleic acid locus. In some embodiments, the target nucleic acid locus comprises deoxyribonucleic acid (DNA) or ribonucleic acid (RNA). In some embodiments, the target nucleic acid comprises genomic eukaryotic DNA, archaeal DNA, viral DNA, or bacterial DNA. In some embodiments, the target nucleic acid comprises bacterial DNA wherein the bacterial DNA is derived from a bacterial or archaeal species different from a species from which the endonuclease was derived. In some embodiments, the target nucleic acid locus is in vitro. In some embodiments, the target nucleic acid locus is within a cell. In some embodiments, endonuclease and the engineered guide nucleic acid structure are encoded by separate nucleic acid molecules. In some embodiments, the cell is a prokaryotic cell, a bacterial cell, an archaeal cell, a eukaryotic cell, a fungal cell, a plant cell, an animal cell, a mammalian cell, a rodent cell, a primate cell, or a human cell. In some embodiments, the cell is derived from a species different from a species from which the endonuclease was derived. In some embodiments, delivering the engineered nuclease system to the target nucleic acid locus comprises delivering any of the nucleic acids described herein or any of the vectors described herein. In some embodiments, delivering the engineered nuclease system to the target nucleic acid locus comprises delivering a nucleic acid comprising an open reading frame encoding the endonuclease. In some embodiments, the nucleic acid comprises a promoter to which the open reading frame encoding the endonuclease is operably linked. In some embodiments, delivering the engineered nuclease system to the target nucleic acid locus comprises delivering a capped mRNA containing the open reading frame encoding the endonuclease. In some embodiments, delivering the engineered nuclease system to the target nucleic acid locus comprises delivering a translated polypeptide. In some embodiments, delivering the engineered nuclease system to the target nucleic acid locus comprises delivering a deoxyribonucleic acid (DNA) encoding the engineered guide ribonucleic acid structure operably linked to a ribonucleic acid (RNA) pol III promoter. In some embodiments, the endonuclease induces a single-stranded break or a double-stranded break at or proximal to the target locus. In some embodiments, the endonuclease induces a double stranded break proximal to the target locus 5′ from a protospacer adjacent motif (PAM). In some embodiments, the endonuclease induces a double-stranded break 6-8 nucleotides or 7 nucleotides 5′ from the PAM. In some embodiments, the engineered nuclease system induces a chemical modification of a nucleotide base within or proximal to the target locus. In some embodiments, the chemical modification is deamination of an adenosine or a cytosine nucleotide. In some embodiments, the endonuclease further comprises a base editor coupled to the endonuclease. In some embodiments, the base editor is an adenosine deaminase. In some embodiments, the adenosine deaminase comprises ADAR1 or ADAR2. In some embodiments, the base editor is a cytosine deaminase. In some embodiments, the cytosine deaminase comprises APOBEC1, APOBEC2, APOBEC3A, APOBEC3B, APOBEC3C, APOBEC3D, APOBEC3F, APOBEC3G, APOBEC3H, or APOBEC4.

In some aspects, the present disclosure provides fora method of disrupting a TRAC locus in a cell, comprising contacting to the cell a composition comprising: (a) an endonuclease having at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof, and (b) an engineered guide RNA, wherein the engineered guide RNA is configured to form a complex with the endonuclease and the engineered guide RNA comprises a spacer sequence configured to hybridize to a region of the locus, wherein the engineered guide RNA is configured to hybridize to any one of SEQ ID NOs: 1079-1082, 1145-1166, and 1169-1170. In some embodiments, the engineered guide RNA comprises a sequence having at least about at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 1123-1144 or 1167-1168. In some embodiments, the engineered guide RNA comprises the modified nucleotides of any one of SEQ ID NOs: 1123-1144 or 1167-1168. In some embodiments, the engineered guide RNA comprises a sequence having at least about at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to a sequence complementary to any one of SEQ ID NOs: 1145-1166 or 1169-1170. In some embodiments, the endonuclease has at least about 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 582, 988, 990, 993, 996, 999, or 1002. In some embodiments, the region is 5′ to a protospacer adjacent motif (PAM) comprising any one of SEQ ID NOs: SEQ ID NOs: 1023-1044.

In some aspects, the present disclosure provides for an isolated RNA molecule comprising a sequence at least about 80%, 81%, 82%, 83%, 84%, 85%, 86%, 87%, 88%, 89%, 90%, 91%, 92%, 93%, 94%, 95%, 96%, 97%, 98%, 99%, or 100% identical to any one of SEQ ID NOs: 1123-1144 or 1167-1168. In some embodiments, the isolated RNA molecule comprises the pattern of chemical modifications recited in any one of SEQ ID NOs: 1123-1144 or 1167-1168.

In some aspects, the present disclosure provides for use of any of the isolated RNA molecules described herein for modifying a TRAC locus of a cell.

In some aspects, the present disclosure provides for a method of disrupting an AAVS1 locus in a cell, comprising contacting to the cell a composition comprising: (a) an endonuclease having at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof, and (b) an engineered guide RNA, wherein the engineered guide RNA is configured to form a complex with the endonuclease and the engineered guide RNA comprises a spacer sequence configured to hybridize to a region of the locus, wherein the engineered guide RNA is configured to hybridize to any one of SEQ ID NOs: 1105-1122. In some embodiments, the engineered guide RNA comprises a sequence having at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 1087-1104. In some embodiments, the engineered guide RNA comprises the modified nucleotides of any one of SEQ ID NOs: 1087-1104. In some embodiments, the engineered guide RNA comprises a sequence having at least about 80% identity to a sequence complementary to any one of SEQ ID NOs: 1105-1122. In some embodiments, the endonuclease has at least about 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 582, 988, 990, 993, 996, 999, or 1002. In some embodiments, the endonuclease has at least about 75%, 80%, or 90% sequence identity to SEQ ID NO: 582. In some embodiments, the region is 5′ to a protospacer adjacent motif (PAM) comprising any one of SEQ ID NOs: 1023-1044.

In some aspects, the present disclosure provides for an isolated RNA molecule comprising a sequence at least about 80%, 81%, 82%, 83%, 84%, 85%, 86%, 87%, 88%, 89%, 90%, 91%, 92%, 93%, 94%, 95%, 96%, 97%, 98%, 99%, or 100% identical to any one of SEQ ID NOs: 1087-1104. In some embodiments, the RNA molecule comprises the pattern of chemical modifications recited in any one of SEQ ID NOs: 1087-1104.

In some aspects, the present disclosure provides for an engineered nuclease system, comprising: (a) an endonuclease comprising a RuvC domain and an HNH domain; wherein the endonuclease comprises a sequence having at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to any one of SEQ ID NOs: 25-27, 30, 126, 582, 594, 118, 128, 396, 530, 618, 620, 621, 653, 656, 657, 656, or a variant thereof, and (b) an engineered guide ribonucleic acid structure configured to form a complex with the endonuclease comprising: (i) a guide ribonucleic acid sequence configured to hybridize to a target deoxyribonucleic acid sequence; and (ii) a ribonucleic acid sequence configured to bind to the endonuclease; wherein the ribonucleic acid sequence configured to bind the endonuclease comprises a sequence with at least at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, at least 99%, or 100% sequence identity to the non-degenerate nucleotides of any one of SEQ ID NOs: 677-681, 686, 1006-1008, 1011-1014, or 1231-1259. In some embodiments, the engineered guide ribonucleic acid structure comprises a single ribonucleic acid polynucleotide comprising the guide ribonucleic acid sequence and the ribonucleic acid sequence configured to bind the endonuclease. In some embodiments, the guide ribonucleic acid sequence is complementary to a prokaryotic, bacterial, archaeal, eukaryotic, fungal, plant, mammalian, or human genomic sequence. In some embodiments, the endonuclease comprises one or more nuclear localization sequences (NLSs) proximal to an N- or C-terminus of the endonuclease. In some embodiments, the NLS comprises a sequence selected from any one SEQ ID NOs: 205-220. In some embodiments, the system further comprises a single- or double-stranded DNA repair template comprising from 5′ to 3′: a first homology arm comprising a sequence of at least 20 nucleotides 5′ to the target deoxyribonucleic acid sequence, a synthetic DNA sequence of at least 10 nucleotides, and a second homology arm comprising a sequence of at least 20 nucleotides 3′ to the target sequence. In some embodiments, the endonuclease and the ribonucleic acid sequence configured to bind the endonuclease are derived from distinct species within a same phylum. In some embodiments, the endonuclease is not a Cas9 endonuclease, a Cas14 endonuclease, a Cas12a endonuclease, a Cas12b endonuclease, a Cas 12c endonuclease, a Cas12d endonuclease, a Cas12e endonuclease, a Cas13a endonuclease, a Cas13b endonuclease, a Cas13c endonuclease, or a Cas 13d endonuclease. In some embodiments, the endonuclease does not exhibit collateral ssDNA cleavage activity.

In some aspects, the present disclosure provides for an engineered nuclease system, comprising: (a) an endonuclease comprising a RuvC domain and an HNH domain; wherein the endonuclease comprises a sequence having at least 80% sequence identity to any one of the endonuclease effectors sequences described herein, or a variant thereof, and (b) an engineered guide ribonucleic acid structure configured to form a complex with the endonuclease comprising: (i) a guide ribonucleic acid sequence configured to hybridize to a target deoxyribonucleic acid sequence; and (ii) a ribonucleic acid sequence configured to bind to the endonuclease; wherein the endonuclease comprises a sequence having at least 80% sequence identity to non-degenerate nucleotides of any of the sgRNA sequences described herein, or a variant thereof.

In some aspects, the present disclosure provides for an isolated RNA molecule comprising a sequence at least about 80%, 81%, 82%, 83%, 84%, 85%, 86%, 87%, 88%, 89%, 90%, 91%, 92%, 93%, 94%, 95%, 96%, 97%, 98%, 99%, or 100% identical to non-degenerate nucleotides of any of the sgRNA sequences described herein.

In some aspects, the present disclosure provides for a nucleic acid comprising any of the sequences described herein.

In some aspects, the present disclosure provides for a vector comprising any of the nucleic acid sequences described herein.

In some aspects, the present disclosure provides for an engineered nuclease system, comprising: (a) an endonuclease comprising a RuvC domain and an HNH domain, wherein said endonuclease is derived from an uncultivated microorganism; and (b) an engineered guide ribonucleic acid structure configured to form a complex with said endonuclease comprising: (i) a guide ribonucleic acid sequence configured to hybridize to a target deoxyribonucleic acid sequence; and (ii) a tracr ribonucleic acid sequence configured to bind to said endonuclease; wherein said endonuclease has a molecular weight of about 96 kDa or less. In some embodiments, said endonuclease is an archaeal endonuclease. In some embodiments, said endonuclease is a Class 2, Type II Cas endonuclease. In some embodiments, said endonuclease comprises a sequence with at least 70%, at least 75%, at least 80% or at least 90% sequence identity to any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof. In some embodiments, said endonuclease further comprises an arginine-rich region comprising an RRxRR motif or a domain with PF14239 homology. In some embodiments, said arginine rich region or said domain with PF14239 homology has at least 85%, at least 90%, or at least 95% identity to an arginine rich region or a domain with PF14239 homology of any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof. In some embodiments, said endonuclease further comprises a REC (recognition) domain. In some embodiments, said REC domain has at least 85%, at least 90%, or at least 95% identity to a REC domain of any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof. In some embodiments, said endonuclease further comprises a BH (bridge helix) domain, a WED (wedge) domain, and a PI (PAM interacting) domain. In some embodiments, said BH domain, said WED domain, or said PI domain has at least 85%, at least 90%, or at least 95% identity to a BH domain, a WED domain, or a PI domain of any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof.

In some aspects, the present disclosure provides for an engineered nuclease system comprising: (a) an engineered guide ribonucleic acid structure comprising: (i) a guide ribonucleic acid sequence configured to hybridize to a target deoxyribonucleic acid sequence; and (ii) a ribonucleic acid sequence configured to bind to an endonuclease, wherein said ribonucleic acid sequence comprises a sequence with at least 80% sequence identity to any one of SEQ ID NOs: 199-200, 460-461, or 669-673, or a sequence with at least 80% sequence identity to nonvariable nucleotides of any one of SEQ ID NOs: 201-203, 613-616, 677-686, 1003-1022, or 1231-1259; and (b) an RNA-guided endonuclease configured to bind to said engineered guide ribonucleic acid. In some embodiments, said RNA-guided endonuclease is an archaeal endonuclease. In some embodiments, said endonuclease has a molecular weight of about 120 kDa or less, 100 kDa or less, 90 kDa or less, or 60 kDa or less. In some embodiments, said engineered guide ribonucleic acid structure comprises at least two ribonucleic acid polynucleotides. In some embodiments, said engineered guide ribonucleic acid structure comprises a single ribonucleic acid polynucleotide comprising said guide ribonucleic acid sequence and said tracr ribonucleic acid sequence. In some embodiments, said guide ribonucleic acid sequence is complementary to a prokaryotic, bacterial, archaeal, eukaryotic, fungal, plant, mammalian, or human genomic sequence. In some embodiments, said guide ribonucleic acid sequence is 15-24 nucleotides in length. In some embodiments, said endonuclease comprises one or more nuclear localization sequences (NLSs) proximal to an N- or C-terminus of said endonuclease. In some embodiments, said NLS comprises a sequence selected from SEQ ID NOs: 205-220. In some embodiments, the system further comprises a single- or double-stranded DNA repair template comprising from 5′ to 3′: a first homology arm comprising a sequence of at least 20 nucleotides 5′ to said target deoxyribonucleic acid sequence, a synthetic DNA sequence of at least 10 nucleotides, and a second homology arm comprising a sequence of at least 20 nucleotides 3′ to said target sequence. In some embodiments, said first or second homology arm comprises a sequence of at least 40, 80, 120, 150, 200, 300, 500, or 1,000 nucleotides. In some embodiments, said system further comprises a source of Mg²⁺. In some embodiments, said endonuclease and said tracr ribonucleic acid sequence are derived from distinct bacterial species within a same phylum. In some embodiments, said endonuclease comprises a sequence with at least 70% sequence identity to any one of SEQ ID NOs: 2-24 and said guide RNA structure comprises an RNA sequence predicted to comprise a hairpin comprising a stem and a loop, wherein said stem comprises at least 12 pairs of ribonucleotides. In some embodiments, said guide RNA structure further comprises a second stem and a second loop, wherein the second stem comprises at least 5 pairs of ribonucleotides. In some embodiments, said guide RNA structure further comprises an RNA structure comprising at least two hairpins. In some embodiments, said endonuclease comprises a sequence with at least 70% sequence identity to SEQ ID NO: 1 and said guide RNA structure comprises an RNA sequence predicted to comprise at least four hairpins comprising a stem and a loop. In some embodiments, a) said endonuclease comprises a sequence at least 70%, at least 80%, or at least 90% identical to any one of SEQ ID NOs: 1, 2, 10, 17, or 613-616; and b) said guide RNA structure comprises a sequence at least 70%, at least 80%, or at least 90% identical to any one of SEQ ID NOs: 199-200 or 669-673 or the nonvariable nucleotides of any one of SEQ ID NOs: 201-203, 613-616. In some embodiments, a) said endonuclease comprises a sequence at least 70%, at least 80%, or at least 90% identical to any one of SEQ ID NOs: 1-24, 462-488, or 501-612; and b) said guide RNA structure comprises a sequence at least 70%, at least 80%, or at least 90% identical to any one of SEQ ID NOs: 199-200 or 669-673 or the nonvariable nucleotides of any one of SEQ ID NOs: 201-203 or 613-616. In some embodiments, a) said endonuclease comprises a sequence at least 70%, at least 80%, or at least 90% identical to any one of SEQ ID NOs: 2, 10, or 17; and b) said guide RNA structure comprises a sequence at least 70%, at least 80%, or at least 90% identical to the nonvariable nucleotides of any one of SEQ ID NOs: 202-203 or 613-614. In some embodiments: a) said endonuclease comprises a sequence at least 70%, at least 80%, or at least 90% identical to any one of SEQ ID NOs: 25-198, 221-459, or 489-580; and b) said guide RNA structure comprises a sequence at least 70%, at least 80%, or at least 90% identical to a class 2, type II sgRNA or tracr sequence. In some embodiments, said sequence identity is determined by a BLASTP, CLUSTALW, MUSCLE, MAFFT, or CLUSTALW with parameters of the Smith-Waterman homology search algorithm. In some embodiments, said sequence identity is determined by said BLASTP homology search algorithm using parameters of a wordlength (W) of 3, an expectation (E) of 10, and a BLOSUM62 scoring matrix setting gap costs at existence of 11, extension of 1, and using a conditional compositional score matrix adjustment. In some embodiments, said endonuclease is not a Cas9 endonuclease, a Cas14 endonuclease, a Cas12a endonuclease, a Cas12b endonuclease, a Cas 12c endonuclease, a Cas12d endonuclease, a Cas12e endonuclease, a Cas13a endonuclease, a Cas13b endonuclease, a Cas13c endonuclease, or a Cas 13d endonuclease. In some embodiments, said endonuclease has less than 80% identity to a Cas9 endonuclease.

In some aspects, the present disclosure provides for an engineered single guide ribonucleic acid polynucleotide comprising: a) a DNA-targeting segment comprising a nucleotide sequence that is complementary to a target sequence in a target DNA molecule; and b) a protein-binding segment comprising two complementary stretches of nucleotides that hybridize to form a double-stranded RNA (dsRNA) duplex, wherein said two complementary stretches of nucleotides are covalently linked to one another with intervening nucleotides, and wherein said engineered guide ribonucleic acid polynucleotide is configured to form a complex with an endonuclease comprising a variant having at least 75% sequence identity to any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof. In some embodiments, said DNA-targeting segment is positioned 5′ of both of said two complementary stretches of nucleotides. In some embodiments, a) said protein binding segment comprises a sequence having at least at least 70%, at least 80%, or at least 90% identical to any one of SEQ ID NOs: 199-200 or 669-673; b) said protein binding segment comprises a sequence having at least 70%, at least 80%, or at least 90% identical to the nonvariable nucleotides of any one of SEQ ID NOs: 201-203 or 613-616. In some embodiments, a) said endonuclease comprises a sequence at least 70%, at least 80%, or at least 90% identical to any one of SEQ ID NOs: 2, 10, or 17; and b) said guide RNA structure comprises a sequence at least 70%, at least 80%, or at least 90% identical to at least one of SEQ ID NO: 200 or the nonvariable nucleotides of SEQ ID NO: 202-203 or 613-614. In some embodiments, a) said endonuclease comprises a sequence at least 70%, at least 80%, or at least 90% identical to any one of SEQ ID NOs: 25-198, 221-459, or 489-580; and b) said guide RNA structure comprises a sequence at least 70%, at least 80%, or at least 90% identical to a class 2, type II sgRNA. In some embodiments, said endonuclease further comprises a base editor or a histone editor coupled to said endonuclease. In some embodiments, said base editor is an adenosine deaminase. In some embodiments, said adenosine deaminase comprises ADAR1 or ADAR2. In some embodiments, said base editor is a cytosine deaminase. In some embodiments, said cytosine deaminase comprises APOBEC1, APOBEC2, APOBEC3A, APOBEC3B, APOBEC3C, APOBEC3D, APOBEC3F, APOBEC3G, APOBEC3H, or APOBEC4.

In some aspects, the present disclosure provides for a deoxyribonucleic acid polynucleotide encoding any of the engineered guide ribonucleic acid polynucleotides described herein.

In some aspects, the present disclosure provides for a nucleic acid comprising an engineered nucleic acid sequence optimized for expression in an organism, wherein said nucleic acid encodes a class 2, type II Cas endonuclease comprising a RuvC domain and an HNH domain, wherein said endonuclease is derived from an uncultivated microorganism, and wherein said endonuclease has a molecular weight of about 120 kDa or less, 100 kDa or less, 90 kDa or less, 60 kDa or less, or 30 kDa or less. In some embodiments, said endonuclease comprises SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof having at least 70% sequence identity thereto. In some embodiments, said endonuclease further comprises a sequence encoding one or more nuclear localization sequences (NLSs) proximal to an N- or C-terminus of said endonuclease. In some embodiments, said NLS comprises a sequence selected from SEQ ID NOs: 205-220. In some embodiments, said organism is prokaryotic, bacterial, eukaryotic, fungal, plant, mammalian, rodent, or human. In some embodiments, said organism is prokaryotic or bacterial, and said organism is a different organism from an organism from which said endonuclease is derived. In some embodiments, said organism is not said uncultivated microorganism.

In some aspects, the present disclosure provides for a vector comprising any of the nucleic acids described herein. In some embodiments, the vector further comprising a nucleic acid encoding an engineered guide ribonucleic acid structure configured to form a complex with said endonuclease, said engineered guide ribonucleic acid structure comprising: a) a guide ribonucleic acid sequence configured to hybridize to a target deoxyribonucleic acid sequence; and b) a tracr ribonucleic acid sequence configured to binding to said endonuclease. In some embodiments, the vector is a plasmid, a minicircle, a CELiD, an adeno-associated virus (AAV) derived virion, or a lentivirus.

In some aspects, the present disclosure provides for a cell comprising any of the vectors described herein. In some embodiments, said cell is a bacterial, archaeal, fungal, eukaryotic, mammalian, or plant cell. In some embodiments, said cell is a bacterial cell.

In some aspects, the present disclosure provides for a method of manufacturing an endonuclease, comprising cultivating any of the cells described herein.

In some aspects, the present disclosure provides for a method for binding, cleaving, marking, or modifying a double-stranded deoxyribonucleic acid polynucleotide, comprising: (a) contacting said double-stranded deoxyribonucleic acid polynucleotide with an RNA-guided archaeal endonuclease in complex with an engineered guide ribonucleic acid structure configured to bind to said endonuclease and said double-stranded deoxyribonucleic acid polynucleotide; wherein said double-stranded deoxyribonucleic acid polynucleotide comprises a protospacer adjacent motif (PAM); and wherein said endonuclease comprises a variant with at least 70%, at least 75%, at least 80% or at least 90% sequence identity to any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof. In some embodiments, said endonuclease cleaves said double-stranded deoxyribonucleic acid polynucleotide, wherein said PAM comprises NGG. In some embodiments, said endonuclease cleaves said double-stranded deoxyribonucleic acid polynucleotide 6-8 or 7 nucleotides from said PAM. In some embodiments, said class 2, type II Cas endonuclease is not a Cas9 endonuclease, a Cas14 endonuclease, a Cas12a endonuclease, a Cas12b endonuclease, a Cas 12c endonuclease, a Cas12d endonuclease, a Cas12e endonuclease, a Cas13a endonuclease, a Cas13b endonuclease, a Cas13c endonuclease, or a Cas 13d endonuclease. In some embodiments, said class 2, type II Cas endonuclease is derived from an uncultivated microorganism. In some embodiments, said double-stranded deoxyribonucleic acid polynucleotide is a prokaryotic, archaeal, bacterial, eukaryotic, plant, fungal, mammalian, rodent, or human double-stranded deoxyribonucleic acid polynucleotide. In some embodiments, said double-stranded deoxyribonucleic acid polynucleotide is a prokaryotic, archaeal, or bacterial double-stranded deoxyribonucleic acid polynucleotide from a species other than a species from which said endonuclease was derived.

In some aspects, the present disclosure provides for a method of modifying a target nucleic acid locus, said method comprising delivering to said target nucleic acid locus any of the engineered nuclease systems described herein, wherein said endonuclease is configured to form a complex with said engineered guide ribonucleic acid structure, and wherein said complex is configured such that upon binding of said complex to said target nucleic acid locus, said complex modifies said target nucleic locus. In some embodiments, modifying said target nucleic acid locus comprises binding, nicking, cleaving, or marking said target nucleic acid locus. In some embodiments, said target nucleic acid locus comprises deoxyribonucleic acid (DNA) or ribonucleic acid (RNA). In some embodiments, said target nucleic acid comprises genomic eukaryotic DNA, archaeal DNA, viral DNA, or bacterial DNA. In some embodiments, said target nucleic acid comprises bacterial DNA wherein said bacterial DNA is derived from a bacterial or archaeal species different from a species from which said endonuclease was derived. In some embodiments, said target nucleic acid locus is in vitro. In some embodiments, said target nucleic acid locus is within a cell. In some embodiments, said endonuclease and said engineered guide nucleic acid structure are encoded by separate nucleic acid molecules. In some embodiments, said cell is a prokaryotic cell, a bacterial cell, an archaeal cell, a eukaryotic cell, a fungal cell, a plant cell, an animal cell, a mammalian cell, a rodent cell, a primate cell, or a human cell. In some embodiments, said cell is derived from a species different from a species from which said endonuclease was derived. In some embodiments, delivering said engineered nuclease system to said target nucleic acid locus comprises delivering any of the nucleic acids described herein or any of the vectors described herein. In some embodiments, delivering said engineered nuclease system to said target nucleic acid locus comprises delivering a nucleic acid comprising an open reading frame encoding said endonuclease. In some embodiments, said nucleic acid comprises a promoter to which said open reading frame encoding said endonuclease is operably linked. In some embodiments, delivering said engineered nuclease system to said target nucleic acid locus comprises delivering a capped mRNA containing said open reading frame encoding said endonuclease. In some embodiments, delivering said engineered nuclease system to said target nucleic acid locus comprises delivering a translated polypeptide. In some embodiments, delivering said engineered nuclease system to said target nucleic acid locus comprises delivering a deoxyribonucleic acid (DNA) encoding said engineered guide ribonucleic acid structure operably linked to a ribonucleic acid (RNA) pol III promoter. In some embodiments, said endonuclease induces a single-stranded break or a double-stranded break at or proximal to said target locus. In some embodiments, said endonuclease induces a double stranded break proximal to said target locus 5′ from a protospacer adjacent motif (PAM). In some embodiments, said endonuclease induces a double-stranded break 6-8 nucleotides or 7 nucleotides 5′ from said PAM. In some embodiments, said engineered nuclease system induces a chemical modification of a nucleotide base within or proximal to said target locus or a chemical modification of a histone within or proximal to said target locus. In some embodiments, said chemical modification is deamination of an adenosine or a cytosine nucleotide. In some embodiments, said endonuclease further comprises a base editor coupled to said endonuclease. In some embodiments, said base editor is an adenosine deaminase. In some embodiments, said adenosine deaminase comprises ADAR1 or ADAR2. In some embodiments, said base editor is a cytosine deaminase. In some embodiments, said cytosine deaminase comprises APOBEC1, APOBEC2, APOBEC3A, APOBEC3B, APOBEC3C, APOBEC3D, APOBEC3F, APOBEC3G, APOBEC3H, or APOBEC4.

Additional aspects and advantages of the present disclosure will become readily apparent to those skilled in this art from the following detailed description, wherein only illustrative embodiments of the present disclosure are shown and described. As will be realized, the present disclosure is capable of other and different embodiments, and its several details are capable of modifications in various obvious respects, all without departing from the disclosure. Accordingly, the drawings and description are to be regarded as illustrative in nature, and not as restrictive.

INCORPORATION BY REFERENCE

All publications, patents, and patent applications mentioned in this specification are herein incorporated by reference to the same extent as if each individual publication, patent, or patent application was specifically and individually indicated to be incorporated by reference.

BRIEF DESCRIPTION OF THE DRAWINGS

The novel features of the invention are set forth with particularity in the appended claims. A better understanding of the features and advantages of the present invention will be obtained by reference to the following detailed description that sets forth illustrative embodiments, in which the principles of the invention are utilized, and the accompanying drawings (also “Figure” and “FIG.” herein), of which:

FIG. 1A-FIG. 1B depicts a dendrogram showing homology relationships of CRISPR/Cas loci of different classes and types. Shown are SMART I and II Cas enzyme classes described herein relative to Class 2, Type II-A, II-B, and II-C Cas systems, demonstrating that these systems group into separate classes than II-A, II-B, and II-C. (FIG. 1A) shows a SMART phylogenetic tree in context of Cas9 reference sequences, where SMART effectors are distantly clustered away from Cas9 reference sequences (Type II-A, II-B, and II-C); (FIG. 1B) shows a SMART phylogenetic tree illustrating subgroups of SMART enzymes.

FIG. 2 shows length distribution for SMART effectors described herein, showing that SMART I and II enzymes are clustered at a lower molecular weight than Cas9-like enzymes. SMART nucleases show a bimodal distribution with one peak around 400 aa (SMART II) and a second peak around 750 aa (SMART I). Cas9 nucleases also show a bimodal distribution with peaks around 1,100 aa (e.g. SaCas9) and 1,300 aa (e.g. SpCas9).

FIG. 3A-FIG. 3D depicts the genomic context of ‘small’ Type II nucleases MG33-1, MG35-236. SMART nucleases and CRISPR accessory proteins are shown as dark grey arrows, other genes are depicted as light grey arrows. Domains predicted for all genes in a genomic fragment are shown as grey boxes under the arrows. Shown are: (FIG. 3A) genomic context of the SMART I MG33-1 nuclease and CRISPR loci encoded upstream from a SMART II nuclease MG35-236, showing downstream from the SMART II a predicted insertion sequence carrying transposases TnpA and TnpB; (FIG. 3B): genomic context of the SMART I nuclease MG34-1, where environmental expression sequencing reads are shown aligned under the CRISPR array and the predicted tracrRNA, and the transcriptomic coverage for the regions is illustrated above the contig sequence; (FIG. 3C) genomic context of the SMART I nuclease MG34-16, wherein environmental expression sequencing reads are shown aligned under the CRISPR array and the predicted tracrRNA, and the transcriptomic coverage for the regions is illustrated above the contig sequence; and (FIG. 3D) a genomic fragment targeted by spacer 7 from the MG34-16 CRISPR array in (FIG. 3D), where the genomic fragment was identified as being derived from phage based on virus-specific gene annotations terminase and portal; the inset shows the location of the MG34-16 spacer 7 targeting the C-terminus of a viral gene of unknown function—the putative NGG PAM for MG34-16 is highlighted by a grey box downstream from the spacer match.

FIG. 4A-FIG. 4C shows a multiple sequence alignment of example SMART endonucleases (MG33-1 (SEQ ID NO: 1), MG33-2 (SEQ ID NO: 463), MG33-3 (SEQ ID NO: 464), MG34-1 (SEQ ID NO: 2), MG 34-9 (SEQ ID NO: 10), MG34-16 (SEQ ID NO: 17), MG 102-1 (SEQ ID NO: 581), MG102-2 (SEQ ID NO: 582), MG35-1 (SEQ ID NO: 25), MG 35-2 (SEQ ID NO: 26), MG 35-3 (SEQ ID NO: 27), MG 35-102 (SEQ ID NO: 126), MG35-236 (SEQ ID NO: 284), MG35-419 (SEQ ID NO: 222), MG35-420 (SEQ ID NO: 223), and MG 35-421 (SEQ ID NO: 224)), where the sequence of SaCas9 was used as reference domains are shown as a rectangles below the reference sequence, and catalytic residues are shown as squares above each sequence. Shown are: (FIG. 4A) an alignment of the endonuclease region containing the RuvC-I and bridge helix domains; (FIG. 4B) an alignment of the region containing the RuvC-III domain; and (FIG. 4C) an alignment of the region containing the RuvC-II and HNH domains

FIG. 5A-FIG. 5B depicts an example domain organization for SMART I endonucleases, using MG34-1 as an example. Shown are (FIG. 5A) a diagram showing the predicted domain architecture of SMART I nucleases comprising three RuvC domains, a bridge helix (“BH”), a domain with homology to a Pfam PF14239 which interrupts a recognition domain (“REC”), an HNH endonuclease domain (“HNH”), a wedge domain (“WED”), and a PAM interacting domain (PI); and (FIG. 5B) a multiple sequence alignment overview of two SMART I nucleases relative to reference Cas9 nuclease sequences, wherein RuvC and HNH catalytic residues are shown as black bars above each sequence, regions that align in 3D space with the crystal structure of SaCas are represented by rounded boxes, and dashed lines represent regions with poor or no alignment in 3D space between the 3D structure prediction of the SMART and SaCas9.

FIG. 6A-FIG. 6B depicts an example domain organization for SMART II endonucleases, using MG35 family enzymes (MG35-3, MG35-4) as an example. Shown are (FIG. 6A) a diagram showing the predicted domain architecture of SMART II nucleases comprising three RuvC domains, a domain with homology to a Pfam PF14239, an HNH endonuclease domain, an unknown domain, and a recognition domain (REC); and (FIG. 6B) a multiple sequence alignment overview of two SMART II nucleases relative to reference Cas9 nuclease sequences, where RuvC and HNH catalytic residues are shown as black bars above each sequence, regions that align in 3D space with the crystal structure of SaCas are represented by rounded boxes, and residues identified from 3D structure prediction which may be involved in recognizing a guide/target/PAM sequence are represented by dark grey boxes above the MG35-419 sequence (within the RRXRR and REC domains).

FIG. 7A-FIG. 7B illustrates various features of SMART enzymes. Shown are (FIG. 7A) a dot plot showing identity of SMART I domains of various enzymes depicted herein versus those of spCas9 showing that these have a maximum of about 35% sequence identity; (FIG. 7B) a dot plot of length of individual SMART I domains of enzymes described herein.

FIG. 8A-FIG. 8B illustrates count distribution of various SMART-specific motifs versus motifs predicted in Cas9 nuclease sequences showing that these motifs occur more commonly in SMART enzymes; motifs were predicted on 803 reference Cas9 sequences (Type II-A, II-B, and II-C), 84 SMART I sequences, and 471 SMART II sequences. Shown are (FIG. 8A) a box plot of count frequency of Zn-binding ribbon motifs (CX[2-4]C and CX[2-4]H) in various types of class 2 Cas enzymes; and (B) a histogram of count frequency of RRXRR motifs in various types of class 2 Cas enzymes. In (FIG. 8A) and (FIG. 8B) lines track the mean count value, while outliers are represented by dots.

FIG. 9A-FIG. 9D illustrates predicted guide RNA structures of designed single-guide RNAs (sgRNAs) for cleavage activity with SMART I endonucleases. Shown are (FIG. 9A) MG34-1 sgRNA 1; (FIG. 9B) MG34-1 sgRNA 2; (FIG. 9C) MG34-9 sgRNA 1, and (FIG. 9D) MG34-16 sgRNA 1.

FIG. 10A-FIG. 10B depicts cleavage characterization of SMART I nucleases as described in Example 1. (FIG. 10A) shows an Agilent TapeStation gel of the ligation products of a cleavage assay for MG34-1 with two sgRNA designs vs. the negative control. Lane L3: ladder. Lane A4: Apo, no sgRNA. Lanes B4 and C4: MG34-1 sgRNAs tested (sg1: SEQ ID No. 612, sg2: 613). Cleavage product bands are labeled with arrows. Lanes G3 and H3: greyed out, not relevant to this experiment. (FIG. 10B) shows a PCR gel of the ligation products show activity of MG34-1, 34-9 and 34-16. Lane 1: ladder. Lanes 2-7: sgRNA designs with six spacer lengths for MG34-1. Lanes 8 and 9: sgRNA design for 34-9 and 34-16, respectively. Arrows indicate cleavage confirmation bands.

FIG. 11A-FIG. 11C illustrates sequence cutting preference for MG34 nucleases. (FIG. 11A) shows a SeqLogo representation of a consensus PAM sequence (NGGN) for MG34-1 with sgRNA 1 (top, SEQ ID NO: 612) and sgRNA 2 (bottom, SEQ ID NO: 613). (FIG. 11B) shows a histogram showing the location of the cut site for MG34-1, demonstrating that MG34-1 prefers to cleave at about position 7 from the PAM. (FIG. 11C) shows a sanger sequencing chromatogram shows a preferred NGG PAM for MG34-9 (highlighted with a box). The arrow indicates the cut site at position 7 from the PAM.

FIG. 12A-FIG. 12C illustrates the results of plasmid targeting experiments in E. coli for MG 34-1. (FIG. 12A) shows replica plating of E. coli strains demonstrating plasmid cutting; E. coli expressing MG34-1 and a sgRNA were transformed with a kanamycin resistance plasmid containing a target for the sgRNA (+sp). Plate quadrants that show growth impairment (+sp) vs. the negative control (without the target and PAM (−sp)) indicate successful targeting and cleavage by the enzyme. The experiment was replicated twice and performed in triplicate. (FIG. 12B) Shows graphs of colony forming unit (cfu) measurements from the replica plating experiments in A showing growth repression in the target condition (+sp) vs. the non-target control (−sp), demonstrating the plasmid was cut. (FIG. 12C) shows barplots of colony forming unit (cfu) measurements (in log-scale) showing E. coli growth repression in the target condition (white bars) vs. the non-target controls (green bars). Plasmid interference assays for each nuclease were done in triplicate along with the SpCas9 positive control.

FIG. 13A-FIG. 13B shows an example genomic context of a SMART system for MG35-419. SMART nucleases are shown as dark grey arrows, other genes are depicted as lighter grey arrows. Domains predicted for all genes in a genomic fragment are shown as grey boxes under the arrows. Environmental expression sequencing reads are shown aligned under the CRISPR arrays in (FIG. 13A) and upstream from the effector in (FIG. 13B). Transcriptomic coverage for the regions showing expression is illustrated above the contig sequence. (FIG. 13A) Shows the genomic context of the SMART II MG35-419 effector and CRISPR loci encoded in the vicinity. (FIG. 13B) Shows the genomic context of the SMART II effector MG35-3 showing a transcribed 5′ UTR.

FIG. 14 shows a 3D structural prediction for SMART II MG35-419. This 3D model aligns well with regions of the SaCas9 crystal structure, despite being less than half its size. Regions that aligned with the SaCas9 template include the catalytic lobe (RuvC-I, HNH and RuvC-III domains) and a short region of the recognition (REC) lobe. SMART II-specific domains include a domain containing an RRXRR motif and homology to a Pfam PF14239, and a domain of unknown function.

FIG. 15 depicts results of preliminary cleavage assays for SMART II effectors. MG35-420 (SEQ ID NO: 223) protein preps were tested for cleavage activity in TXTL extracts where the entire locus was expressed. Experiments incubated the protein prep with a PAM library (dsDNA target), a repetitive region predicted in the locus (cr1) in both forward and reverse orientations (fw and rv), and with intergenic regions potentially encoding relevant cofactors. Lanes 2-9 (no cr array): control experiments without a repetitive region. Apo: only protein prep with a target PAM library. Labels 1-2.5 represent seven different intergenic regions. −IG: no intergenic region included as control. PCR gel of the ligation products shows putative cleavage bands (arrows) suggesting dsDNA cleavage.

FIGS. 16A-FIG. 16B depict the genomic context of SMART systems. SMART nucleases are shown as dark grey arrows, other genes are depicted as lighter grey arrows. Domains predicted for all genes in a genomic fragment are shown as grey boxes under the arrows. Environmental expression sequencing reads are shown aligned upstream from the effector. FIG. 16A depicts the genomic context of the SMART II MG35-419 effector. FIG. 16B depicts the genomic context of the SMART II MG35-102 effector.

FIGS. 17A-FIG. 17B depict data demonstrating that MG35-420 is an active dsDNA nuclease. FIG. 17A depicts the genomic context of the MG34-420 effector. The effector is represented by a dark arrow in the reverse orientation, predicted PFAM domains are represented by rectangles below arrows, and intergenic regions possibly encoding guide RNAs are annotated as “IG” on the black line. A CRISPR-like repetitive region is present in the contig. FIG. 17B depicts the results of purified protein preps tested for cleavage activity in TXTL. Experiments incubated purified protein with a PAM library (dsDNA target), a CRISPR-like repetitive region predicted in the locus (cr1) in both forward and reverse orientations (fw and rv), and with intergenic regions potentially encoding relevant cofactors. Lanes 2-9 (no cr array): control experiments without a repetitive region. Apo: only protein prep with a target PAM library. Labels 1-2.5 represent seven different intergenic regions. −IG: no intergenic region included as control. PCR gel of the ligation products shows putative cleavage bands (arrows) suggesting dsDNA cleavage. Bands recovered on lanes labeled “4” represent cleavage bands from incubating the enzyme with the CRISPR-like region and the SMART II 5′ UTR.

FIGS. 18A-FIG. 18B depict the predicted guide RNA for MG35-420. FIG. 18A depicts the genomic context of the MG34-420 effector showing RNASeq reads sequenced from an in vitro transcription reaction of the SMART II effector with its 5′ UTR. The effector is represented by a dark arrow in the reverse orientation, predicted PFAM domains are represented by rectangles below arrows, and a predicted guide RNA is annotated on the black line. FIG. 18B depicts secondary structure representation of the SMART II MG35-420 putative guide RNA.

FIGS. 19A-FIG. 19B depict multiple sequence alignment (MSA) of conserved UTR regions associated with SMART II effectors. FIG. 19A depicts full-length MSA of the region immediately upstream from the start codon of SMART II effectors. Percent identity histogram above the alignment indicates regions of conservation (annotated as 5′ UTR guide RNA, grey arrow). FIG. 19B depicts a highly conserved region within the putative guide RNA encoded sequence. Percent identity histogram and Sequence Logo representation are shown above the alignment. Identical bases are highlighted by black boxes.

FIGS. 20A-FIG. 20B depict data demonstrating that MG35 effectors are active dsDNA nucleases using an sgRNA. FIG. 20A depicts the results of an in vitro cleavage assay. Effectors with (sg) and without (Apo) sgRNA were assayed in in-vitro transcription/translation reactions incubated with a PAM library (dsDNA target). Cleavage products were amplified via PCR (successful RNA guided cleavage by the nuclease produced bands at the expected size; arrows). FIG. 20B depicts target-adjacent motifs (TAMs).

FIGS. 21A-FIG. 21F depict data demonstrating that SMART enzymes are novel nucleases with diverse targeting ability. FIG. 21A depicts the predicted domain architecture of SMART nucleases vs. SpCas9. FIG. 21B depicts the genomic context of the SMART MG102-2 system. The tracrRNA and CRISPR array orientations were confirmed by in vitro cleavage activity with the effector. FIG. 21C depicts the genomic context of the SMART MG34-1 system. Adaptation module genes (Cas1, Cas2, Cas4 and putative Csn2) were identified. Environmental RNASeq reads mapped in the forward orientation to the array and intergenic region encoding a tracrRNA. Other genes encoded in the locus are represented by yellow arrows. The tracrRNA and CRISPR array orientations were confirmed by in vitro cleavage activity with the effector. FIG. 21D depicts the HEARO RNA secondary structure for two active SMART HEARO nucleases. SeqLogo representation of consensus target motif sequences are shown. FIG. 21E depicts a phylogenetic protein tree of SMART nucleases vs. Cas9 and IscB reference sequences. SMART effectors and archaeal Cas9 sequences (teal and violet branches) are distantly related to documented Cas9 reference sequences (Type II-A, II-B, and II-C, grey branches). The tree was inferred from a multiple sequence alignment of the shared RuvC-II/HNH/RuvC-III domains. The SMART MG33 family of nucleases (burgundy branches) clusters with CRISPR Type II-C variant systems, while other CRISPR-associated SMART nucleases (teal branches) cluster with sequences recently classified as Type II-D. SMART HEARO nucleases (lilac branches) cluster with HEARO ORF and IscB sequences. FIG. 21F depicts phylogenetic clades of SMART CRISPR Type II families. The clades are a zoom in representation of the phylogenetic tree depicted in FIG. 21E. Local support values for internal family split nodes are shown and range from 0 to 1. SeqLogo representation of consensus target motif sequences and sgRNA designs from biochemical cleavage activity assays for active SMART nucleases are shown.

FIGS. 22A-FIG. 22D depict data demonstrating that SMART I's are dsDNA nucleases. FIG. 22A depicts a histogram of cut position preference showing that MG34-1 cleaves dsDNA preferentially at position 7 from the PAM. The inset shows that MG34-1 produces a staggered cut, where a cut at position 3 occurs on the target strand (TS), while a cut at positions 6-7 occurs on the non-target strand (NTS). FIG. 22B depicts the distribution of percent DNA cleavage with varying spacer lengths, indicating a preference for 18 bp spacers for MG34-1. FIG. 22C depicts time series cleavage assays for MG34-1, suggesting slower kinetics vs. SpCas9. FIG. 22D depicts a plasmid targeting assay. Left: diagram of the methods show an engineered E. coli strain, which expresses the effector nuclease (MG34-1 or MG34-9) and the sgRNA cofactor. When transformed with a plasmid containing an antibiotic resistance gene with a target or non-target spacer (negative control), growth impairment occurs for the target plasmid. Middle and right: bar graphs indicating approximately 2-fold growth repression for the plasmid encoding the MG34-1 (middle) or MG34-9 (right) enzymes and sgRNA.

FIG. 23 depicts percent amino acid content over the full protein length for a group of SMART HNH endonuclease-associated RNA and ORF (HEARO) (35-1, 35-2, 35-3, 35-6, 35-102, and IscB) and SMART (34-1, 102-2, 102-14, 102-35, 102-45) nucleases. High percent arginine (R) and lysine (K) content is highlighted in green, while low methionine (M) content is highlighted in orange. Percent amino acid content of most proteins in the Uniref50 database (Carugo, vol. 17,12 (2008): 2187-91) was used for comparison.

FIG. 24A depicts a scatterplot of the average amino acid content of proteins in the Uniref50 database (X axis) vs. the percentage of amino acid content in SMART proteins (Y axis). The arginine (R) and lysine (K) content deviates from the linear trend. FIG. 24B depicts a graph showing the ratio of Amino Acid percentages in SMART proteins to the percentages in the Uniref50 database. The mean of all ratios is 0.99, with SD 0.22. Green lines show two standard deviations from the average, assuming normalcy.

FIGS. 25A-FIG. 25D depict data demonstrating that SMART enzymes are dsDNA nucleases. FIG. 25A depicts histograms of cut position preference for three SMART nucleases on the non-target strand (NTS) from next-generation sequencing (NGS). The insets show that SMART nucleases produce a staggered cut, where cleavage at position 3 occurs on the target strand (TS), while cleavage at positions 5-7 from the PAM occur on the NTS. TS cleavage site was determined via Sanger run-off sequencing. FIG. 25B depicts a bar plot of colony forming unit (cfu) measurements (in log-scale) showing E. coli growth repression in the target condition vs. the non-target controls. Plasmid interference assays for each nuclease were done in triplicate along with the SpCas9 positive control. FIG. 25C depicts measurement of in vitro DNA cleavage efficiency with varying spacer lengths, indicating a preference for 18-20 bp spacers for SMART nucleases, while the SMART HEARO 35-1 prefers 24 bp spacers. (*) spacer lengths 14 bp (34-1) and 30 bp (35-1 and 102-2) were not evaluated. FIG. 25D depicts mismatch kill assays indicating high specificity for target spacers at positions −1 to −13 from the PAM. Left: Bar plot of colony forming unit (cfu) measurements (log-scale) showing E. coli growth repression in the target condition vs. a spacer containing mismatches, as well as the non-target controls. Top right: Diagram of the mismatch kill assay. E. coli containing two plasmids for nuclease expression and guide expression are transformed with a library of target plasmids with mismatches in the protospacer. Bottom right: heatmap showing mismatch tolerance at each position of the target spacer. For the target spacer and spacers with tolerated mismatches, growth is expected to be repressed (purple). Positions with required base pairing will not cut efficiently and will be relatively enriched in the output library (yellow). Plasmid interference (kill) assays with the library for each nuclease were done in duplicate.

FIG. 26 depicts data demonstrating that MG102-2 is a highly active nuclease in human cells. Nuclease activity was tested by nucleofecting MG102-2 mRNA and two sgRNA targeting sites in the TRAC locus (guides A1 and B1) with increasing concentrations of sgRNA (150, 300 and 450 pmol/reaction). The mock control represents background editing levels at the target region in the absence of mRNA and guide.

FIG. 27 depicts mismatch kill assays showing the log fold change cleavage activity for spacers with mismatches at each position of the tested spacer for MG102-2 and MG35-1.

FIG. 28 depicts data demonstrating that SMART nucleases do not exhibit activity on ssDNA.

FIG. 29 depicts guide and salt concentration titration for SMART nucleases. In vitro cleavage assays for MG102-2 (lanes 1-6) and SMART HEARO 35-1 (lanes 7-18) show cleavage of target plasmid DNA (at ˜3500 bp) into a linear DNA products (below 2500 bp).

FIGS. 30A-FIG. 30G depict data demonstrating SMART I editing efficiency in human cells. Nuclease activity was tested by nucleofecting SMART I mRNA and sgRNAs (450 pmol/reaction) targeting multiple sites in the locus. Each bar represents editing efficiency at a site targeted by a specific spacer (guides). FIG. 30A depicts data for MG102-2 targeting the AAVS1 locus. FIGS. 30B, 30C, 30D, 30E, 30F, and 30G depict data for MG102-39, MG102-42, MG102-48, MG33-34, MG102-26, and MG102-45 targeting the TRAC locus, respectively.

FIG. 31 depicts multiple sequence alignment of the 5′ UTR nucleotide sequence of four SMART HEARO nucleases. The region preceding the start of the HEARO RNA (box) shows poor similarity, while strong conservation around the first structural hairpin is observed (inset).

FIGS. 32A-FIG. 32G depict the genomic context of SMART HEARO nucleases. While the vast majority of SMART HEARO nucleases are not CRISPR-associated (e.g. MG35-104, FIG. 32A), few SMART HEARO nucleases are associated with CRISPR arrays (e.g. MG35-463 and MG35-556 in FIGS. 32B and 32C). The SMART HEARO nuclease is represented by a dark grey arrow with RRXRR and HNH Pfam domains annotated underneath the gene. HEARO RNAs predicted from covariance models (CM) are shown upstream from the SMART HEARO effector genes (CM HEARO RNA). RAR: repeat-antirepeat. FIGS. 32D-32G depict HEARO RNA secondary structures for three active nucleases: MG35-104 sg1, MG35-463 sg2 (CRISPR-independent), MG35-463 sg3 (CRISPR-associated), and MG35-556 dual guide HEARO RNA (CRISPR-associated), respectively.

FIGS. 33A-FIG. 33C depict SMART HEARO cleavage activity in vitro. SMART II effectors were assayed in in vitro transcription/translation reactions incubated with their single guide RNA and a PAM library (dsDNA target). Cleavage products were amplified via ligation to the cut site and subsequent PCR (successful RNA-guided cleavage by the nuclease produced bands at the expected size: arrows). For FIG. 33A, lane labels are as follows: L: Ladder; PC: MG35-1 nuclease as positive control (PC); 1: MG35-94; 2: MG35-104; 3: MG35-346; 4: MG35-350; 5: MG35-423; 6: MG35-422; 7: MG35-461; 8: MG35-465; 9: MG35-515. For FIG. 33B, lane labels are as follows: L: Ladder; PC: MG35-1 nuclease as positive control (PC); 10: MG35-517; 11: MG35-518 with sgRNA design 1; 12: MG35-518 with sgRNA design 2; 13: MG35-519; 14: MG35-550 with sgRNA design 1; 15: MG35-550 with sgRNA design 2; 16: MG35-553; 17: MG35-554 with sgRNA design 1; 18: MG35-554 with sgRNA design 2; 19: MG35-555; and 20: MG35-556. For FIG. 33C, SMART II effectors were assayed for cleavage activity via a TAM/PAM enrichment protocol. The effectors were expressed in in vitro transcription/translation (IVTT) reactions in the presence of their single guide RNA and then added to a PAM library (dsDNA target). Cleavage products were amplified via ligation to the cut site and subsequent PCR (successful RNA-guided cleavage by the nuclease produced bands at the expected size: arrows). The reaction shown is prior to PCR clean-up, so primers and adapter-dimers bands are observed at sizes <100 bp.

FIG. 34 depicts TAM recognition motifs for active SMART HEARO nucleases. NGS sequencing of the bands identified in FIG. 33A-33C were used to generate the TAMs and preferred cleavage position for each nuclease. The structure of the working guide as predicted by Geneious (Andronescu 2007) is shown inlaid. Cleavage usually occurs between position 5-10 on the non-target strand.

FIGS. 35A-FIG. 35B depict in vitro cleavage efficiency for active SMART HEARO nucleases. For FIG. 35A, cleavage was measured by the supercoiled (uncut) to linear (cut) transition of reaction products and visualized on the Agilent Tapestation. Arrows indicate initial dsDNA product (supercoiled) and dsDNA product after successful targeted cleavage by the enzyme (linearized). PE: PURExpress; sgRNA, single guide RNA. FIG. 35B depicts a barplot representation of the quantification from FIG. 35A. DNA: DNA-only control without RNP reaction (negative control); Apo: RNP reaction without sgRNA added; Holo: RNP reaction with sgRNA.

FIG. 36A-FIG. 36B depicts SMART HEARO guide engineering. Five active SMART HEARO sgRNAs had one or more PolyT tracts in their sequences. Three PolyT mutant sgRNAs were designed per candidate to compare the activity vs. the original guide. Guides were in vitro transcribed and normalized to the same concentration, then used in the in vitro cleavage efficiency reaction. FIG. 36A depicts an example guide RNA with poly-T regions and engineered guide sequences for MG35-518. FIG. 36B depicts cleavage efficiency of engineered SMART HEARO guide RNAs vs. the native guide. Apo: no guide added (negative control); WT: native guide RNA.

FIG. 37A-FIG. 37D depicts phylogenetic analysis of SMART I nucleases. Phylogenetic trees were inferred with FastTree or RAxML from global (g-ins-i) or local (1-ins-i) multiple sequence alignments. To account for phylogenetic uncertainty, six reconstructed sequences were obtained from multiple trees (nodes highlighted with a closed circle: MG34-26, MG34-27, MG34-28, MG34-29, MG34-30 and MG34-31).

FIG. 38 depicts 3D structure prediction of reconstructed SMART I MG34-30 vs. the predicted structure of an active MG34-1 nuclease. Good structural alignment of proteins overall was observed by the overlap between the two structures, as well as by the low RMSD value.

FIG. 39 depicts data demonstrating that reconstructed SMART I effectors are active nucleases. Novel SMART I effectors were assayed for cleavage activity via a PAM enrichment protocol. The effectors were expressed in in vitro transcription/translation (IVTT) reactions in the presence of the single guide RNA from other active MG34 nucleases, and added to a PAM library (dsDNA target). Cleavage products were amplified via ligation to the cut site and subsequent PCR amplification (successful RNA guided cleavage by the nuclease produced bands at the expected 180 bp size: arrows). MG34-27 and MG34-29 showed clear activity with the 3 tested guide RNAs.

FIG. 40 depicts PAM recognition motifs for active SMART I nucleases from computational reconstruction. NGS sequencing of the bands identified in FIG. 39 were used to generate the PAMs and preferred cleavage position for each nuclease. Cleavage occurs between position 6 and 8 from the PAM on the non-target strand.

BRIEF DESCRIPTION OF THE SEQUENCE LISTING

The Sequence Listing filed herewith provides exemplary polynucleotide and polypeptide sequences for use in methods, compositions and systems according to the disclosure. Below are exemplary descriptions of sequences therein.

MG33 Nucleases

SEQ ID NOs: 1, 463-486, 981-988, and 1289-1312 show the full-length peptide sequences of MG33 nucleases.

SEQ ID NOs: 199 and 669-670 show the nucleotide sequence of a tracrRNA predicted to function with an MG33 nuclease.

SEQ ID NOs: 201 and 1003-1005 show the nucleotide sequences of predicted single-guide RNA (sgRNA) sequences predicted to function with an MG33 nuclease. “N”s denote variable residues and non-N-residues represent the scaffold sequence.

SEQ ID NOs: 1023-1028 show PAM sequences compatible with MG33 nucleases.

SEQ ID NOs: 1045-1054 show CRISPR repeats of MG33 nucleases described herein.

MG34 Nucleases

SEQ ID NOs: 2-24, 487-488, and 1313-1321 show the full-length peptide sequences of MG34 nucleases.

SEQ ID NO: 200 shows the nucleotide sequence of a tracrRNA predicted to function with an MG34 nuclease.

SEQ ID NOs: 202, 203, and 613-616 show the nucleotide sequences of predicted single-guide RNA (sgRNA) sequences predicted to function with an MG34 nuclease. “N”s denote variable residues and non-N-residues represent the scaffold sequence.

SEQ ID NOs: 1023-1028 show PAM sequences compatible with MG34 nucleases.

SEQ ID NOs: 1055-1057 show CRISPR repeats of MG34 nucleases described herein.

MG35 Nucleases

SEQ ID NOs: 25-198, 221-459, 489-580, 617-668, and 674-675 show the full-length peptide sequences of MG35 nucleases.

SEQ ID NOs: 460-461 show the nucleotide sequences of MG35 tracrRNAs derived from the same loci as MG35 nucleases.

SEQ ID NOs: 462, 676, and 1229-1230 show CRISPR repeats of MG35 nucleases described herein.

SEQ ID NOs: 677-686, 1006-1012, and 1231-1259 show the nucleotide sequences of MG35 single guide RNAs.

SEQ ID NOs: 687-974 show the nucleotide sequences of MG35 single guide RNA encoding sequences.

SEQ ID NOs: 1029-1034 show PAM sequences compatible with MG35 nucleases.

SEQ ID NOs: 1172-1228 show the nucleotide sequences of loci encoding MG35 nucleases described herein.

MG102 Nucleases

SEQ ID NOs: 581-612, 989-1002, and 1260-1273 show the full-length peptide sequences of MG102 nucleases.

SEQ ID NOs: 672-673 show the nucleotide sequences of MG102 tracrRNAs derived from the same loci as MG102 nucleases

SEQ ID NOs: 205-220 show the sequences of example nuclear localization sequences (NLSs) that can be appended to nucleases according to the disclosure.

SEQ ID NOs: 1013-1022 show the nucleotide sequences of MG102 single guide RNAs.

SEQ ID NOs: 1035-1044 show PAM sequences compatible with MG102 nucleases.

SEQ ID NOs: 1058-1072 show CRISPR repeats of MG102 nucleases described herein.

SEQ ID NO: 1171 shows the nucleotide sequence of a locus encoding an MG102 nuclease described herein.

MG143 Nucleases

SEQ ID NO: 975 shows the full-length peptide sequence of an MG143 nuclease.

SEQ ID NOs: 1073 shows a CRISPR repeat of an MG143 nuclease described herein.

MG144 Nucleases

SEQ ID NOs: 976-979 and 1274-1288 show the full-length peptide sequences of

Mg144 Nucleases.

SEQ ID NOs: 1074-1077 show CRISPR repeats of MG144 nucleases described herein.

MG145 Nucleases

SEQ ID NO: 980 shows the full-length peptide sequence of an MG145 nuclease.

SEQ ID NOs: 1078 shows a CRISPR repeat of an MG145 nuclease described herein.

MG102 TRAC Targeting

SEQ ID NOs: 1079-1082 and 1145-1166 show the DNA sequences of TRAC target sites.

SEQ ID NOs: 1083-1086 and 1123-1144 show the nucleotide sequences of sgRNAs engineered to function with an MG102 nuclease in order to target TRAC.

MG33 TRAC Targeting

SEQ ID NOs: 1167-1168 show the nucleotide sequences of sgRNAs engineered to function with an MG33 nuclease in order to target TRAC.

SEQ ID NOs: 1169-1170 show the DNA sequences of TRAC target sites.

AAVS1 Targeting

SEQ ID NOs: 1087-1104 show the nucleotide sequences of sgRNAs engineered to function with an MG102 nuclease in order to target AAVS1.

SEQ ID NOs: 1105-1122 show the DNA sequences of AAVS1 target sites.

DETAILED DESCRIPTION

While various embodiments of the invention have been shown and described herein, it will be obvious to those skilled in the art that such embodiments are provided by way of example only. Numerous variations, changes, and substitutions may occur to those skilled in the art without departing from the invention. It should be understood that various alternatives to the embodiments of the invention described herein may be employed.

The practice of some methods disclosed herein employ, unless otherwise indicated, techniques of immunology, biochemistry, chemistry, molecular biology, microbiology, cell biology, genomics and recombinant DNA. See for example Sambrook and Green, Molecular Cloning: A Laboratory Manual, 4th Edition (2012); the series Current Protocols in Molecular Biology (F. M. Ausubel, et al. eds.); the series Methods In Enzymology (Academic Press, Inc.), PCR 2: A Practical Approach (M. J. MacPherson, B. D. Hames and G. R. Taylor eds. (1995)), Harlow and Lane, eds. (1988) Antibodies, A Laboratory Manual, and Culture of Animal Cells: A Manual of Basic Technique and Specialized Applications, 6th Edition (R. I. Freshney, ed. (2010)) (which is entirely incorporated by reference herein).

As used herein, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. Furthermore, to the extent that the terms “including”, “includes”, “having”, “has”, “with”, or variants thereof are used in either the detailed description or the claims, such terms are intended to be inclusive in a manner similar to the term “comprising”.

The term “about” or “approximately” means within an acceptable error range for the particular value as determined by one of ordinary skill in the art, which will depend in part on how the value is measured or determined, i.e., the limitations of the measurement system. For example, “about” can mean within one or more than one standard deviation, per the practice in the art. Alternatively, “about” can mean a range of up to 20%, up to 15%, up to 10%, up to 5%, or up to 1% of a given value.

As used herein, a “cell” generally refers to a biological cell. A cell may be the basic structural, functional or biological unit of a living organism. A cell may originate from any organism having one or more cells. Some non-limiting examples include: a prokaryotic cell, eukaryotic cell, a bacterial cell, an archaeal cell, a cell of a single-cell eukaryotic organism, a protozoa cell, a cell from a plant (e.g., cells from plant crops, fruits, vegetables, grains, soy bean, corn, maize, wheat, seeds, tomatoes, rice, cassava, sugarcane, pumpkin, hay, potatoes, cotton, cannabis, tobacco, flowering plants, conifers, gymnosperms, ferns, clubmosses, homworts, liverworts, mosses), an algal cell, (e.g., Botryococcus braunii, Chlamydomonas reinhardtii, Nannochloropsis gaditana, Chlorella pyrenoidosa, Sargassum patens C. Agardh, and the like), seaweeds (e.g., kelp), a fungal cell (e.g., a yeast cell, a cell from a mushroom), an animal cell, a cell from an invertebrate animal (e.g., fruit fly, cnidarian, echinoderm, nematode, etc.), a cell from a vertebrate animal (e.g., fish, amphibian, reptile, bird, mammal), a cell from a mammal (e.g., a pig, a cow, a goat, a sheep, a rodent, a rat, a mouse, a non-human primate, a human, etc.), and etcetera. Sometimes a cell is not originating from a natural organism (e.g., a cell can be synthetically made, sometimes termed an artificial cell).

The term “nucleotide,” as used herein, generally refers to a base-sugar-phosphate combination. A nucleotide may comprise a synthetic nucleotide. A nucleotide may comprise a synthetic nucleotide analog. Nucleotides may be monomeric units of a nucleic acid sequence (e.g., deoxyribonucleic acid (DNA) and ribonucleic acid (RNA)). The term nucleotide may include ribonucleoside triphosphates adenosine triphosphate (ATP), uridine triphosphate (UTP), cytosine triphosphate (CTP), guanosine triphosphate (GTP) and deoxyribonucleoside triphosphates such as dATP, dCTP, dITP, dUTP, dGTP, dTTP, or derivatives thereof. Such derivatives may include, for example, [uS]dATP, 7-deaza-dGTP and 7-deaza-dATP, and nucleotide derivatives that confer nuclease resistance on the nucleic acid molecule containing them. The term nucleotide as used herein may refer to dideoxyribonucleoside triphosphates (ddNTPs) and their derivatives. Illustrative examples of dideoxyribonucleoside triphosphates may include, but are not limited to, ddATP, ddCTP, ddGTP, ddITP, and ddTTP. A nucleotide may be unlabeled or detectably labeled, such as using moieties comprising optically detectable moieties (e.g., fluorophores). Labeling may also be carried out with quantum dots. Detectable labels may include, for example, radioactive isotopes, fluorescent labels, chemiluminescent labels, bioluminescent labels and enzyme labels. Fluorescent labels of nucleotides may include but are not limited fluorescein, 5-carboxyfluorescein (FAM), 2′7′-dimethoxy-4′5-dichloro-6-carboxyfluorescein (JOE), rhodamine, 6-carboxyrhodamine (R6G), N,N,N′,N′-tetramethyl-6-carboxyrhodamine (TAMRA), 6-carboxy-X-rhodamine (ROX), 4-(4′dimethylaminophenylazo) benzoic acid (DABCYL), Cascade Blue, Oregon Green, Texas Red, Cyanine and 5-(2′-aminoethyl)aminonaphthalene-1-sulfonic acid (EDANS). Specific examples of fluorescently labeled nucleotides can include [R6G]dUTP, [TAMRA]dUTP, [R110]dCTP, [R6G]dCTP, [TAMRA]dCTP, [JOE]ddATP, [R6G]ddATP, [FAM]ddCTP, [R110]ddCTP, [TAMRA]ddGTP, [ROX]ddTTP, [dR6G]ddATP, [dR110]ddCTP, [dTAMRA]ddGTP, and [dROX]ddTTP available from Perkin Elmer, Foster City, Calif; FluoroLink DeoxyNucleotides, FluoroLink Cy3-dCTP, FluoroLink Cy5-dCTP, FluoroLink Fluor X-dCTP, FluoroLink Cy3-dUTP, and FluoroLink Cy5-dUTP available from Amersham, Arlington Heights, Ill.; Fluorescein-15-dATP, Fluorescein-12-dUTP, Tetramethyl-rodamine-6-dUTP, IR770-9-dATP, Fluorescein-12-ddUTP, Fluorescein-12-UTP, and Fluorescein-15-2′-dATP available from Boehringer Mannheim, Indianapolis, Ind.; and Chromosome Labeled Nucleotides, BODIPY-FL-14-UTP, BODIPY-FL-4-UTP, BODIPY-TMR-14-UTP, BODIPY-TMR-14-dUTP, BODIPY-TR-14-UTP, BODIPY-TR-14-dUTP, Cascade Blue-7-UTP, Cascade Blue-7-dUTP, fluorescein-12-UTP, fluorescein-12-dUTP, Oregon Green 488-5-dUTP, Rhodamine Green-5-UTP, Rhodamine Green-5-dUTP, tetramethylrhodamine-6-UTP, tetramethylrhodamine-6-dUTP, Texas Red-5-UTP, Texas Red-5-dUTP, and Texas Red-12-dUTP available from Molecular Probes, Eugene, Oreg. Nucleotides can also be labeled or marked by chemical modification. A chemically-modified single nucleotide can be biotin-dNTP. Some non-limiting examples of biotinylated dNTPs can include, biotin-dATP (e.g., bio-N6-ddATP, biotin-14-dATP), biotin-dCTP (e.g., biotin-11-dCTP, biotin-14-dCTP), and biotin-dUTP (e.g., biotin-11-dUTP, biotin-16-dUTP, biotin-20-dUTP). A nucleotide may comprise a nucleotide analog. In some embodiments, nucleotide analogs may comprise structures of natural nucleotides that are modified at any position so as to alter certain chemical properties of the nucleotide yet retain the ability of the nucleotide analog to perform its intended function (e.g. hybridization to other nucleotides in RNA or DNA). Examples of positions of the nucleotide which may be derivatized include the 5 position, e.g., 5-(2-amino)propyl uridine, 5-bromo uridine, 5-propyne uridine, 5-propenyl uridine, etc.; the 6 position, e.g., 6-(2-amino)propyl uridine; the 8-position for adenosine or guanosines, e.g., 8-bromo guanosine, 8-chloro guanosine, 8-fluoroguanosine, etc. Nucleotide analogs also include deaza nucleotides, e.g., 7-deaza-adenosine: O- and N-modified (e.g., alkylated, e.g., N6-methyl adenosine) nucleotides; and other heterocyclically modified nucleotide analogs such as those described in Herdewijn, Antisense Nucleic Acid Drug Dev., 2000 Aug. 10(4):297-310. Nucleotide analogs may also comprise modifications to the sugar portion of the nucleotides. For example the 2′ OH-group may be replaced by a group selected from H, OR, R, F, Cl, Br, I, SH, SR, NH2, NHR, NR2, COOR, or OR, wherein R is substituted or unsubstituted C1-C6 alkyl, alkenyl, alkynyl, aryl, etc. Other possible modifications include those described in U.S. Pat. Nos. 5,858,988, and 6,291,438. Examples of positions of the nucleotide which may be derivatized include the 5 position, e.g., 5-(2-amino)propyl uridine, 5-bromo uridine, 5-propyne uridine, 5-propenyl uridine, etc.; the 6 position, e.g., 6-(2-amino)propyl uridine; the 8-position for adenosine or guanosines, e.g., 8-bromo guanosine, 8-chloro guanosine, 8-fluoroguanosine, etc. Nucleotide analogs also include deaza nucleotides, e.g., 7-deaza-adenosine: O- and N-modified (e.g., alkylated, e.g., N6-methyl adenosine) nucleotides; and other heterocyclically modified nucleotide analogs such as those described in Herdewijn, Antisense Nucleic Acid Drug Dev., 2000 Aug. 10(4):297-310.

Nucleotide analogs may also comprise modifications to the sugar portion of the nucleotides. For example the 2′ OH-group may be replaced by a group selected from H, OR, R, F, Cl, Br, I, SH, SR, NH2, NHR, NR2, COOR, or OR, wherein R is substituted or unsubstituted C1-C6 alkyl, alkenyl, alkynyl, aryl, etc. Other possible modifications include those described in U.S. Pat. Nos. 5,858,988, and 6,291,438.

The terms “polynucleotide,” “oligonucleotide,” and “nucleic acid” are used interchangeably to generally refer to a polymeric form of nucleotides of any length, either deoxyribonucleotides or ribonucleotides, or analogs thereof, either in single-, double-, or multi-stranded form. A polynucleotide may be exogenous or endogenous to a cell. A polynucleotide may exist in a cell-free environment. A polynucleotide may be a gene or fragment thereof. A polynucleotide may be DNA. A polynucleotide may be RNA. A polynucleotide may have any three-dimensional structure and may perform any function. A polynucleotide may comprise one or more analogs (e.g., altered backbone, sugar, or nucleobase). If present, modifications to the nucleotide structure may be imparted before or after assembly of the polymer. Some non-limiting examples of analogs include: 5-bromouracil, peptide nucleic acid, xeno nucleic acid, morpholinos, locked nucleic acids, glycol nucleic acids, threose nucleic acids, dideoxynucleotides, cordycepin, 7-deaza-GTP, fluorophores (e.g., rhodamine or fluorescein linked to the sugar), thiol containing nucleotides, biotin linked nucleotides, fluorescent base analogs, CpG islands, methyl-7-guanosine, methylated nucleotides, inosine, thiouridine, pseudourdine, dihydrouridine, queuosine, and wyosine. Non-limiting examples of polynucleotides include coding or non-coding regions of a gene or gene fragment, loci (locus) defined from linkage analysis, exons, introns, messenger RNA (mRNA), transfer RNA (tRNA), ribosomal RNA (rRNA), short interfering RNA (siRNA), short-hairpin RNA (shRNA), micro-RNA (miRNA), ribozymes, cDNA, recombinant polynucleotides, branched polynucleotides, plasmids, vectors, isolated DNA of any sequence, isolated RNA of any sequence, cell-free polynucleotides including cell-free DNA (cfDNA) and cell-free RNA (cfRNA), nucleic acid probes, and primers. The sequence of nucleotides may be interrupted by non-nucleotide components.

The terms “transfection” or “transfected” generally refer to introduction of a nucleic acid into a cell by non-viral or viral-based methods. The nucleic acid molecules may be gene sequences encoding complete proteins or functional portions thereof. See, e.g., Sambrook et al., 1989, Molecular Cloning: A Laboratory Manual, 18.1-18.88 (which is entirely incorporated by reference herein).

The terms “peptide,” “polypeptide,” and “protein” are used interchangeably herein to generally refer to a polymer of at least two amino acid residues joined by peptide bond(s). This term does not connote a specific length of polymer, nor is it intended to imply or distinguish whether the peptide is produced using recombinant techniques, chemical or enzymatic synthesis, or is naturally occurring. The terms apply to naturally occurring amino acid polymers as well as amino acid polymers comprising at least one modified amino acid. In some cases, the polymer may be interrupted by non-amino acids. The terms include amino acid chains of any length, including full length proteins, and proteins with or without secondary or tertiary structure (e.g., domains). The terms also encompass an amino acid polymer that has been modified, for example, by disulfide bond formation, glycosylation, lipidation, acetylation, phosphorylation, oxidation, and any other manipulation such as conjugation with a labeling component. The terms “amino acid” and “amino acids,” as used herein, generally refer to natural and non-natural amino acids, including, but not limited to, modified amino acids and amino acid analogues. Modified amino acids may include natural amino acids and non-natural amino acids, which have been chemically modified to include a group or a chemical moiety not naturally present on the amino acid. Amino acid analogues may refer to amino acid derivatives. The term “amino acid” includes both D-amino acids and L-amino acids.

As used herein, the term “non-native” can generally refer to a nucleic acid or polypeptide sequence that is not found in a native nucleic acid or protein. Non-native may refer to affinity tags. Non-native may refer to fusions. Non-native may refer to a naturally occurring nucleic acid or polypeptide sequence that comprises mutations, insertions or deletions. A non-native sequence may exhibit or encode for an activity (e.g., enzymatic activity, methyltransferase activity, acetyltransferase activity, kinase activity, ubiquitinating activity, etc.) that may also be exhibited by the nucleic acid or polypeptide sequence to which the non-native sequence is fused. A non-native nucleic acid or polypeptide sequence may be linked to a naturally-occurring nucleic acid or polypeptide sequence (or a variant thereof) by genetic engineering to generate a chimeric nucleic acid or polypeptide sequence encoding a chimeric nucleic acid or polypeptide.

The term “promoter”, as used herein, generally refers to the regulatory DNA region which controls transcription or expression of a gene and which may be located adjacent to or overlapping a nucleotide or region of nucleotides at which RNA transcription is initiated. A promoter may contain specific DNA sequences which bind protein factors, often referred to as transcription factors, which facilitate binding of RNA polymerase to the DNA leading to gene transcription. A ‘basal promoter’, also referred to as a ‘core promoter’, may generally refer to a promoter that contains all the basic elements to promote transcriptional expression of an operably linked polynucleotide. Eukaryotic basal promoters typically, though not necessarily, contain a TATA-box or a CAAT box.

The term “expression”, as used herein, generally refers to the process by which a nucleic acid sequence or a polynucleotide is transcribed from a DNA template (such as into mRNA or other RNA transcript) or the process by which a transcribed mRNA is subsequently translated into peptides, polypeptides, or proteins. Transcripts and encoded polypeptides may be collectively referred to as “gene product.” If the polynucleotide is derived from genomic DNA, expression may include splicing of the mRNA in a eukaryotic cell.

As used herein, “operably linked”, “operable linkage”, “operatively linked”, or grammatical equivalents thereof generally refer to juxtaposition of genetic elements, e.g., a promoter, an enhancer, a polyadenylation sequence, etc., wherein the elements are in a relationship permitting them to operate in the expected manner. For instance, a regulatory element, which may comprise promoter or enhancer sequences, is operatively linked to a coding region if the regulatory element helps initiate transcription of the coding sequence. There may be intervening residues between the regulatory element and coding region so long as this functional relationship is maintained.

A “vector” as used herein, generally refers to a macromolecule or association of macromolecules that comprises or associates with a polynucleotide and which may be used to mediate delivery of the polynucleotide to a cell. Examples of vectors include plasmids, viral vectors, liposomes, and other gene delivery vehicles. The vector generally comprises genetic elements, e.g., regulatory elements, operatively linked to a gene to facilitate expression of the gene in a target.

As used herein, “an expression cassette” and “a nucleic acid cassette” are used interchangeably generally to refer to a combination of nucleic acid sequences or elements that are expressed together or are operably linked for expression. In some cases, an expression cassette refers to the combination of regulatory elements and a gene or genes to which they are operably linked for expression.

A “functional fragment” of a DNA or protein sequence generally refers to a fragment that retains a biological activity (either functional or structural) that is substantially similar to a biological activity of the full-length DNA or protein sequence. A biological activity of a DNA sequence may be its ability to influence expression in a manner attributed to the full-length sequence.

As used herein, an “engineered” object generally indicates that the object has been modified by human intervention. According to non-limiting examples: a nucleic acid may be modified by changing its sequence to a sequence that does not occur in nature; a nucleic acid may be modified by ligating it to a nucleic acid that it does not associate with in nature such that the ligated product possesses a function not present in the original nucleic acid; an engineered nucleic acid may synthesized in vitro with a sequence that does not exist in nature; a protein may be modified by changing its amino acid sequence to a sequence that does not exist in nature; an engineered protein may acquire a new function or property. An “engineered” system comprises at least one engineered component.

As used herein, the term “optimally aligned” generally refers to an alignment of two amino acid sequences that give the highest percent identity score or maximizes the number of matched residues.

As used herein, “synthetic” and “artificial” are used interchangeably to refer to a protein or a domain thereof that has low sequence identity (e.g., less than 50% sequence identity, less than 25% sequence identity, less than 10% sequence identity, less than 5% sequence identity, less than 1% sequence identity) to a naturally occurring human protein. For example, VPR and VP64 domains are synthetic transactivation domains.

The term “tracrRNA” or “tracr sequence”, as used herein, can generally refer to a nucleic acid with at least about 5%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 95%, or 100% sequence identity or sequence similarity to a wild type exemplary tracrRNA sequence (e.g., a tracrRNA from S. pyogenes S. aureus, etc.). tracrRNA can refer to a nucleic acid with at most about 5%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, or 100% sequence identity or sequence similarity to a wild type exemplary tracrRNA sequence (e.g., a tracrRNA from S. pyogenes S. aureus, etc). tracrRNA may refer to a modified form of a tracrRNA that can comprise a nucleotide change such as a deletion, insertion, or substitution, variant, mutation, or chimera. A tracrRNA may refer to a nucleic acid that can be at least about 60% identical to a wild type exemplary tracrRNA (e.g., a tracrRNA from S. pyogenes S. aureus, etc.) sequence over a stretch of at least 6 contiguous nucleotides. For example, a tracrRNA sequence can be at least about 60% identical, at least about 65% identical, at least about 70% identical, at least about 75% identical, at least about 80% identical, at least about 85% identical, at least about 90% identical, at least about 95% identical, at least about 98% identical, at least about 99% identical, or 100% identical to a wild type exemplary tracrRNA (e.g., a tracrRNA from S. pyogenes S. aureus, etc.) sequence over a stretch of at least 6 contiguous nucleotides. Type II tracrRNA sequences can be predicted on a genome sequence by identifying regions with complementarity to part of the repeat sequence in an adjacent CRISPR array.

As used herein, a “guide nucleic acid” can generally refer to a nucleic acid that may hybridize to another nucleic acid. A guide nucleic acid may be RNA. A guide nucleic acid may be DNA. The guide nucleic acid may be programmed to bind to a sequence of nucleic acid site-specifically. The nucleic acid to be targeted, or the target nucleic acid, may comprise nucleotides. The guide nucleic acid may comprise nucleotides. A portion of the target nucleic acid may be complementary to a portion of the guide nucleic acid. The strand of a double-stranded target polynucleotide that is complementary to and hybridizes with the guide nucleic acid may be called the complementary strand. The strand of the double-stranded target polynucleotide that is complementary to the complementary strand, and therefore may not be complementary to the guide nucleic acid may be called noncomplementary strand. A guide nucleic acid may comprise a polynucleotide chain and can be called a “single guide nucleic acid.” A guide nucleic acid may comprise two polynucleotide chains and may be called a “double guide nucleic acid.” If not otherwise specified, the term “guide nucleic acid” may be inclusive, referring to both single guide nucleic acids and double guide nucleic acids. A guide nucleic acid may comprise a segment that can be referred to as a “nucleic acid-targeting segment” or a “nucleic acid-targeting sequence.” A nucleic acid-targeting segment may comprise a sub-segment that may be referred to as a “protein binding segment” or “protein binding sequence” or “Cas protein binding segment”.

The term “sequence identity” or “percent identity” in the context of two or more nucleic acids or polypeptide sequences, generally refers to two (e.g., in a pairwise alignment) or more (e.g., in a multiple sequence alignment) sequences that are the same or have a specified percentage of amino acid residues or nucleotides that are the same, when compared and aligned for maximum correspondence over a local or global comparison window, as measured using a sequence comparison algorithm. Suitable sequence comparison algorithms for polypeptide sequences include, e.g., BLASTP using parameters of a wordlength (W) of 3, an expectation (E) of 10, and the BLOSUM62 scoring matrix setting gap costs at existence of 11, extension of 1, and using a conditional compositional score matrix adjustment for polypeptide sequences longer than 30 residues; BLASTP using parameters of a wordlength (W) of 2, an expectation (E) of 1000000, and the PAM30 scoring matrix setting gap costs at 9 to open gaps and 1 to extend gaps for sequences of less than 30 residues (these are the default parameters for BLASTP in the BLAST suite available at https://blast.ncbi.nlm.nih.gov); or CLUSTALW with parameters of the Smith-Waterman homology search algorithm with parameters of a match of 2, a mismatch of −1, and a gap of −1; MUSCLE with default parameters; MAFFT with parameters retree of 2 and maxiterations of 1000; Novafold with default parameters; HMMER hmmalign with default parameters.

As used herein, the term “RuvC_III domain” generally refers to a third discontinuous segment of a RuvC endonuclease domain (the RuvC nuclease domain being comprised of three discontiguous segments, RuvC_I, RuvC_II, and RuvC_III). A RuvC domain or segments thereof (e.g. RuvC_I, RuvC_II, or RuvC_III) can generally be identified by alignment to documented domain sequences, structural alignment to proteins with annotated domains, or by comparison to Hidden Markov Models (HMMs) built based on documented domain sequences (e.g., Pfam HMM PF18541 for RuvC III).

As used herein, the term “HNH domain” generally refers to an endonuclease domain having characteristic histidine and asparagine residues. An HNH domain can generally be identified by alignment to documented domain sequences, structural alignment to proteins with annotated domains, or by comparison to Hidden Markov Models (HMMs) built based on documented domain sequences (e.g., Pfam HMM PF01844 for domain HNH).

As used herein, the term “bridge helix domain” or “BH domain” generally refers to an arginine-rich helix domain present in Cas enzymes that plays an important role in initiating cleavage activity upon binding of target DNA.

As used herein, the term “recognition domain” or “REC domain” generally refers to a domain thought to interact with the repeat:anti-repeat duplex of the gRNA and to mediate the formation of a Cas endonuclease/gRNA complex.

As used herein, the term “wedge domain” or “WED domain” generally refers to a fold comprising a twisted five-stranded beta sheet flanked by four alpha helices, which is generally responsible for the recognition of the distorted repeat: anti-repeat duplex for Cas enzymes. WED domains can be responsible for the recognition of single-guide RNA scaffolds.

As used herein, the term “PAM interacting domain” or “PI domain” generally refers to a domain found in Cas enzymes positioned in the endonuclease-DNA-complex to recognize the PAM sequence on the non-complementary DNA strand of the guide RNA.

Overview

The discovery of new Cas enzymes with unique functionality and structure may offer the potential to further disrupt deoxyribonucleic acid (DNA) editing technologies, improving speed, specificity, functionality, and ease of use. Relative to the predicted prevalence of Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) systems in microbes and the sheer diversity of microbial species, relatively few functionally characterized CRISPR/Cas enzymes exist in the literature. This is partly because a huge number of microbial species may not be readily cultivated in laboratory conditions. Metagenomic sequencing from natural environmental niches that represent large numbers of microbial species may offer the potential to drastically increase the number of new CRISPR/Cas systems documented and speed the discovery of new oligonucleotide editing functionalities. A recent example of the fruitfulness of such an approach is demonstrated by the 2016 discovery of CasX/CasY CRISPR systems from metagenomic analysis of natural microbial communities.

CRISPR/Cas systems are RNA-directed nuclease complexes that have been described to function as an adaptive immune system in microbes. In their natural context, CRISPR/Cas systems occur in CRISPR (clustered regularly interspaced short palindromic repeats) operons or loci, which generally comprise two parts: (i) an array of short repetitive sequences (30-40 bp) separated by equally short spacer sequences, which encode the RNA-based targeting element; and (ii) ORFs encoding the Cas encoding the nuclease polypeptide directed by the RNA-based targeting element alongside accessory proteins/enzymes. Efficient nuclease targeting of a particular target nucleic acid sequence generally requires both (i) complementary hybridization between the first 6-8 nucleic acids of the target (the target seed) and the crRNA guide; and (ii) the presence of a protospacer-adjacent motif (PAM) sequence within a defined vicinity of the target seed (the PAM usually being a sequence not commonly represented within the host genome). Depending on the exact function and organization of the system, CRISPR-Cas systems are commonly organized into 2 classes, 5 types and 16 subtypes based on shared functional characteristics and evolutionary similarity.

Class I CRISPR-Cas systems have large, multisubunit effector complexes, and comprise Types I, III, and IV.

Type I CRISPR-Cas systems are considered of moderate complexity in terms of components. In Type I CRISPR-Cas systems, the array of RNA-targeting elements is transcribed as a long precursor crRNA (pre-crRNA) that is processed at repeat elements to liberate short, mature crRNAs that direct the nuclease complex to nucleic acid targets when they are followed by a suitable short consensus sequence called a protospacer-adjacent motif (PAM). This processing occurs via an endoribonuclease subunit (Cas6) of a large endonuclease complex called Cascade, which also comprises a nuclease (Cas3) protein component of the crRNA-directed nuclease complex. Cas I nucleases function primarily as DNA nucleases.

Type III CRISPR systems may be characterized by the presence of a central nuclease, known as Cas10, alongside a repeat-associated mysterious protein (RAMP) that comprises Csm or Cmr protein subunits. Like in Type I systems, the mature crRNA is processed from a pre-crRNA using a Cas6-like enzyme. Unlike type I and II systems, type III systems appear to target and cleave DNA-RNA duplexes (such as DNA strands being used as templates for an RNA polymerase).

Type IV CRISPR-Cas systems possess an effector complex that comprises a highly reduced large subunit nuclease (csf1), two genes for RAMP proteins of the Cas5 (csf3) and Cas7 (csf2) groups, and, in some cases, a gene for a predicted small subunit; such systems are commonly found on endogenous plasmids.

Class II CRISPR-Cas systems generally have single-polypeptide multidomain nuclease effectors, and comprise Types II, V and VI.

Type II CRISPR-Cas systems are considered the simplest in terms of components. In Type II CRISPR-Cas systems, the processing of the CRISPR array into mature crRNAs does not require the presence of a special endonuclease subunit, but rather a small trans-encoded crRNA (tracrRNA) with a region complementary to the array repeat sequence; the tracrRNA interacts with both its corresponding effector nuclease (e.g. Cas9) and the repeat sequence to form a precursor dsRNA structure, which is cleaved by endogenous RNAse III to generate a mature effector enzyme loaded with both tracrRNA and crRNA. Cas II nucleases are DNA nucleases. Type II effectors generally exhibit a structure comprising a RuvC-like endonuclease domain that adopts the RNase H fold with an unrelated HNH nuclease domain inserted within the folds of the RuvC-like nuclease domain. The RuvC-like domain is responsible for the cleavage of the target (e.g., crRNA complementary) DNA strand, while the HNH domain is responsible for cleavage of the displaced DNA strand.

Type V CRISPR-Cas systems are characterized by a nuclease effector (e.g. Cas12) structure similar to that of Type II effectors, comprising a RuvC-like domain. Similar to Type II, most (but not all) Type V CRISPR systems use a tracrRNA to process pre-crRNAs into mature crRNAs; however, unlike Type II systems which requires RNAse III to cleave the pre-crRNA into multiple crRNAs, type V systems are capable of using the effector nuclease itself to cleave pre-crRNAs. Like Type-II CRISPR-Cas systems, Type V CRISPR-Cas systems are DNA nucleases. Unlike Type II CRISPR-Cas systems, some Type V enzymes (e.g., Cas12a) appear to have a robust single-stranded nonspecific deoxyribonuclease activity that is activated by the first crRNA directed cleavage of a double-stranded target sequence.

Type VI CRISPR-Cas systems have RNA-guided RNA endonucleases. Instead of RuvC-like domains, the single polypeptide effector of Type VI systems (e.g. Cas13) comprises two HEPN ribonuclease domains. Differing from both Type II and V systems, Type VI systems also appear to not need a tracrRNA for processing of pre-crRNA into crRNA. Similar to type V systems, however, some Type VI systems (e.g., C2C2) appear to possess robust single-stranded nonspecific nuclease (ribonuclease) activity activated by the first crRNA directed cleavage of a target RNA.

Because of their simpler architecture, Class II CRISPR-Cas have been most widely adopted for engineering and development as designer nuclease/genome editing applications.

One of the early adaptations of such a system for in vitro use can be found in Jinek et al. (Science. 2012 Aug. 17; 337(6096):816-21, which is entirely incorporated herein by reference). The Jinek study first described a system that involved (i) recombinantly-expressed, purified full-length Cas9 (e.g., a Class II, Type II Cas enzyme) isolated from S. pyogenes SF370, (ii) purified mature −42 nt crRNA bearing a −20 nt 5′ sequence complementary to the target DNA sequence to be cleaved followed by a 3′ tracr-binding sequence (the whole crRNA being in vitro transcribed from a synthetic DNA template carrying a T7 promoter sequence); (iii) purified tracrRNA in vitro transcribed from a synthetic DNA template carrying a T7 promoter sequence, and (iv) Mg²⁺. Jinek later described an improved, engineered system wherein the crRNA of (ii) is joined to the 5′ end of (iii) by a linker (e.g., GAAA) to form a single fused synthetic guide RNA (sgRNA) capable of directing Cas9 to a target by itself (compare top and bottom panel of FIG. 2).

Mali et al. (Science. 2013 Feb. 15; 339(6121): 823-826.), which is entirely incorporated herein by reference, later adapted this system for use in mammalian cells by providing DNA vectors encoding (i) an ORF encoding codon-optimized Cas9 (e.g., a Class II, Type II Cas enzyme) under a suitable mammalian promoter with a C-terminal nuclear localization sequence (e.g., SV40 NLS) and a suitable polyadenylation signal (e.g., TK pA signal); and (ii) an ORF encoding an sgRNA (having a 5′ sequence beginning with G followed by 20 nt of a complementary targeting nucleic acid sequence joined to a 3′ tracr-binding sequence, a linker, and the tracrRNA sequence) under a suitable Polymerase III promoter (e.g., the U6 promoter).

MG Enzymes

In one aspect, the present disclosure provides for an engineered nuclease system. The engineered nuclease system may comprise (a) an endonuclease. In some cases, the endonuclease comprises a RuvC domain and an HNH domain. The endonuclease may be from an uncultivated microorganism. The endonuclease may be a Cas endonuclease. The endonuclease may be a class 2 endonuclease. The endonuclease may be a class 2, type II Cas endonuclease. The engineered nuclease system may comprise (b) an engineered guide ribonucleic acid structure. The engineered guide ribonucleic acid structure may be configured to form a complex with the endonuclease. In some cases, the engineered guide ribonucleic acid structure configured to form a complex with the endonuclease comprises a guide ribonucleic acid sequence. The guide ribonucleic acid sequence may be configured to hybridize to a target deoxyribonucleic acid sequence. In some cases, the engineered guide ribonucleic acid structure configured to form a complex with the endonuclease comprises a tracr ribonucleic acid sequence. The tracr ribonucleic acid sequence may be configured to bind to the endonuclease. In some cases, the endonuclease has a molecular weight of about 120 kDa or less, about 110 kDa or less, about 100 kDa or less, about 90 kDa or less, about 80 kDa or less, about 70 kDa or less, about 60 kDa or less, about 50 kDa or less, about 40 kDa or less, about 30 kDa or less, about 20 kDa or less, or about 10 kDa or less.

In one aspect, the present disclosure provides an engineered nuclease system. The engineered nuclease system may comprise (a) an endonuclease. The endonuclease may comprise a RuvC-1 domain or a RuvC domain. The endonuclease may comprise an HNH domain. The endonuclease may comprise a RuvC-1 domain and an HNH domain. The endonuclease may be a Cas endonuclease. The endonuclease may be a class 2 endonuclease. The endonuclease may be a class 2, type II Cas endonuclease. The engineered nuclease system may comprise (b) an engineered guide ribonucleic acid. The engineered guide ribonucleic acid structure may be configured to form a complex with the endonuclease. The guide ribonucleic acid structure configured to form a complex with the endonuclease may comprise a guide ribonucleic acid sequence. The guide ribonucleic acid sequence may be configured to hybridize to a target deoxyribonucleic acid sequence. The engineered guide ribonucleic acid structure configured to form a complex with the endonuclease may comprise a tracr ribonucleic acid sequence. The tracr ribonucleic acid sequence may be configured to bind to the endonuclease. The endonuclease may comprise a sequence with at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity to any one of 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321. The endonuclease may be an archaeal endonuclease. The endonuclease may be a Class 2, Type II Cas endonuclease. The endonuclease may comprise an arginine rich region comprising an RRxRR motif or a domain with PF14239 homology. The arginine-rich region or domain with PF14239 homology can comprise a sequence with at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity to an arginine rich region or a domain with PF14239 homology of any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof. The domain boundaries of the arginine rich domain or the domain with PF14239 homology can be identified by optimal alignment to MG34-1 or MG34-9. The endonuclease may comprise REC domain. The REC domain can comprise a sequence with at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity to a REC domain of any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof. The domain boundaries of the REC domain can be identified by optimal alignment to MG34-1 or MG34-9. The endonuclease may comprise BH (Bridge Helix) domain. The BH domain can comprise a sequence with at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity to a BH domain of any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof. The domain boundaries of the BH domain can be identified by optimal alignment to MG34-1 or MG34-9.

The endonuclease may comprise WED (wedge) domain. The WED domain can comprise a sequence with at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity to a WED domain of any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof. The domain boundaries of the WED domain can be identified by optimal alignment to MG34-1 or MG34-9. The endonuclease may comprise PI (PAM interacting) domain. The PI domain can comprise a sequence with at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 81%, at least 82%, at least 83%, at least 84%, at least 85%, at least 86%, at least 87%, at least 88%, at least 89%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity to a PI domain of any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof. The domain boundaries of the PI domain can be identified by optimal alignment to MG34-1 or MG34-9.

In some cases, the endonuclease is derived from an uncultivated microorganism. In some cases, the tracr ribonucleic acid sequence comprises a sequence with at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 85%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity to at least 50, at least 60, at least 70, at least 80 consecutive nucleotides from any one of SEQ ID NOs: 199-200, 460-461, or 669-673 or a sequence with at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 85%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity to at least 50, at least 60, at least 70, at least 80 consecutive nucleotides of the nonvariable nucleotides of any one of SEQ ID NOs: 201-203,613-616, 677-686, 1003-1022, or 1231-1259.

In some cases, the guide nucleic acid structure comprises SEQ ID NO: 201. In some cases, the guide nucleic acid structure comprises SEQ ID NO: 202. In some cases, the guide nucleic acid structure comprises SEQ ID NO: 203. In some cases, the guide nucleic acid structure comprises SEQ ID NO: 201-203. In some cases, the guide nucleic acid structure comprises SEQ ID NO: 613. In some cases, the guide nucleic acid structure comprises SEQ ID NO: 614. In some cases, the guide nucleic acid structure comprises SEQ ID NO: 615. In some cases, the guide nucleic acid structure comprises SEQ ID NO: 616.

In one aspect, the present disclosure provides an engineered nuclease system. The engineered nuclease system may comprise (a) an engineered guide ribonucleic acid structure. The engineered guide ribonucleic acid structure may comprise a guide ribonucleic acid sequence. The guide ribonucleic acid sequence may be configured to hybridize to a target deoxyribonucleic acid sequence. The engineered guide ribonucleic acid structure may comprise a tracr ribonucleic acid sequence. The tracr ribonucleic acid sequence may be configured to bind to an endonuclease. In some cases, the tracr ribonucleic acid sequence comprises a sequence with at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 85%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity to at least 50, at least 60, at least 70, at least 80 consecutive nucleotides from any one of SEQ ID NOs: 199-200, 460-461, or 669-673 or a sequence with at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 85%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity to at least 15, at least 20, at least 25, at least 30, at least 35, at least 40, at least 45, at least 50, at least 60, at least 70, at least 80 consecutive nucleotides of the nonvariable nucleotides of any one of SEQ ID NOs: 201-203,613-616, 677-686, 1003-1022, or 1231-1259.

In some cases, the engineered nuclease system comprises an endonuclease. The endonuclease may be a class 2 endonuclease. The endonuclease may be a Cas endonuclease. The endonuclease may be a class 2, Type II Cas endonuclease.

In some cases, the endonuclease has a particular molecular weight range. In some embodiments the endonuclease has a molecular weight of about 120 kDa or less, about 110 kDa or less, about 105 kDa or less, about 100 kDa or less, about 95 kDa or less, about 90 kDa or less, about 95 kDa or less, about 80 kDa or less, about 75 kDa or less, about 70 kDa or less, about 65 kDa or less, about 60 kDa or less, about 55 kDa or less, about 50 kDa or less, about 45 kDa or less, about 40 kDa or less, about 35 kDa or less, about 30 kDa or less, about 25 kDa or less, about 20 kDa or less, about 15 kDa or less, or about 10 kDa or less. In some cases, the engineered guide ribonucleic acid structure comprises at least two ribonucleic acid polynucleotides. In some cases, the endonuclease comprises a particular number of residues. The endonuclease can comprise equal to or fewer than about 1,100 residues, equal to or fewer than about 1,000 residues, equal to or fewer than about 950 residues, equal to or fewer than about 900 residues, equal to or fewer than about 850 residues, equal to or fewer than about 800 residues, equal to or fewer than about 750 residues, equal to or fewer than about 700 residues, equal to or fewer than about 650 residues, equal to or fewer than about 600 residues, equal to or fewer than about 550 residues, equal to or fewer than about 500 residues, equal to or fewer than about 450 residues, equal to or fewer than about 400 residues, or equal to or fewer than about 350 residues. The endonuclease can comprise about 700 to about 1,100 residues. The endonuclease can comprise about 400 to about 600 residues. In some cases, the engineered guide ribonucleic acid structure comprises a single ribonucleic acid polynucleotide. The single ribonucleic acid polynucleotide may comprise the guide ribonucleic acid sequence and the tracr ribonucleic acid sequence.

In some cases, the guide ribonucleic acid sequence is complementary to a prokaryotic, bacterial, archaeal, eukaryotic, fungal, plant, mammalian, or human genomic sequence. In some cases, the guide ribonucleic acid sequence is complementary to a prokaryotic genomic sequence. In some cases, the guide ribonucleic acid sequence is complementary to a bacterial genomic sequence. In some cases, the guide ribonucleic acid sequence is complementary to an archaeal genomic sequence. In some cases, the guide ribonucleic acid sequence is complementary to a eukaryotic genomic sequence. In some cases, the guide ribonucleic acid sequence is complementary to a fungal genomic sequence. In some cases, the guide ribonucleic acid sequence is complementary to a plant genomic sequence. In some cases, the guide ribonucleic acid sequence is complementary to a mammalian genomic sequence. In some cases, the guide ribonucleic acid sequence is complementary to a human genomic sequence.

In some cases, the guide ribonucleic acid targeting sequence or spacer is 10-30 nucleotides in length, or 12-28 nucleotides in length, or 15-24 nucleotides in length. In some cases, the endonuclease comprises one or more nuclear localization sequences (NLSs) proximal to an N- or C-terminus of the endonuclease. In some cases, the NLS comprises a sequence selected from SE ID NOs: 205-220.

TABLE 1

Examples NLS Sequences that may be used with Cas effectors according

to the present disclosure.

SEQ ID

Source
NLS amino acid sequence
NO:

SV40 NLS
PKKKRKV
205

nucleoplasmin
KRPAATKKAGQAKKKK
206

bipartite

c-myc
PAAKRVKLD
207

c-myc
RQRRNELKRSP
208

hnRNPA1 M9
NQSSNFGPMKGGNFGGRSSGPYGGGGQYFAKPRNQGGY
209

Importin-
RMRIZFKNKGKDTAELRRRRVEVSVELRKAKKDEQILKRRNV
210

alpha IBB

domain

Myoma T
VSRKRPRP
211

protein

Myoma T
PPKKARED
212

protein

p53
PQPKKKPL
213

mouse c-abl
SALIKKKKKMAP
214

IV

influenza
DRLRR
215

virus NS1

influenza
PKQKKRK
216

virus NS1

Hepatitis virus
RKLKKKIKKL
217

delta antigen

mouse Mx1
REKKKFLKRR
218

protein

human
KRKGDEVDGVDEVAKKKSKK
219

poly

(ADP-ribose)

polymerase

steroid
RKCLQAGMNLEARKTKK
220

hormone

receptors

glucocorticoid

Included in the current disclosure are variants of any of the enzymes described herein with one or more conservative amino acid substitutions. Such conservative substitutions can be made in the amino acid sequence of a polypeptide without disrupting the three-dimensional structure or function of the polypeptide. Conservative substitutions can be accomplished by substituting amino acids with similar hydrophobicity, polarity, and R chain length for one another. Additionally, or alternatively, by comparing aligned sequences of homologous proteins from different species, conservative substitutions can be identified by locating amino acid residues that have been mutated between species (e.g., non-conserved residues) without altering the basic functions of the encoded proteins. Such conservatively substituted variants may include variants with at least about 20%, at least about 25%, at least about 30%, at least about 35%, at least about 40%, at least about 45%, at least about 50%, at least about 55%, at least about 60%, at least about 65%, at least about 70%, at least about 75%, at least about 80%, at least about 85%, at least about 86%, at least about 87%, at least about 88%, at least about 89%, at least about 90%, at least about 91%, at least about 92%, at least about 93%, at least about 94%, at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99% identity to any one of the endonuclease protein sequences described herein. In some embodiments, such conservatively substituted variants are functional variants. Such functional variants can encompass sequences with substitutions such that the activity of one or more critical active site residues or guide RNA binding residues of the endonuclease are not disrupted. In some embodiments, a functional variant of any of the proteins described herein lacks substitution of at least one of the conserved or functional residues called out in FIG. 4. In some embodiments, a functional variant of any of the proteins described herein lacks substitution of all of the conserved or functional residues called out in FIG. 4. Also provided for by the disclosure herein are altered activity variants of any of the nucleases described herein. Such altered activity variants may comprise an inactivating mutation in one or more catalytic residues identified herein (e.g. in FIG. 4) or generally described for RuvC domains. Such altered activity variants may comprise a change-switch mutation in a catalytic residue of a RuvCI, RuvCII, or RuvCIII domain.

Conservative substitution tables providing functionally similar amino acids are available from a variety of references (see, for e.g., Creighton, Proteins: Structures and Molecular Properties (W H Freeman & Co.; 2nd edition (December 1993)). The following eight groups each contain amino acids that are conservative substitutions for one another:

- 1) Alanine (A), Glycine (G);
- 2) Aspartic acid (D), Glutamic acid (E);
- 3) Asparagine (N), Glutamine (Q);
- 4) Arginine (R), Lysine (K);
- 5) Isoleucine (I), Leucine (L), Methionine (M), Valine (V);
- 6) Phenylalanine (F), Tyrosine (Y), Tryptophan (W);
- 7) Serine (S), Threonine (T); and
- 8) Cysteine (C), Methionine (M)

Included in the current disclosure are variants of any of the endonucleases described herein with sequence identity to particular domains. The domain can be an arginine rich domain (e.g. a domain with PF14239 homology), a REC (recognition) domain, a BH (bridge helix) domain, a WED (wedge) domain, a PI (PAM-interacting) domain, a PF14239 homology domain, or any other domain described herein. In some embodiments, residues encompassing one or more of these domains is identified in a protein by alignment to one of the proteins below (e.g. when one of the proteins below and the protein of interest are optimally aligned), wherein the residue boundaries for example domains are described.

TABLE 2

Example domain boundaries for endonucleases described herein

WED

Domain w/ PF14239

and

RuvC-I
BH
REC
homology
RuvC-II
HNH
RuvC-III
PI

MG34-1
1-41
42-76
77-281
4-65; 123-339
282-323
324-459
460-551
552-747

effector

MG34-9
1-41
42-76
77-280
4-65; 123-338
281-322
323-490
491-582
583-778

effector

In some cases, the engineered nuclease system further comprises a single-stranded DNA repair template. In some cases, the engineered nuclease system further comprises a double-stranded DNA repair template. In some cases, the single- or double-stranded DNA repair template comprises from 5′ to 3′ a first homology arm comprising a sequence of at least 20 nucleotides 5′ to the target deoxyribonucleic acid sequence. In some cases, the single- or double-stranded DNA repair template comprises from 5′ to 3′ a synthetic DNA sequence of at least 10 nucleotides. In some cases, the single- or double-stranded DNA repair template comprises from 5′ to 3′ a second homology arm comprising a sequence of at least 20 nucleotides 3′ to the target sequence. In some cases, the single- or double-stranded DNA repair template comprises from 5′ to 3′: a first homology arm comprising a sequence of at least 20 nucleotides 5′ to the target deoxyribonucleic acid sequence, a synthetic DNA sequence of at least 10 nucleotides, or a second homology arm comprising a sequence of at least 20 nucleotides 3′ to the target sequence.

In some cases, the first homology arm comprises a sequence of at least 10, at least 20, at least 30, at least 40, at least 50, at least 60, at least 70, at least 80, at least 90, at least 100, at least 110, at least 120, at least 130, at least 140, at least 150, at least 175, at least 200, at least 250, at least 300, at least 400, at least 500, at least 750, or at least 1000 nucleotides. In some cases, the engineered nuclease system further comprises a source of Mg²⁺. In some cases, the endonuclease and the tracr ribonucleic acid sequence are derived from distinct bacterial species. In some cases, the endonuclease and the tract ribonucleic acid sequence are derived from distinct bacterial species within a same phylum.

In some cases, the endonuclease comprises a sequence with at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 85%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity to any one of SEQ ID NOs: 1-24 or 462-488. In some cases, the guide RNA structure comprises an RNA sequence predicted to comprise a hairpin. In some cases, the hair pin comprises a stem and a loop. In some cases, the stem comprises at least 12 pairs, at least 14 pairs, at least 16 pairs or at least 18 pairs or ribonucleotides.

In some cases, the guide RNA structure further comprises a second stem and a second loop. In some cases, the second stem comprises at least 5 pairs, at least 6 pairs, at least 7 pairs, at least 8 pairs, at least 9 pairs or at least 10 pairs of ribonucleotides. In some cases, the guide RNA structure further comprises an RNA structure and this RNA structure comprises at least two hairpins. In some cases, the endonuclease comprises a sequence with at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 85%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity to SEQ ID NO: 1 and the guide RNA structure comprises an RNA sequence predicted to comprise at least four hairpins. In some cases, each of these four hairpins comprises a stem and a loop.

In some cases, the engineered nuclease system comprises a sequence at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 85%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% identical to SEQ ID NO: 1. In some cases, the engineered nuclease system comprises the guide RNA structure which comprises a sequence at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 85%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% identical to at least one of SEQ ID NO: 199 or the nonvariable nucleotides of SEQ ID NO: 201.

In some cases, the engineered nuclease system comprises a sequence at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 85%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% identical to any one of SEQ ID NOs: 1-24 or 462-488. In some cases, the engineered nuclease system comprises a sequence at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 85%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% identical to any one of SEQ ID NOs: 199-200, 460-461, or 669-673 or the nonvariable nucleotides of any one of SEQ ID NOs: 201-203,613-616, 677-686, 1003-1022, or 1231-1259.

In some cases, the sequence identity is determined by a BLASTP, CLUSTALW, MUSCLE, MAFFT, or CLUSTALW with the Smith-Waterman homology search algorithm parameters. In some cases, the sequence identity is determined by said BLASTP homology search algorithm using parameters of a wordlength (W) of 3, an expectation (E) of 10, and a BLOSUM62 scoring matrix setting gap costs at existence of 11, extension of 1, and using a conditional compositional score matrix adjustment.

In one aspect, the present disclosure provides an engineered guide RNA comprising (a) a DNA-targeting segment. In some cases, the DNA-targeting segment comprises a nucleotide sequence that is complementary to a target sequence in a target DNA molecule. In some cases, the engineered single guide ribonucleic acid polynucleotide comprises a protein-binding segment. The protein-binding segment comprises two complementary stretches of nucleotides that hybridize to form a double-stranded RNA (dsRNA) duplex. In some cases, the two complementary stretches of nucleotides are covalently linked to one another with intervening nucleotides. In some cases, the engineered guide ribonucleic acid polynucleotide is configured to form a complex with an endonuclease comprising a variant having at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 85%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity to any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof.

In some cases, the DNA-targeting segment is positioned 5′ of both of the two complementary stretches of nucleotides. In some cases, the protein binding segment comprises a sequence at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 85%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% identical to any one of SEQ ID NOs: 199-200, 460-461, 669-673 or the nonvariable nucleotides of any one of SEQ ID NOs: 201-203, 613-616, 677-686, 1003-1022, or 1231-1259. In some cases, a deoxyribonucleic acid polynucleotide encodes the engineered guide ribonucleic acid polynucleotide described herein.

In one aspect, the present disclosure provides a nucleic acid comprising an engineered nucleic acid sequence. In some cases, the engineered nucleic acid sequence is optimized for expression in an organism. In some cases, the nucleic acid encodes an endonuclease. The endonuclease may be a Cas endonuclease. The endonuclease may be a class 2 endonuclease. The endonuclease may be a class 2, type II Cas endonuclease. In some cases, the endonuclease comprises a RuvC domain and an HNH domain. In some cases, the endonuclease is derived from an uncultivated microorganism. In some cases, the endonuclease has a particular molecular weight range. In some embodiments the endonuclease has a molecular weight of about 120 kDa or less, about 110 kDa or less, about 105 kDa or less, about 100 kDa or less, about 95 kDa or less, about 90 kDa or less, about 95 kDa or less, about 80 kDa or less, about 75 kDa or less, about 70 kDa or less, about 65 kDa or less, about 60 kDa or less, about 55 kDa or less, about 50 kDa or less, about 45 kDa or less, about 40 kDa or less, about 35 kDa or less, about 30 kDa or less, about 25 kDa or less, about 20 kDa or less, about 15 kDa or less, or about 10 kDa or less. In some cases, the engineered guide ribonucleic acid structure comprises at least two ribonucleic acid polynucleotides. In some cases, the endonuclease comprises a particular number of residues. The endonuclease can comprise equal to or fewer than about 1,100 residues, equal to or fewer than about 1,000 residues, equal to or fewer than about 950 residues, equal to or fewer than about 900 residues, equal to or fewer than about 850 residues, equal to or fewer than about 800 residues, equal to or fewer than about 750 residues, equal to or fewer than about 700 residues, equal to or fewer than about 650 residues, equal to or fewer than about 600 residues, equal to or fewer than about 550 residues, equal to or fewer than about 500 residues, equal to or fewer than about 450 residues, equal to or fewer than about 400 residues, or equal to or fewer than about 350 residues. The endonuclease can comprise about 700 to about 1,100 residues. The endonuclease can comprise about 400 to about 600 residues. In some cases, the endonuclease comprises SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof having at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 85%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity thereto. In some cases, the endonuclease further comprises a sequence encoding one or more nuclear localization sequences (NLSs) proximal to an N- or C-terminus of said endonuclease. In some cases, the NLS comprises a sequence selected from SEQ ID NOs: 205-220.

In some cases, the organism is prokaryotic, bacterial, eukaryotic, fungal, plant, mammalian, rodent, or human. In some cases, the organism is prokaryotic. In some cases, the organism is bacterial. In some cases, the organism is eukaryotic. In some cases, the organism is fungal. In some cases, the organism is plant. In some cases, the organism is mammalian. In some cases, the organism is rodent. In some cases, the organism is human. Where the organism is prokaryotic or bacterial, then the organism may be a different organism from an organism from which the endonuclease is derived. In some cases, the organisms is not the uncultivated microorganism.

In one aspect, the present disclosure provides a vector which comprises a nucleic acid sequence. In some cases, the nucleic acid sequence encodes an endonuclease. In some cases, the endonuclease is a Cas endonuclease. In some cases, the endonuclease is a class 2 endonuclease. In some cases, the endonuclease is a class 2, type II Case endonuclease. The endonuclease may comprise a RuvC-I domain and an HNH domain. In some cases, the endonuclease is derived from an uncultivated microorganism. In some cases, the endonuclease has a particular molecular weight range. In some embodiments the endonuclease has a molecular weight of about 120 kDa or less, about 110 kDa or less, about 105 kDa or less, about 100 kDa or less, about 95 kDa or less, about 90 kDa or less, about 95 kDa or less, about 80 kDa or less, about 75 kDa or less, about 70 kDa or less, about 65 kDa or less, about 60 kDa or less, about 55 kDa or less, about 50 kDa or less, about 45 kDa or less, about 40 kDa or less, about 35 kDa or less, about 30 kDa or less, about 25 kDa or less, about 20 kDa or less, about 15 kDa or less, or about 10 kDa or less. In some cases, the engineered guide ribonucleic acid structure comprises at least two ribonucleic acid polynucleotides. In some cases, the endonuclease comprises a particular number of residues. The endonuclease can comprise equal to or fewer than about 1,100 residues, equal to or fewer than about 1,000 residues, equal to or fewer than about 950 residues, equal to or fewer than about 900 residues, equal to or fewer than about 850 residues, equal to or fewer than about 800 residues, equal to or fewer than about 750 residues, equal to or fewer than about 700 residues, equal to or fewer than about 650 residues, equal to or fewer than about 600 residues, equal to or fewer than about 550 residues, equal to or fewer than about 500 residues, equal to or fewer than about 450 residues, equal to or fewer than about 400 residues, or equal to or fewer than about 350 residues. The endonuclease can comprise about 700 to about 1,100 residues. The endonuclease can comprise about 400 to about 600 residues.

In some aspects, the present disclosure provides for an endonuclease described herein configured to induce a double stranded break proximal to said target locus 5′ to a protospacer adjacent motif (PAM). The endonuclease can induce a double-stranded break 6-8 nucleotides from the PAM or 7 nucleotides from the PAM. In some aspects, the present disclosure provides for an endonuclease described herein configured to induce a single-stranded break proximal to said target locus 5′ to a protospacer adjacent motif (PAM). The endonuclease can induce a single-stranded break 6-8 nucleotides from the PAM or 7 nucleotides from the PAM. In some cases, an endonuclease configured to induce a single-stranded break comprises an inactivating mutation in one or more catalytic residues of an endonuclease described herein.

In some aspects, the present disclosure provides for an endonuclease system described herein configured to cause a chemical modification of a nucleotide base within or proximal to a target locus targeted by the endonuclease system. In this case, chemical modification of a nucleotide base generally refers to modification of the chemical moiety involved in base-pairing rather than modification of the sugar or phosphate portion of the nucleotide. The chemical modification can comprise deamination of an adenosine or a cytosine nucleotide. In some cases, endonuclease systems configured to cause a chemical modification comprises an endonuclease having a base editor coupled or fused in frame to said endonuclease. The endonuclease to which the base editor is fused or coupled can comprise a deactivating mutation in at least one catalytic residue of the endonuclease (e.g. in the RuvC domain). The base editor can be fused N- or C-terminally to said endonuclease, or linked via chemical conjugation. Base editors can include any adenosine or cytosine deaminases, including but not limited to Adenosine Deaminase RNA Specific 1 (ADAR1), Adenosine Deaminase RNA Specific 2 (ADAR2), Apolipoprotein B MRNA Editing Enzyme Catalytic Subunit 1 (APOBEC1), Apolipoprotein B MRNA Editing Enzyme Catalytic Subunit 2 (APOBEC2), Apolipoprotein B MRNA Editing Enzyme Catalytic Subunit 3A (APOBEC3A), Apolipoprotein B MRNA Editing Enzyme Catalytic Subunit 3B (APOBEC3B), Apolipoprotein B MRNA Editing Enzyme Catalytic Subunit 3C (APOBEC3C), Apolipoprotein B MRNA Editing Enzyme Catalytic Subunit 3D (APOBEC3D), Apolipoprotein B MRNA Editing Enzyme Catalytic Subunit 3F (APOBEC3F), Apolipoprotein B MRNA Editing Enzyme Catalytic Subunit 3G (APOBEC3G), Apolipoprotein B MRNA Editing Enzyme Catalytic Subunit 3H (APOBEC3H), or Apolipoprotein B MRNA Editing Enzyme Catalytic Subunit 4 (APOBEC4), or a functional fragment thereof. The base editor can comprise a yeast, eukaryotic, mammalian, or human base editor.

In some aspects, the present disclosure provides for an endonuclease system described herein configured to cause a chemical modification of histone within or proximal to a target locus targeted by the endonuclease system. In some cases, endonuclease systems configured to cause a chemical modification of a histone comprise an endonuclease having a histone editor coupled or fused in frame to said endonuclease. The histone editor can be coupled or fused N- or C-terminally to the endonuclease. In some embodiments, the chemical modification can comprise methylation, acetylation, demethylation, or deacetylation. The endonuclease to which the histone editor is fused or coupled can comprise a deactivating mutation in at least one catalytic residue of the endonuclease (e.g. in the RuvC domain). The histone editor can comprise a histone methyltransferase (e.g. ASH1L, DOT1L, EHMT1, EHMT2, EZH1, EZH2, MLL, MLL2, MLL3, MLL4, MLL5, NSD1, PRDM2, SET, SETBP1, SETD1A, SETD1B, SETD2, SETD3, SETD4, SETD5, SETD6, SETD7, SETD8, SETD9, SETDB1, SETDB2, SETMAR, SMYD1, SMYD2, SMYD3, SMYD4, SMYD5, SUV39H1, SUV39H2, SUV420H1, or SUV420H2), a histone demethylase (e.g. the KDM1, KDM2, KDM3, KDM4, KDM5, or KDM6 families), a histone acetyltransferase (e.g. GNATs or HAT family acetyltransferases), or a histone deacetylase (e.g. HDAC1, HDAC2, HDAC 3, HDAC4, HDAC5, HDAC6, HDAC7, HDAC8, HDAC9, HDAC10, HDAC11, SIRT1, SIRT2, SIRT3, SIRT4, SIRT5, SIRT6, or SIRT7). The histone editor can comprise a yeast, eukaryotic, mammalian, or human histone editor.

In one aspect, the present disclosure provides a vector comprising the nucleic acid described herein. In some cases, the vector further comprises a nucleic acid encoding an engineered guide ribonucleic acid structure. The engineered guide ribonucleic acid structure may be configured to form a complex with the endonuclease. In some cases, the engineered guide ribonucleic acid structure comprises a guide ribonucleic acid sequence. In some cases, the guide ribonucleic acid sequence is configured to hybridize to a target deoxyribonucleic acid sequence. In some cases, the engineered guide ribonucleic acid structure comprises a tracr ribonucleic acid sequence. In some cases, the tracr ribonucleic acid sequence is configured to bind to the endonuclease. In some cases, the vector is a plasmid, a minicircle, a CELiD, an adeno-associated virus (AAV) derived virion, or a lentivirus.

In one aspect, the present disclosure provides a cell comprising any of the vectors described herein.

In one aspect, the present disclosure provides a method of manufacturing an endonuclease. The method can comprise cultivating any of the cells described herein.

In one aspect, the present disclosure provides a method for binding, cleaving, marking, or modifying a double-stranded deoxyribonucleic acid polynucleotide. The method may comprise contacting the double-stranded deoxyribonucleic acid polynucleotide with an endonuclease. In some cases, the endonuclease is a Cas endonuclease. In some cases, the endonuclease is a class 2 endonuclease. In some cases, the endonuclease is a class 2, type II Cas endonuclease. The endonuclease may complex with an engineered guide ribonucleic acid structure. In some cases, the engineered guide ribonucleic acid structure is configured to bind to the endonuclease and the double-stranded deoxyribonucleic acid polynucleotide. In some cases, the double-stranded deoxyribonucleic acid polynucleotide comprises a protospacer adjacent motif (PAM). In some cases, the endonuclease has a molecular weight of about 120 kDa or less, about 110 kDa or less, about 100 kDa or less, about 90 kDa or less, about 80 kDa or less, about 70 kDa or less, about 60 kDa or less, about 50 kDa or less, about 40 kDa or less, about 30 kDa or less, about 20 kDa or less, or about 10 kDa or less. In some cases, the endonuclease comprises a variant with at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 85%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity to any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof.

In one aspect, the present disclosure provides a method for binding, cleaving, marking, or modifying a double-stranded deoxyribonucleic acid polynucleotide. The method may comprise contacting the double-stranded deoxyribonucleic acid polynucleotide with an endonuclease. In some cases, the endonuclease is a Cas endonuclease. In some cases, the endonuclease is a class 2 endonuclease. In some cases, the endonuclease is a class 2, type II Cas endonuclease. The endonuclease may complex with an engineered guide ribonucleic acid structure. In some cases, the engineered guide ribonucleic acid structure may be configured to bind to the endonuclease and the double-stranded deoxyribonucleic acid polynucleotide. In some cases, the double-stranded deoxyribonucleic acid polynucleotide comprises a protospacer adjacent motif (PAM). In some cases, the PAM is NGG. In some cases, the endonuclease comprises a variant with at least 50%, at least 55%, at least 50%, at least 55%, at least 60%, at least 65%, at least 70%, at least 75%, at least 80%, at least 85%, at least 90%, at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98%, or at least 99% sequence identity to any one of SEQ ID NOs: 1-198, 221-459, 463-612, 617-668, 674-675, 975-1002, 1260-1321, or a variant thereof.

In some cases, the endonuclease is not a Cas9 endonuclease, a Cas14 endonuclease, a Cas12a endonuclease, a Cas12b endonuclease, a Cas 12c endonuclease, a Cas12d endonuclease, a Cas12e endonuclease, a Cas13a endonuclease, a Cas13b endonuclease, a Cas13c endonuclease, or a Cas 13d endonuclease. In some cases, the endonuclease is derived from an uncultivated microorganism. In some cases, the double-stranded deoxyribonucleic acid polynucleotide is a prokaryotic, archaeal, bacterial, eukaryotic, plant, fungal, mammalian, rodent, or human double-stranded deoxyribonucleic acid polynucleotide. In some cases, the double-stranded deoxyribonucleic acid polynucleotide is a prokaryotic, archaeal, or bacterial double-stranded deoxyribonucleic acid polynucleotide from a species other than a species from which the endonuclease is derived.

In one aspect, the present disclosure provides a method of modifying a target nucleic acid locus. The method may comprise delivering to the target nucleic acid locus the engineered nuclease system described herein. In some cases, the endonuclease is configured to form a complex with the engineered guide ribonucleic acid structure. In some cases, the complex is configured such that upon binding of the complex to the target nucleic acid locus, the complex modifies the target nucleic locus. In some cases, modifying the target nucleic acid locus comprises binding, nicking, cleaving, or marking the target nucleic acid locus.

In some cases, the target nucleic acid locus comprises deoxyribonucleic acid (DNA) or ribonucleic acid (RNA). In some cases, the target nucleic acid comprises genomic eukaryotic DNA, viral DNA, or bacterial DNA. In some cases, the target nucleic acid comprises bacterial DNA. The bacterial DNA may be derived from a bacterial species different to a species from which the endonuclease was derived. In some cases, the target nucleic acid locus is in vitro. In some cases, the nucleic acid locus is within a cell. In some cases, the endonuclease and the engineered guide nucleic acid structure are provided encoded on separate nucleic acid molecules. In some cases, the cell is a prokaryotic cell, a bacterial cell, a eukaryotic cell, a fungal cell, a plant cell, an animal cell, a mammalian cell, a rodent cell, a primate cell, or a human cell. In some cases, the cell is derived from a species different to a species from which the endonuclease is derived.

In some cases, delivering the engineered nuclease system to the target nucleic acid locus comprises delivering the nucleic acid described herein or the vector described herein. In some cases, delivering the engineered nuclease system to the target nucleic acid locus comprises delivering a nucleic acid comprising an open reading frame encoding the endonuclease. In some cases, the nucleic acid comprises a promoter to which the open reading frame encoding the endonuclease is operably linked. In some cases, delivering the engineered nuclease system to the target nucleic acid locus comprises delivering a capped mRNA containing the open reading frame encoding said endonuclease. In some cases, delivering the engineered nuclease system to said target nucleic acid locus comprises delivering a translated polypeptide.

In some cases, delivering the engineered nuclease system to the target nucleic acid locus comprises delivering a deoxyribonucleic acid (DNA) encoding the engineered guide ribonucleic acid structure operably linked to a ribonucleic acid (RNA) pol III promoter. In some cases, the endonuclease induces a single-stranded break or a double-stranded break at or proximal to the target locus.

Systems of the present disclosure may be used for various applications, such as, for example, nucleic acid editing (e.g., gene editing), binding to a nucleic acid molecule (e.g., sequence-specific binding). Such systems may be used, for example, for addressing (e.g., removing or replacing) a genetically inherited mutation that may cause a disease in a subject, inactivating a gene in order to ascertain its function in a cell, as a diagnostic tool to detect disease-causing genetic elements (e.g. via cleavage of reverse-transcribed viral RNA or an amplified DNA sequence encoding a disease-causing mutation), as deactivated enzymes in combination with a probe to target and detect a specific nucleotide sequence (e.g. sequence encoding antibiotic resistance int bacteria), to render viruses inactive or incapable of infecting host cells by targeting viral genomes, to add genes or amend metabolic pathways to engineer organisms to produce valuable small molecules, macromolecules, or secondary metabolites, to establish a gene drive element for evolutionary selection, to detect cell perturbations by foreign small molecules and nucleotides as a biosensor.

EXAMPLES
Example 1—Discovery of New Cas Effectors by Metagenomics
Metagenomic Mining

Metagenomic samples were collected from sediment, soil and animal. Deoxyribonucleic acid (DNA) was extracted with a Zymobiomics DNA mini-prep kit and sequenced on an Illumina HiSeq® 2500. Samples were collected with consent of property owners. DNA was extracted from samples using either the Qiagen DNeasy PowerSoil Kit or the ZymoBIOMICS DNA Miniprep Kit. DNA was sent for sequencing library preparation (Illumina TruSeq) and sequencing on an Illumina HiSeq 4000 or Novaseq to the Vincent J. Coates Genomics Sequencing Laboratory at UC Berkeley (paired 150 base pair (bp) reads with a 400-800 bp target insert size). Additionally, publicly available high temperature, as well as soil and ocean metagenomic sequencing data were downloaded from the NCBI SRA. Sequencing reads were trimmed using BBMap (Bushnell B., sourceforge.net/projects/bbmap/) and assembled with Megahit (https://paperpile.com/c/QSZG6K/clMrh). Protein sequences were predicted with Prodigal (https://paperpile.com/c/QSZG6K/BJ6oW). HMM profiles of documented Type II CRISPR nucleases were built and searched against all predicted proteins using HMMER3 (hmmer.org). CRISPR arrays were predicted on assembled contigs with Minced (https://github.com/ctSkennerton/minced or https://paperpile.com/c/QSZG6K/OPC44). Taxonomy was assigned to proteins with Kaiju https://paperpile.com/c/QSZG6K/nMi6k and contig taxonomy was determined by finding the consensus of all encoded proteins.

Predicted and reference (e.g. SpCas9, SaCas9, and AsCas9) Type II effector proteins were aligned with MAFFT (https://paperpile.com/c/QSZG6K/sVHNH) and phylogenetic trees were inferred using FastTree2 (https://paperpile.com/c/QSZG6K/osZNM). Novel families were identified from clades composed of sequences recovered from this study. From within families, candidates were selected if they contained all components for laboratory analysis (i.e. they were found on a well-assembled and annotated contig with a CRISPR array and predicted tracrRNA). Selected representative and reference sequences were aligned using MUSCLE (https://paperpile.com/c/QSZG6K/ITOla) to identify catalytic and PAM interacting residues.

This metagenomic workflow resulted in the delineation of the SMART (SMall ARchaeal-associaTed) endonuclease systems described herein.

Discovery of SMART Endonucleases Containing Active Residue Signatures

Mining of tens of thousands of high quality CRISPR Cas systems assembled from metagenomic data uncovered novel effectors containing both RuvC and HNH domains, but that were of unusually small size (<900 aa) (FIG. 21A). These effector nucleases showed low sequence similarity (<20% amino acid identity) to archaeal Cas9 endonucleases as a reference point. Phylogenetic analysis of effector protein sequences indicated that the SMART systems are a divergent group relative to well-studied Type II systems from subtype A, B, or C (FIGS. 1A and 21B).

These compact “SMART” effectors (˜400-1000 amino acids, FIG. 2) appeared in loci in the genome adjacent to CRISPR arrays. Some of these adjacent SMART loci also included sequences predicted to encode tracrRNAs and the CRISPR adaptation genes (e.g. genes involved in spacer acquisition) cas1, cas2, or cas4 within the same operon (FIGS. 3 and 21A). Despite their compact size, SMART effectors contain six putative HNH and RuvC catalytic residues when aligned with a reference SaCas9 sequence (FIG. 4). In addition, 3D structure predictions identified residues involved in guide and target binding, as well as in recognition of a PAM, suggesting that that the SMART effectors are active dsDNA endonucleases.

Multiple Groups of SMART Endonucleases

Based on the location of important catalytic and binding residues, SMART nucleases comprise three RuvC domains, an arginine rich region usually containing an RRxRR motif (e.g. a domain with PF14239 homology), an HNH endonuclease domain, and a putative recognition domain (FIG. 5 and FIG. 6). These domains share low sequence similarity with reference sequences (FIG. 7). In addition, SMART effectors, as well as reference archaeal sequences, contain RRxRR and zinc-binding ribbon motifs (CX[2-4]C or CX[2-4]H) significantly more frequently than Cas9 nucleases (FIG. 8). In addition, unlike Cas9 effector sequences, most SMART effectors contain significant hits to the Pfam domain PF14239, which is often associated with diverse endonucleases. Based upon differences in SMART effector size, phylogenetic relationship, and both operon and domain architecture, we classified these systems into two primary groups: SMART I and SMART II. The salient features of these groups are outlined in Table 3 below, which also illustrates differences compared to Class 2, Type II A/B/C Cas enzymes.

TABLE 3

Attributes of SMART I and II group enzymes described herein

Attribute
SMART I
SMART II
Type II: A, B, C

Zn-binding residues
yes
yes
no

Bridge helix
yes
no
yes

PAM interacting
yes
no
yes

and WED domain

RRxRR motif
yes
yes
no

REC domain
Novel domain
Novel domain
Cas9 REC

w/homology
at C-terminus
domain

to PF14239

Domain w/
yes
yes
no

PF14239 homology

Monophyletic clade
yes
no
yes

Related to TnpB
yes
yes
yes

Operon contains
no
sometimes
no

IS605 Tns repeats

<900 aa
sometimes
yes
no

CRISPR-associated
yes
sometimes
yes

Contains RuvC and
yes
yes
yes

HNH

Although SMART nucleases contain RuvC and HNH domains as in Cas9, the RuvC-I, bridge helix, and recognition domains align poorly. In order to best understand the evolutionary relationships between SMART nucleases and reference sequences, a multiple sequence alignment of full-length SMART, reference Type II sequences documented and classified (see e.g. Burstein, D. et al. New CRISPR-Cas systems from uncultivated microbes. Nature 2017, 542, 237-241; and Gasiunas, G. et al. A catalogue of biochemically diverse CRISPR-Cas9 orthologs. Nat Commun 2020, 11, 5512, each of which is incorporated by reference in its entirety herein), as well as with >10,300 recently reported Cas9 homologs and IscB sequences (see e.g. Altae-Tran, H. et al. The widespread IS200/605 transposon family encodes diverse programmable RNA-guided endonucleases. Science 2021, 374, 57-65, which is incorporated by reference in its entirety herein) was generated. The trimmed, well-aligned region encompassing the RuvC-II/HNH/RuvC-III domains was retained. Phylogenetic analysis inferred from this final alignment indicated divergent clades of effectors clustering away from documented Cas9 effectors currently classified as II-A, II-B, and II-C (FIG. 21E). Two SMART clades, which were found phylogenetically closer to classified Type II effectors, were more likely to be encoded adjacent to CRISPR arrays (FIGS. 21B, 21C, and 21E). The MG33 family of SMART nucleases clusters with Type II-C2 effectors and greatly expands this clade (FIGS. 21E and 21F, mauve branches). This family contains representatives of 900-1050 aa, the largest of the SMART enzymes, and their length distribution overlaps with the smallest classified Type II-C enzymes. A more distant SMART clade (FIGS. 21E and 21F, teal, green, and yellow branches) contains “early Cas9” sequences, which were recently classified as Type II-D (FIGS. 21E and 21F, light grey branches). These CRISPR systems may generally be referred to collectively as SMARTs.

SMART I Endonucleases

SMART I effectors range between approximately 600 amino acids and 1,050 amino acids in size. Common features in their genomic context were adaptation module genes (e.g. genes involved in spacer acquisition) and predicted tracrRNAs near the CRISPR array, the organization of which resembled Type II and Type V CRISPR systems (FIGS. 3A, 3B and 3C). The RRXRR motif-containing region in SMART I effectors is unique but may play a similar functional role as the arginine-rich bridge helix in Cas9 nucleases. When modeled against the SaCas9 crystal structure, predicted 3D structures of SMART I effectors showed unaligned regions within the recognition lobe (which often contains the Pfam domain PF14239) and RuvC-II domains (FIG. 5). The results indicated that these domains have different origins relative to other Type II effectors. Taken together with their divergent placement in a Type II effector phylogenetic tree and their low sequence similarity to documented Type II effectors (FIGS. 1A and 21B), these results indicate that SMART I endonucleases belong to a new group of Type II CRISPR systems. Following the accepted classification of CRISPR systems, these SMART I systems were classified as Type II-D.

Putative single guide RNAs (sgRNAs) were engineered using environmental RNA expression data for the SMART I MG34-1 system. In addition, multiple sgRNAs designed from SMART I repeat and tracrRNA predictions were tested in vitro in PAM enrichment assays. In the case of SMART I enzymes, optimal identification of PAM sequences was performed using end repair and blunt-end ligation at this stage, suggesting that these enzymes can produce staggered double-stranded DNA breaks. Assays confirmed dsDNA cleavage for MG34-1 (SEQ ID NO: 2), MG34-9 (SEQ ID NO: 9), and MG34-16 (SEQ ID NO: 17) with multiple sgRNA designs (FIG. 7, depicting use of SEQ ID NOs: 612-615). MG34-1 demonstrated a preference for an NGGN PAM for target recognition and cleavage (FIG. 8A), while members of the MG102 family recognize a 3′ NRC PAM for target recognition and cleavage (FIG. 21C). Analysis of the cut site indicated preferential cleavage at position 7 (FIGS. 8B and 22A). These results suggest a novel biochemical mechanism compared with cleavage mechanisms from other Type II enzymes, which preferentially cleave at positions 2-3 from the PAM, supporting a new classification for SMART I CRISPR systems.

Environmental expression data for some SMART I systems confirmed in situ transcription of the CRISPR array and intergenic region encoding the predicted tracrRNA (FIGS. 3B and 3C). Additionally, cases of active CRISPR targeting were evaluated by searching spacer sequences that match other genomic sequences assembled from the same, or related metagenomes. Along these lines, a phage genome being targeted by one of the spacers encoded in a SMART I CRISPR array (FIGS. 3C and 3D) was identified. Analysis of the region adjacent to the target sequence suggests a 3′ PAM sequence containing a GG motif (FIG. 3D). These results indicate that SMART I CRISPR systems are active in their natural environments as RNA guided effectors involved in phage defense, likely functioning as nucleases that cut or degrade targeted DNA or RNA.

SMART I Effectors are Active, RNA Guided dsDNA CRISPR Endonucleases

Putative single guide RNA (sgRNA) were engineered using the environmental RNA expression data for SMART I MG34-1 and MG34-16 systems (FIGS. 3B and 3C, and FIG. 9). In addition, multiple sgRNAs designed from SMART I repeat and tracrRNA predictions were tested in vitro in PAM enrichment assays (FIG. 10). Assays confirmed programmable dsDNA cleavage for MG34-1, MG34-9, and MG34-16 with multiple sgRNA designs (FIG. 10). MG34-1 and MG34-9 require an NGGN PAM for target recognition and cleavage (FIGS. 11A and 11C). Analysis of the cut site indicates preferential cleavage at position 7 (FIGS. 11B and 11C). These results suggest a novel biochemical cleavage mechanism compared with Cas9 enzymes, which preferentially cleave at position 3 from the PAM, and provide further support for a new classification for SMART I CRISPR systems.

PAM enrichment assays without an end repair procedure did not show activity for SMART I nucleases. The requirement for end repair to create blunt-end fragments prior to ligation in the PAM enrichment protocol indicates that these enzymes create a staggered double strand DNA break. A staggered double strand break was confirmed by sequencing of cleavage products of the MG34-1 nuclease (FIG. 22A). These results suggest a novel biochemical cleavage mechanism compared with mechanisms from most documented Type II enzymes, which preferentially cleave at positions 2-3 from the PAM. In vitro cleavage assays with purified protein indicates that MG34-1 is more efficient at targeted DNA cleavage with target guides 18 bp long, and time series cleavage assays indicate that MG34-1 cuts at a slower rate compared with the reference SpCas9 when tested with identical guides (FIGS. 22B and 22C).

Experiments conducted in E. coli showed that the system has the required activity to function as a nuclease in cells. E. coli strains expressing MG34-1 and MG34-9 sgRNAs were transformed with a kanamycin resistance plasmid containing a target for the sgRNA. In the presence of the antibiotic, successful targeting and cutting of the antibiotic resistance plasmid will result in a growth defect. The assay showed an approximately 2-fold to 10-fold growth repression compared with control experiments conducted with a kanamycin resistance plasmid that did not contain a target for the sgRNA (FIGS. 12 and 22D).

SMART II Endonucleases

SMART II effectors have a size distribution that skews smaller (˜400 amino acids-600 amino acids) vs. SMART I effectors. Their genomic context suggested unusual repetitive regions or CRISPR arrays. The non-CRISPR repetitive regions contain direct repeats that range in size from about 10 to over 30 bp. In some cases, these include multiple distinct repeating units. Sometimes, common CRISPR identification algorithms will flag these regions as CRISPR systems; however, closer inspection will reveal that the regions identified as spacer sequences are repeated in the array. The arrays are not immediately adjacent to the effectors, but they are in the same genomic region (FIG. 3A, MG35-236 and FIG. 13A, e.g., >20 kb from the effector gene). SMART II system operons were generally devoid of adaptation module genes (e.g. genes involved in spacer acquisition).

Structural predictions identified characteristic residues of Cas enzymes involved in guide RNA binding, target cleavage, and recognition of and interaction with a PAM, in addition to all six RuvC and HNH nuclease catalytic residues (FIG. 6) often found in class 2, type II Cas effectors. In addition, SMART II effectors contained multiple RRXRR and zinc binding ribbon motifs (CX[2-4]C or CX[2-4]H), which are possibly involved in recognition and binding of a target nucleic acid motif Based on the location of important residues, the predicted domain architecture of SMART II nucleases comprised three RuvC subdomains, an arginine-rich region containing an RRxRR motif (e.g. a domain with PF14239 homology), an HNH endonuclease domain, an unknown domain, and a recognition domain (REC) (FIG. 6). The domain architecture of SMART II effectors differed from the documented domain architecture for Type II Cas9 nucleases (FIG. 6 and FIG. 14).

Environmental transcriptomic data for some SMART II systems confirmed in situ expression of CRISPR arrays and other repetitive regions in the natural environment (FIG. 13A). Transcription of the 5′ untranslated region (UTR) of some SMART II effectors was also observed from environmental expression data (FIGS. 13B and 16), suggesting that this region may be important for either nuclease activity or regulation of the SMART system.

Preliminary in vitro experiments conducted with SMART II effector proteins, repetitive regions, and associated intergenic regions show that these enzymes have the ability to cleave dsDNA, possibly in a programmable manner (FIGS. 15 and 17). Results suggest that SMART II nuclease activity may be RNA or DNA guided, which may require using a repetitive region such as a CRISPR array, or via recognition of features encoded within the loci such as TIR or 5′ UTR. The 5′ UTR of SMART II effectors are actively transcribed in in vitro transcription assays and display high secondary structures (FIG. 18). A multiple sequence alignment of the region immediately upstream from the start codon of SMART II effectors demonstrates blocks of conservation (FIG. 19), suggesting that the 5′ UTR associated with SMART II effectors encodes an RNA guide for the effector to target DNA for cleavage activity.

Recently, short Cas9 homologs were reported to be programmable dsDNA nucleases using a guide RNA encoded in the 5′ UTR region of the effector (Altae-Tran, Kannan, et al. Science 2021). In these systems, a targeting “spacer” was identified upstream from the transcribed 5′ UTR of the effectors, suggesting that SMART II enzymes can be reprogrammed to target and cleave a specific DNA site by adding a “target spacer” to the 5′ end of predicted guide RNAs encoded in their 5′ UTR. Appending a target spacer to the 5′ end of the guide RNA encoded in the 5′ UTR region of SMART II effectors activated the effectors for targeted dsDNA cleavage, with a variety of target-adjacent motifs (TAMs) (FIG. 20).

Some SMART II effectors were observed next to a putative insertion sequence (IS) encoding transposases TnpA and TnpB (FIG. 3A). The ends of the IS were identified as containing terminal inverted repeats (TIR) with predicted hairpin structures, and the target site duplication at which the IS most likely integrated into was also identified). In addition, some SMART II loci encoded putative TIRs flanking the SMART II effector (e.g. FIG. 3).

SMART HEARO Clades Contain Virus-Associated RNA-Guided dsDNA Nucleases

Phylogenetic analysis indicated that SMART nucleases of less than 600 aa in length (FIG. 21E, lilac branches) cluster together with documented IscB sequences (“insertion sequences Cas9-like” (see e.g. Kapitonov, V. V., Makarova, K. S. & Koonin, E. V. ISC, a Novel Group of Bacterial and Archaeal DNA Transposons That Encode Cas9 Homologs. JBacteriol 2016, 198, 797-807, which is incorporated by reference in its entirety herein)) (FIG. 21E, dark gray branches) forming two main clades. Kapitonov and colleagues reported IscB homology with Cas9 based on the presence of RuvC and HNH domains, and subsequently described a PLMP domain in this same group of enzymes (see e.g. Altae-Tran, H. et al. The widespread IS200/605 transposon family encodes diverse programmable RNA-guided endonucleases. Science 2021, 374, 57-65, which is incorporated by reference in its entirety herein). 3D structure prediction was used to show that these proteins contain an arginine rich region usually containing an RRXRR motif. The arginine rich region was suggested to be analogous to the bridge helix in Cas9; however, neither this region nor the RuvC-I domain were found to align well in 3D space with the bridge helix and RuvC-I domains of a reference 3D structure. Such IscB/SMART enzymes lack a PAM interacting domain. Instead, a C-terminal “WED/REC” domain containing Zn-binding ribbon motifs can be involved in target motif recognition. Although protein domains, catalytic residues, and 3D models suggest an evolutionary relationship with Cas9, most IscB/SMART effectors are not CRISPR-associated (e.g. not found proximal to a CRISPR repeat in their genomic context). The group comprising the IscB/SMART systems are generally compact in size (approximately 400 to 600 aa) and are widely distributed in bacterial and archaeal genomes. It was found that over 16% of genomic fragments encoding these effectors were classified as likely viral or prophage-derived, implicating viruses in the evolution of these systems.

Searches for non-coding RNAs (ncRNA) associated with SMART systems found that 65% of IscB/SMART 5′ untranslated regions (UTRs) contain hits to HNH Endonuclease-Associated RNA and ORF (HEARO) RNAs from the RFam database (RF02033). These ncRNAs were first described as highly structured RNAs from a bioinformatics analysis (see e.g. Weinberg, Z., Perreault, J., Meyer, M. M. & Breaker, R. R. Exceptional structured noncoding RNAs revealed by bacterial metagenome analysis. Nature 2009, 462, 656-659, which is incorporated by reference in its entirety herein), but the function of their associated HEARO ORF was not reported (see e.g. Harris, K. A. & Breaker, R. R. Large Noncoding RNAs in Bacteria. Microbiol Spectr 2018, 6, which is incorporated by reference in its entirety herein). It was confirmed that putative HEARO HNH endonuclease ORFs also contain RuvC and HNH catalytic domains and cluster together with IscB/SMART effectors. Therefore, IscB, small SMARTs, and HEARO ORFs represent a large group of non-Cas endonucleases. Recently, it was reported that the 5′ UTR of IscB encodes a single guide RNA required for dsDNA nuclease activity, which the authors refer to as an Omega RNA (see e.g. Altae-Tran, H. et al. The widespread IS200/605 transposon family encodes diverse programmable RNA-guided endonucleases. Science 2021, 374, 57-65, which is incorporated by reference in its entirety herein). In confirmation of the requirement of a guide RNA for function, we observed in situ natural expression of the 5′ UTR of IscB/SMART/HEARO systems, which was recapitulated by in vitro transcription assays. Omega RNA structures share high structure similarity with HEARO RNAs. In recognition of the features that unite IscB/SMART/HEARO systems (broad taxonomic origin and enrichment of arginine residues), as well as of the chronological discovery of the guide RNAs associated to these enzymes, we advocate for a broad functional classification for IscB/SMART/HEARO systems as SMART HEARO (FIG. 21E). We evaluated SMART HEARO cleavage activity in vitro and identified required targeting motifs by reprogramming the 5′ “spacer” region of their HEARO RNA (FIG. 21D), as described by Altae-Tran and Kannan et al (see e.g. Altae-Tran, H. et al. The widespread IS200/605 transposon family encodes diverse programmable RNA-guided endonucleases. Science 2021, 374, 57-65). Moreover, plasmid interference assays in E. coli show that SMART HEARO nucleases are highly active compared to SpCas9 (>570-fold repression for MG35-1 vs. ˜98-fold repression shown by SpCas9, FIG. 25B) and specificity experiments indicate low tolerance for mismatches in the protospacer (FIG. 25D).

Example 2—PAM Sequence Identification/Confirmation for the Endonucleases Described Herein

Putative SMART endonucleases were expressed in an E. coli lysate-based expression system (PURExpress, New England Biolabs). In this system, the endonuclease was codon optimized for E. coli and cloned into a vector with a T7 promoter and C-terminal His tag. The gene was PCR amplified with primer binding sites 150 bp upstream and downstream from the T7 promoter and terminator sequences, respectively. This PCR product was added to NEB PURExpress at 5 nM concentration and expressed for 2 hr at 37° to produce the endonucleases for the PAM assays.

The putative sgRNAs compatible with each SMART Cas enzyme described herein were identified from RNAseq reads assembled to the contig CRISPR locus assembled from sequencing data: secondary structure was determined for the tracr region from RNAseq data along with the repeat sequence from the CRISPR array in the Geneious software package (https://www.geneious.com), and the resulting helix was trimmed and concatenated with a GAAA tetra-loop. Multiple lengths of repeat-anti-repeat helix trimming were tested, as well as different spacer lengths and different tracr termination points (FIG. 12, which demonstrates SEQ ID NOs: 612-615). Each sgRNA was then assembled via assembly PCR, purified with SPRI beads, and in vitro transcribed (IVT) following manufacturer's recommended protocol for short RNA transcripts (HiScribe T7 kit, NEB). RNA transcription reactions were cleaned with the Monarch RNA kit and checked for purity via Tapestation (Agilent).

PAM sequences were determined by sequencing plasmids containing randomly-generated potential PAM sequences that can be cleaved by the putative nucleases. In this system, an E. coli codon optimized nucleotide sequence encoding the putative nuclease was transcribed and translated in vitro from a PCR fragment under control of a T7 promoter. A second PCR fragment with a minimal CRISPR array composed of a T7 promoter followed by a repeat-spacer-repeat sequence was transcribed in the same reaction. Successful expression of the endonuclease and repeat-spacer-repeat sequence in the TXTL system followed by CRISPR array processing provides active in vitro CRISPR nuclease complexes.

A library of target plasmids containing a spacer sequence matching that in the minimal array preceded by 8N mixed degenerate bases (potential PAM sequences) were incubated with the output of the TXTL reaction (10 mM Tris pH 7.5, 100 mM NaCl, and 10 mM MgCl₂with a 5-fold dilution of translated Cas enzyme, 5 nM of an 8N PAM plasmid library, and 50 nM of sgRNA targeting the PAM library). After 1-3 hr, the reaction was stopped, and the DNA was recovered via a DNA clean-up kit. Adapter sequences were blunt-end ligated to DNA with active PAM sequences that had been cleaved by the endonuclease, whereas DNA that had not been cleaved was inaccessible for ligation. DNA segments comprising active PAM sequences were then amplified by PCR with primers specific to the library and the adapter sequence. The PCR amplification products were resolved on a gel to identify amplicons that correspond to cleavage events. The amplified segments of the cleavage reaction were also used as a template for preparation of an NGS library or as a substrate for Sanger sequencing. Sequencing this resulting library, which was a subset of the starting 8N library, revealed sequences with PAM activity compatible with the CRISPR complex. For PAM testing with a processed RNA construct, the same procedure was repeated except that an in vitro transcribed RNA was added along with the plasmid library and the minimal CRISPR array/tracr template was omitted. The following spacer sequence was used as a target in these assays (5′-CGUGAGCCACCACGUCGCAAGCCUCGAC-3′).

Having obtained raw sequencing reads from the PAM assays, reads were filtered by Phred quality score >20. The 24 bp representing the documented DNA sequence from the backbone adjacent to the PAM was used as a reference to find the PAM-proximal region and the 8 bp adjacent were identified as the putative PAM. The distance between the PAM and the ligated adapter was also measured for each read. Reads that did not have an exact match to the reference sequence or adapter sequence were excluded. PAM sequences were filtered by cut site frequency such that PAMs with the most frequent cut site+2 bp were selectively included in the analysis. The filtered list of PAMs was used to generate a sequence logo using Logomaker (Tareen A, Kinney J B. Logomaker: beautiful sequence logos in Python. Bioinformatics. 2020; 36(7):2272-2274, which is incorporated by reference herein).

Example 3—Protocol for Predicted RNA Folding

Predicted RNA folding of the active single RNA sequence is computed at 37° using the method of Andronescu 2007. The color of the bases corresponds to the probability of base pairing of that base, where red is high probability and blue is low probability.

Example 4—In Vitro Cleavage Efficiency

Endonucleases are expressed as His-tagged fusion proteins from an inducible T7 promoter in a protease deficient E. coli B strain. The endonuclease was fused to two nuclear localization signals (N-term NLS nucleoplasmin bipartite and C-term simian virus 40 T-antigen NLS PPKKKRK), a maltose binding protein (MBP) tag, a tobacco etch virus (TEV) protease cleavage site, and a 6×His tag in the following order from N to C termini: 6×His-MBP-TEV-NLS-gene-NLS-STOP. This protein was expressed under a pTac promoter in NEB Iq E. coli by autoinduction media (MagicMedia ThermoFisher), grown at 30° C., and induced at 16° C.

Cells expressing the His-tagged proteins were lysed by sonication and the His-tagged proteins purified by Ni-NTA affinity chromatography on a HisTrap FF column (GE Lifescience) on an AKTA Avant FPLC (GE Lifescience). The eluate was resolved by SDS-PAGE on acrylamide gels (Bio-Rad) and stained with InstantBlue Ultrafast Coomassie (Sigma-Aldrich). Purity was determined using densitometry of the protein band with ImageLab software (Bio-Rad). Purified endonucleases were dialyzed into a storage buffer composed of 50 mM Tris-HCl, 300 mM NaCl, 1 mM TCEP, 5% glycerol; pH 7.5 and stored at −80° C.

Target DNAs containing spacer sequences and PAM sequences (determined e.g., as in Example 2) were constructed by DNA synthesis. A single representative PAM is chosen for testing when the PAM has degenerate bases. The target DNAs are comprised of 2200 bp of linear DNA derived from a plasmid via PCR amplification with a PAM and spacer located 700 bp from one end. Successful cleavage results in fragments of 700 and 1500 bp. The target DNA, in vitro transcribed single RNA, and purified recombinant protein are combined in cleavage buffer (10 mM Tris, 100 mM NaCl, 10 mM MgCl₂) with an excess of protein and RNA and are incubated for 5 minutes to 3 hours, usually 1 hr. The reaction is stopped via addition of RNAse A and incubation at 60 minutes. The reaction is then resolved on a 1.2% TAE agarose gel and the fraction of cleaved target DNA is quantified in ImageLab software.

Example 5—Activity in E. coli

E. coli lacks the capacity to efficiently repair double-stranded DNA breaks. Thus, cleavage of genomic DNA can be a lethal event. Exploiting this phenomenon, endonuclease activity is tested in E. coli by recombinantly expressing an endonuclease and a guide RNA in a target strain with spacer/target and PAM sequences integrated into its genomic DNA.

For testing of nuclease activity in bacterial cells, BL21 (DE3) strains (NEB) were transformed with plasmids containing T7-driven effector and sgRNA (10 ng each plasmid), plated and grown overnight. The resulting colonies were cultured overnight in triplicate, then subcultured in SOB and grown to OD 0.4-0.6. 0.5 OD equivalent of cell culture was made chemocompetent according to standard kit protocol (Zymo Mix and Go kit) and transformed with 130 ng of a kanamycin plasmid either with or without a spacer and PAM in the backbone. After heat shock, transformations were recovered in SOC for 1 hr at 37° C., and nuclease efficiency was determined by a 5-fold dilution series grown on induction media (LB agar plates with antibiotics and 0.05 mM IPTG). Colonies were quantified from the dilution series to measure overall repression due to nuclease-driven plasmid cleavage.

The results for such an assay are shown in FIG. 12. In FIG. 12, panel (A) shows replica plating of E. coli strains demonstrating plasmid cutting; E. coli expressing MG34-1 and a sgRNA were transformed with a kanamycin resistance plasmid containing a target for the sgRNA (+sp). Plate quadrants that show growth impairment (+sp) vs. the negative control (without the target and PAM (−sp)) indicate successful targeting and cleavage by the enzyme. The experiment was replicated twice and performed in triplicate. In FIG. 12, panel B shows graphs of colony forming unit (cfu) measurements from the replica plating experiments in A showing growth repression in the target condition (+sp) vs. the non-target control (−sp), demonstrating the plasmid was cut. In FIG. 12, panel C shows barplots of colony forming unit (cfu) measurements (in log-scale) showing E. coli growth repression in the target condition (white bars) vs. the non-target controls (green bars) for various SMART nucleases. Plasmid interference assays for each nuclease was done in triplicate along with the SpCas9 positive control

Engineered strains with PAM sequences (determined e.g. as in Example 2) integrated into their genomic DNA are transformed with DNA encoding the endonuclease. Transformants are then made chemocompetent and are transformed with 50 ng of guide RNAs (e.g., crRNAs) either specific to the target sequence (“on target”), or non-specific to the target (“non target”). After heat shock, transformations are recovered in SOC for 2 hrs at 37° C. Nuclease efficiency is then determined by a 5-fold dilution series grown on induction media. Colonies are quantified from the dilution series in triplicate.

Example 6—Testing Genome Cleavage Activity of MG CRISPR Complexes in Mammalian Cells

To show targeting and cleavage activity in mammalian cells, the MG Cas effector protein sequences are tested in two mammalian expression vectors: (a) one with a C-terminal SV40 NLS and a 2A-GFP tag, and (b) one with no GFP tag and two SV40 NLS sequences, one on the N-terminus and one on the C-terminus. The NLS sequences comprise any of the NLS sequences described herein. In some instances, nucleotide sequences encoding the endonucleases are codon-optimized for expression in mammalian cells.

The corresponding crRNA sequence with targeting sequence attached is cloned into a second mammalian expression vector. The two plasmids are cotransfected into HEK293T cells. 72 hr after co-transfection of the expression plasmid and a gRNA targeting plasmid into HEK293T cells, the DNA is extracted and used for the preparation of an NGS-library. Percent NHEJ is measured via indels in the sequencing of the target site to demonstrate the targeting efficiency of the enzyme in mammalian cells. At least 10 different target sites are chosen to test each protein's activity.

Example 7—Predicted Activity of MG Families Described Herein

In situ expression and protein sequence analyses indicate that these enzymes are active nucleases. They contain predicted endonuclease-associated domains (matching RRXRR and HNH_endonuclease Pfam domains; FIGS. 2, 3A and 3B), and contain predicted HNH and RuvC catalytic residues (e.g. FIGS. 2, 3A and 3B, rectangles). Furthermore, the presence of an RRXRR motif, found in Ribonuclease H-like protein families, indicates potential RNA targeting or nuclease activity (See FIG. 2).

Expression data confirms in situ natural activity for candidate MG34-1 nuclease, tracrRNA and CRISPR array (FIG. 4).

Example 8—Activity in Mammalian Cells with mRNA Delivery

For genome editing using cell transfection/transformation with mRNA, the coding sequence is mouse or human codon optimized using algorithms from Twist Bioscience or Thermo Fisher Scientific (GeneArt). A cassette is constructed with two nuclear localization signals appended to the coding endonuclease sequence: SV40 and nucleoplasmin at the N and C terminal respectively. Additionally, untranslated regions from human complement 3 (C3) are appended to both the 5′ and 3′ to the coding sequence within the cassette.

This cassette is then cloned into a mRNA production vector upstream of a long poly A stretch. The mRNA construct organization can be as follows: 5′ UTR from C3-SV40 NLS—codon optimized SMART gene—nucleoplasmin NLS—3′ UTR from C3—107 polyA tail. Run-of transcription of the mRNA is then driven by a T7 promoter using an engineered T7 RNA polymerase (Hi-T7: New England Biolabs). 5′ capping of the mRNA occurs co-transcriptionally using CleanCap AG (Trilink Biolabs). mRNA is then purified using MEGAclear Transcription Clean-Up kit (Thermo Fisher Scientific).

Mammalian cells are co-transfected with transcribed mRNA and a set of at least 10 guides targeting a genomic region of interest using Lipofectamine Messenger Max (Thermo Fisher Scientific). Cells are incubated for a period of time (e.g. 48 hours) followed by genomic DNA isolation using a Purelink Genomic DNA extraction kit (Fisher Scientific). The region of interest is amplified using specific primers. Editing is then assessed by Sanger sequencing using Inference of CRISPR Edits and NGS for a thorough analysis of edit outcomes.

Example 9—SMART II Guide RNA Prediction

The region comprising 400 bp immediately upstream from the start codon of SMART II effector sequences was extracted as potentially encoding a guide RNA required for activity (UTR). UTR sequences were aligned with MAFFT (mafft-ginsi algorithm) and regions showing blocks of conservation were annotated as putative guide RNAs.

Example 10—Activity and PAM Determination Assays

The putative guide RNA predicted from RNASeq or from UTR alignment was folded in Geneious. A target spacer was appended to either the 5′ or 3′ end of the guide RNA to design a single guide RNA (sgRNA). The sgRNA was assembled via assembly PCR, purified with SPRI beads, and in vitro transcribed (IVT) following manufacturer's recommended protocol for short RNA transcripts (HiScribe T7 kit, NEB). RNA reactions were cleaned with the Monarch RNA kit and checked for purity via the Tapestation (Agilent).

Cleavage and PAM determination assays were performed with PURExpress (New England Biolabs). Briefly, the protein was codon optimized for E. coli and cloned into a vector with a T7 promoter and C-terminal His tag. The gene was PCR amplified with primer binding sites 150 bp upstream and downstream from the T7 promoter and terminator sequences, respectively. This PCR product was added to NEB PURExpress at 5 nM concentration and expressed for 2 hr at 37° C. After this point, a cleavage reaction was assembled in 10 mM Tris pH 7.5, 100 mM NaCl, and 10 mM MgCl₂with a 5-fold dilution of PURExpress, 5 nM of an 8N PAM plasmid library, and 50 nM of sgRNA targeting the PAM library.

The cleavage products from the PURExpress reactions were recovered via clean up with AMPure SPRI beads (Beckman Coulter). The DNA was blunted via addition of Klenow fragments and dNTPs (New England Biolabs). Blunt-end products were ligated with a 100-fold excess of double stranded adapter sequences and used as template for the preparation of an NGS library, from which PAM requirements were determined from sequence analysis.

Raw NGS reads were filtered by Phred quality score >20. The 24 bp representing the documented DNA sequence from the backbone adjacent to the PAM was used as a reference to find the PAM-proximal region and the 8 bp adjacent were identified as the putative PAM. The distance between the PAM and the ligated adapter was also measured for each read. Reads that did not have an exact match to the reference sequence or adapter sequence were excluded. PAM sequences were filtered by cut site frequency such that PAMs with the most frequent cut site+2 bp were selectively included in the analysis. The filtered list of PAMs was used to generate a sequence logo using Logomaker.

Example 11—SMARTs Amino Acid Composition

To describe the amino acid composition of SMART protein sequences, the percent amino acid content for a group of SMART sequences was calculated as the number of times each residue was observed, divided by the total protein length, times 100. The amino acid composition was then compared to the percent content reported for a large set of protein sequences from the Uniprot50 database (Carugo, Protein Sci. 2008). Both groups of proteins, SMART HEARO and SMART (Type II-D), contain unusually high arginine and lysine amino acids content relative to the content observed in Uniref50 protein sequences (FIG. 23).

On average, the percent arginine and lysine composition of SMARTs deviates from the linear trend observed for other residues in SMART sequences, as well as from the residue composition of proteins in the Uniref50 database (FIG. 24A). In addition, the methionine content of SMARTs was observed to be statistically lower than the content observed in proteins from the Uniref50 database (FIG. 24B).

To describe the physicochemical properties of SMARTs, the isoelectric point, molecular weight, and charge were determined from the sequences with the “protr” and “Peptides” packages in R. The high arginine and lysine content observed in SMART sequences may contribute to the high isoelectric point and charge at neutral pH (Table 4).

TABLE 4

Theoretical properties of SMART family members

length
MW

Charge

Nuclease
(a.a.)
(Da)
pI
at pH 7.2

MG35-1
428
48300.1
11.1
52.6

MG35-2
524
59310.4
10.4
34.3

MG35-3
423
47899.5
10.8
39.8

MG35-6
428
48373.1
10.9
43.6

MG35-102
424
47544.1
10.8
38.7

IscB (Altae-Tran, 2021)
439
49447.5
11.7
47.2

MG34-1
747
86518.4
10.2
46.9

MG102-2
946
107544.0
9.9
38.8

MG102-14
949
108596.1
10.2
50.6

MG102-35
954
108186.4
9.9
38.3

MG102-45
952
107614.8
10.0
40.5

Properties were calculated using the R packages Peptides (The R Journal. 7(1), 4-14 (2015)) and protr (Bioinformatics, 2015 Jun. 1; 31(11):1857-9). pH 7.2 was selected because intracellular pH tends to range between 7.0 and 7.4 (Biochemical Journal, 1988, 250(1): 1-8.)

The high arginine and Zn-binding ribbon motif content of SMART nucleases suggest that these enzymes may contain intrinsically disordered regions, which may add flexibility for the protein to interact with large guide RNAs and target DNA. Intrinsically disordered regions are segments of proteins that lack a stable tertiary structure in their native, unbound state (see e.g. Bitard-Feildel, T., Lamiable, A., Mornon, J.-P. & Callebaut, I. Order in Disorder as Observed by the “Hydrophobic Cluster Analysis” of Protein Sequences. Proteomics 2018, 18, e1800054, which is incorporated by reference in its entirety herein), may be enriched in positively charged arginines that interact with polyanions (such as RNA) (see e.g. Murthy, A. C. et al. Molecular interactions underlying liquid-liquid phase separation of the FUS low complexity domain. Nat Struct Mol Biol 2019, 26, 637-648, which is incorporated by reference in its entirety herein), and may be found as linkers between Zn-binding ribbons to help with “search function” (see e.g. Dyson, H. J. Roles of intrinsic disorder in protein-nucleic acid interactions. Mol Biosyst 2011, 8, 97-104, which is incorporated by reference in its entirety herein), all of which are features observed in SMART nucleases.

Example 12—Mismatch Kill Assay

To determine the specificity of various SMART enzymes, a mismatch kill assay was developed in which E. coli BL21 (DE3) strains (NEB) were transformed with plasmids containing T7 driven effector (ampicillin resistance) and their T7-driven sgRNA (chloramphenicol resistance), plated, and grown overnight. The resulting colonies were made competent and transformed with 100 ng of a kanamycin plasmid in three conditions: a target spacer and PAM in the backbone, a library of 25 plasmids each containing a single mismatch along a 24 nt spacer and constant PAM, or a control plasmid with no spacer or PAM (FIG. 25D). After heat shock, transformations were recovered in SOC medium for 2 h at 37° C. Cultures were plated and grown at 37° C. overnight on induction media (LB agar plates with antibiotics and 0.05 mM IPTG). Plasmids were extracted from the surviving mismatch colonies via miniprep kit (Qiagen). The target region was amplified via PCR and analyzed via NGS. Enriched spacers relative to the untreated library were unable to be recognized and cut by the nucleases, and thus are considered to be regions where the effectors do not tolerate a mismatch. If a mismatch is tolerated, the enzyme is expected to cleave the antibiotic resistance plasmid and growth impairment will be observed. The MG102-2 nuclease was observed to not tolerate mismatches along the first 13 positions of the target plasmid from the PAM, while variable mismatch tolerance was observed from position 14 (FIG. 25D and FIG. 27). These results suggest that the SMART nucleases can be highly specific and do not exhibit collateral ssDNA cleavage (FIG. 28).

Example 13—Human Cell Editing with the SMART Nuclease MG102-2

K562 cells from ATCC were cultured according to ATCC protocols. Two sgRNAs targeting the TRAC locus were designed based off the MG102-2 PAM and chemically synthesized by IDT. For gene editing experiments, 500 ng of in vitro synthesized MG102-2 mRNA and either 150, 300, or 450 pmol of the indicated sgRNA were co-nucleofected in 1.5×10⁵cells using the Lonza 4D Nucleofector (program FF-120). In parallel, cells were nucleofected with neither mRNA nor guide to assess background at sites targeted by TRAC guides. Cells were harvested 72 hours post-electroporation for genomic DNA extraction using QuickExtract (Lucigen #09050) and processed for next-generation sequencing on an Illumina Miseq. Resulting data were analyzed with an indel calculator script.

Delivery of SMART nucleases via mRNA to human cells targeting the T cell receptor alpha constant locus (TRAC) resulted in over 90% editing activity at one of two TRAC target sites with the MG102-2 nuclease (FIG. 26). As observed in in vitro experiments (FIG. 29), increasing the amount of sgRNA improved editing efficiency at both target loci (FIG. 26). Although localization of the MG34-1 system to the nucleus of human cells (fused with nuclear localization signals, NLS) was confirmed, nuclease-induced InDel formation was not detected for this nuclease.

Example 14—Cleavage Preferences of SMART Nucleases

Sequencing the cleavage products of the MG34-1 and MG102-2 nucleases show that these enzymes create a staggered double strand DNA break (FIG. 25A). Analysis of the cut sites indicates selective cleavage at position five to seven from the PAM (FIG. 25A). These results suggest a rarely observed biochemical cleavage mechanism compared with most Cas9 enzymes, which create blunt end, as well as staggered cuts that are preferentially at positions 3 to 5 from the PAM. In vitro cleavage assays with in vitro transcription/translation reactions and with purified protein indicate that MG34-1 and MG102-2 are most efficient with 18 and 20 nucleotide spacers (FIG. 25C). Furthermore, activity was confirmed in vivo using E. coli plasmid interference assays, showing 2-fold (MG34-9) to >500-fold (MG102-2) growth repression for five SMART nucleases with the specified targeting spacer (FIG. 25B).

Example 15—SMART I Enzymes are Active Nucleases in Human Cells

K562 cells purchased from ATCC were cultured according to ATCC protocols. sgRNAs targeting the TRAC or AAVS1 loci were designed based on the PAMs recognized by MG102-2, MG102-36, MG102-39, MG102-42, MG102-45, and MG33-34 and chemically synthesized by IDT. For gene editing experiments, 500 ng of in vitro-synthesized nuclease mRNA and 450 pmol of the indicated sgRNA were co-nucleofected in 1.5×10⁵cells using the Lonza 4D Nucleofector (program FF-120). Cells were harvested 72 hours post-electroporation for genomic DNA extraction using QuickExtract (Lucigen #09050) and processed for amplicon next-generation sequencing on an Illumina Miseq. Resulting data were analyzed with an in-house indel calculator script.

As described elsewhere herein, the SMART I nuclease MG102-2 is active at two target sites in the TRAC locus of the human genome when delivered via mRNA. It was further confirmed that MG102-2 (SEQ ID No: 582) is also active at the AAVS1 locus (a safe harbor locus) in the human genome, with the enzyme's cleavage efficiency as high as 82.6% and >50% editing efficiency at eight different target sites (FIG. 30A). In addition, MG102-39 (SEQ ID No: 993), MG102-42 (SEQ ID No: 996), and MG102-48 (SEQ ID No: 1002) showed cleavage activity >40% at the TRAC locus of the human genome when delivered by mRNA (FIGS. 30B-30D), while MG33-34 (SEQ ID No: 988), MG102-36 (SEQ ID No: 990), and MG102-45 (SEQ ID No: 999) showed cleavage efficiency above background (10%) at the TRAC locus (FIGS. 30E-30G).

TABLE 5

Guide RNA and Targeting Sequences Tested in Example 15

SEQ ID NO
Name
Sequence

1087
MG102-2 AAVS1 A5
mU*mUmC*rUrGrGrGrArGrArGrGrGrUrArGrCrGrCrAr

GrGrGrUrGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1088
MG102-2 AAVS1 H8
mG*mC*mC*rCrUrGrGrGrArArUrArUrArArGrGrUrGrGr

UrCrCrCrGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1089
MG102-2 AAVS1 H9
mA*mU*mG*rCrUrGrUrCrCrUrGrArArGrUrGrGrArCrAr

UrArGrGrGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1090
MG102-2 AAVS1
mC*mU*mA*rGrArGrArGrGrUrArArGrGrGrGrGrGrUrAr

D11
GrGrGrGrGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1091
MG102-2 AAVS1 E7
mA*mG*mG*rArArGrGrArGrGrArGrGrCrCrUrArArGrGr

ArUrGrGrGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1092
MG102-2 AAVS1 D7
mA*mU*mA*rUrCrArGrGrArGrArCrUrArGrGrArArGrGr

ArGrGrArGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1093
MG102-2 AAVS1 B7
mC*mU*mG*rCrCrUrArArCrArGrGrArGrGrUrGrGrGrGr

GrUrUrArGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1094
MG102-2 AAVS1
mG*mC*mA*rArGrArGrGrArUrGrGrArGrArGrGrUrGrGr

D12
CrUrArArGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1095
MG102-2 AAVS1 C8
mG*mA*mG*rGrGrGrArCrArGrArUrArArArArGrUrArCr

CrCrArGrGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1096
MG102-2 AAVS1 A8
mG*mU*mG*rGrCrCrCrCrArCrUrGrUrGrGrGrGrUrGrGr

ArGrGrGrGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1097
MG102-2 AAVS1 G6
mU*mG*mG*rCrUrCrCrArGrGrArArArUrGrGrGrGrGrUr

GrUrGrUrGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1098
MG102-2 AAVS1 E5
mG*mUmG*rGrCrCrArCrUrGrArGrArArCrCrGrGrGrCr

ArGrGrUrGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1099
MG102-2 AAVS1 G7
mU*mC*mU*rGrUrCrArCrCrArArUrCrCrUrGrUrCrCrCrU

rArGrUrGrUrUrUrCrArArUrCrArArArCrUrGrArArArArG

rUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGrU

rCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGrG

rGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUrU

rCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArArA

rGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrArC

rArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1100
MG102-2 AAVS1 C3
mU*mU*mC*rUrCrCrUrCrUrUrGrGrGrArArGrUrGrUrArA

rGrGrArGrUrUrUrCrArArUrCrArArArCrUrGrArArArArG

rUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGrU

rCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGrG

rGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUrU

rCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArArA

rGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrArC

rArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1101
MG102-2 AAVS1 E1
mC*mC*mU*rGrCrCrArGrGrArCrGrGrGrGrCrUrGrGrCr

UrArCrUrGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1102
MG102-2 AAVS1 E2
mA*mA*mA*rUrUrGrGrGrGrArCrUrArGrArArArGrGrUr

GrArArGrGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1103
MG102-2 AAVS1 H6
mG*mG*mG*rUrGrUrGrUrCrArCrCrArGrArUrArArGrGr

ArArUrCrGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1104
MG102-2 AAVS1
mA*mG*mA*rGrGrUrGrArCrCrCrGrArArUrCrCrArCrAr

H11
GrGrArGrGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrCrGrGrArGrGrGrUrGrCrArCrUrCrCrGrGrGrArUrGr

GrGrGrCrArGrUrCrCrCrGrGrCrArCrUrUrGrCrGrUrUrUr

UrCrCrCrCrGrGrCrUrUrArCrGrCrUrUrCrGrGrArArArAr

ArGrGrCrCrCrUrUrCrGrGrCrArCrGrUrCrGrArArArGrAr

CrArGrGrArUrGrUrGrArGrCrCrCrArA*mU*mU*mU

1105
MG102-2 AAVS1 A5
TTCTGGGAGAGGGTAGCGCAGGGT

1106
MG102-2 AAVS1 H8
GCCCTGGGAATATAAGGTGGTCCC

1107
MG102-2 AAVS1 H9
ATGCTGTCCTGAAGTGGACATAGG

1108
MG102-2 AAVS1
CTAGAGAGGTAAGGGGGGTAGGGG

D11

1109
MG102-2 AAVS1 E7
AGGAAGGAGGAGGCCTAAGGATGG

1110
MG102-2 AAVS1 D7
ATATCAGGAGACTAGGAAGGAGGA

1111
MG102-2 AAVS1 B7
CTGCCTAACAGGAGGTGGGGGTTA

1112
MG102-2 AAVS1
GCAAGAGGATGGAGAGGTGGCTAA

D12

1113
MG102-2 AAVS1 C8
GAGGGGACAGATAAAAGTACCCAG

1114
MG102-2 AAVS1 A8
GTGGCCCCACTGTGGGGTGGAGGG

1115
MG102-2 AAVS1 G6
TGGCTCCAGGAAATGGGGGTGTGT

1116
MG102-2 AAVS1 E5
GTGGCCACTGAGAACCGGGCAGGT

1117
MG102-2 AAVS1 G7
TCTGTCACCAATCCTGTCCCTAGT

1118
MG102-2 AAVS1 C3
TTCTCCTCTTGGGAAGTGTAAGGA

1119
MG102-2 AAVS1 E1
CCTGCCAGGACGGGGCTGGCTACT

1120
MG102-2 AAVS1 E2
AAATTGGGGACTAGAAAGGTGAAG

1121
MG102-2 AAVS1 H6
GGGTGTGTCACCAGATAAGGAATC

1122
MG102-2 AAVS1
AGAGGTGACCCGAATCCACAGGAG

H11

1123
MG102-36 TRAC
mG*mC*mC*rArCrUrUrUrCrArGrGrArGrGrArGrGrArUr

D12
UrCrGrGrGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrUrGrUrCrArGrGrCrArCrUrCrCrCrGrGrArUrGrGrGr

GrCrArGrUrCrCrCrGrGrCrUrCrUrUrGrCrGrGrUrUrArCr

CrGrArUrGrCrGrGrCrArArCrGrUrGrUrCrGrArUrGrUrAr

GrCrCrArArCrUrGrCrCrArGrArCrArCrGrUrCrUrUrUrUr

GrArCrArGrGrArUrGrUrGrArGrCrCrCrArU*mUxmU*mU

1124
MG102-36 TRAC F1
mG*mA*mC*rCrCrUrGrCrCrGrUrGrUrArCrCrArGrCrUr

GrArGrArGrUrUrUrCrArArUrCrArArArCrUrGrArArArAr

GrUrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGr

UrCrUrGrUrCrArGrGrCrArCrUrCrCrCrGrGrArUrGrGrGr

GrCrArGrUrCrCrCrGrGrCrUrCrUrUrGrCrGrGrUrUrArCr

CrGrArUrGrCrGrGrCrArArCrGrUrGrUrCrGrArUrGrUrAr

GrCrCrArArCrUrGrCrCrArGrArCrArCrGrUrCrUrUrUrUr

GrArCrArGrGrArUrGrUrGrArGrCrCrCrArU*mU*mU*mU

1125
MG102-36 TRAC H6
mU*mU*mG*rArArGrUrCrCrArUrArGrArCrCrUrCrArUrG

rUrCrUrGrUrUrUrCrArArUrCrArArArCrUrGrArArArArGr

UrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGrUr

CrUrGrUrCrArGrGrCrArCrUrCrCrCrGrGrArUrGrGrGrGr

CrArGrUrCrCrCrGrGrCrUrCrUrUrGrCrGrGrUrUrArCrCr

GrArUrGrCrGrGrCrArArCrGrUrGrUrCrGrArUrGrUrArGr

CrCrArArCrUrGrCrCrArGrArCrArCrGrUrCrUrUrUrUrGr

ArCrArGrGrArUrGrUrGrArGrCrCrCrArU*mU*mU*mU

1126
MG102-39 TRAC F4
mG*mC*mU*rGrCrCrCrUrUrArCrCrUrGrGrGrCrUrGrGr

GrGrArArGrUrUrUrCrArGrUrUrArCrCrCrUrGrArGrArAr

ArUrCrArGrGrCrUrGrArArGrCrUrGrArArArArGrArGrCr

ArUrCrCrGrUrCrCrGrGrArArGrGrUrCrCrArCrUrCrCrGr

GrGrUrUrArGrGrGrCrArGrArUrCrCrGrGrCrUrCrUrUrGr

GrUrCrCrUrCrUrCrCrUrGrGrCrCrCrUrUrUrUrCrGrGrGr

CrUrCrCrGrArGrArGrGrArArGrCrCrUrUrCrCrGrGrCrAr

UrGrUrCrUrUrCrGrGrArCrArGrGrArUrGrUrGrArGrCrCr

UrUrU*mU*mU*mU

1127
MG102-39 TRAC A9
mU*mC*mU*rUrGrGrUrUrUrUrArCrArGrArUrArCrGrArA

rCrCrUrGrUrUrUrCrArGrUrUrArCrCrCrUrGrArGrArArA

rUrCrArGrGrCrUrGrArArGrCrUrGrArArArArGrArGrCrA

rUrCrCrGrUrCrCrGrGrArArGrGrUrCrCrArCrUrCrCrGrG

rGrUrUrArGrGrGrCrArGrArUrCrCrGrGrCrUrCrUrUrGrG

rUrCrCrUrCrUrCrCrUrGrGrCrCrCrUrUrUrUrCrGrGrGrC

rUrCrCrGrArGrArGrGrArArGrCrCrUrUrCrCrGrGrCrArU

rGrUrCrUrUrCrGrGrArCrArGrGrArUrGrUrGrArGrCrCrU

rUrU*mU*mU*mU

1128
MG102-39 TRAC
mG*mG*mC*rCrArCrUrUrUrCrArGrGrArGrGrArGrGrAr

G11
UrUrCrGrGrUrUrUrCrArGrUrUrArCrCrCrUrGrArGrArAr

ArUrCrArGrGrCrUrGrArArGrCrUrGrArArArArGrArGrCr

ArUrCrCrGrUrCrCrGrGrArArGrGrUrCrCrArCrUrCrCrGr

GrGrUrUrArGrGrGrCrArGrArUrCrCrGrGrCrUrCrUrUrGr

GrUrCrCrUrCrUrCrCrUrGrGrCrCrCrUrUrUrUrCrGrGrGr

CrUrCrCrGrArGrArGrGrArArGrCrCrUrUrCrCrGrGrCrAr

UrGrUrCrUrUrCrGrGrArCrArGrGrArUrGrUrGrArGrCrCr

UrUrU*mU*mU*mU

1129
MG102-39 TRAC
mC*mA*mG*rCrCrGrCrArGrCrGrUrCrArUrGrArGrCrAr

C11
GrArUrUrGrUrUrUrCrArGrUrUrArCrCrCrUrGrArGrArAr

ArUrCrArGrGrCrUrGrArArGrCrUrGrArArArArGrArGrCr

ArUrCrCrGrUrCrCrGrGrArArGrGrUrCrCrArCrUrCrCrGr

GrGrUrUrArGrGrGrCrArGrArUrCrCrGrGrCrUrCrUrUrGr

GrUrCrCrUrCrUrCrCrUrGrGrCrCrCrUrUrUrUrCrGrGrGr

CrUrCrCrGrArGrArGrGrArArGrCrCrUrUrCrCrGrGrCrAr

UrGrUrCrUrUrCrGrGrArCrArGrGrArUrGrUrGrArGrCrCr

UrUrU*mU*mU*mU

1130
MG102-39 TRAC B6
mC*mC*mA*rGrGrCrCrArCrArGrCrArCrUrGrUrUrGrCrU

rCrUrUrGrUrUrUrCrArGrUrUrArCrCrCrUrGrArGrArArA

rUrCrArGrGrCrUrGrArArGrCrUrGrArArArArGrArGrCrA

rUrCrCrGrUrCrCrGrGrArArGrGrUrCrCrArCrUrCrCrGrG

rGrUrUrArGrGrGrCrArGrArUrCrCrGrGrCrUrCrUrUrGrG

rUrCrCrUrCrUrCrCrUrGrGrCrCrCrUrUrUrUrCrGrGrGrC

rUrCrCrGrArGrArGrGrArArGrCrCrUrUrCrCrGrGrCrArU

rGrUrCrUrUrCrGrGrArCrArGrGrArUrGrUrGrArGrCrCrU

rUrU*mU*mU*mU

1131
MG102-39 TRAC B5
mG*mU*mC*rUrUrCrUrGrGrArArUrArArUrGrCrUrGrUrU

rGrUrUrGrUrUrUrCrArGrUrUrArCrCrCrUrGrArGrArArA

rUrCrArGrGrCrUrGrArArGrCrUrGrArArArArGrArGrCrA

rUrCrCrGrUrCrCrGrGrArArGrGrUrCrCrArCrUrCrCrGrG

rGrUrUrArGrGrGrCrArGrArUrCrCrGrGrCrUrCrUrUrGrG

rUrCrCrUrCrUrCrCrUrGrGrCrCrCrUrUrUrUrCrGrGrGrC

rUrCrCrGrArGrArGrGrArArGrCrCrUrUrCrCrGrGrCrArU

rGrUrCrUrUrCrGrGrArCrArGrGrArUrGrUrGrArGrCrCrU

rUrU*mU*mU*mU

1132
MG102-39 TRAC G9
mG*mA*mU*rUrGrGrGrUrUrCrCrGrArArUrCrCrUrCrCrU

rCrCrUrGrUrUrUrCrArGrUrUrArCrCrCrUrGrArGrArArA

rUrCrArGrGrCrUrGrArArGrCrUrGrArArArArGrArGrCrA

rUrCrCrGrUrCrCrGrGrArArGrGrUrCrCrArCrUrCrCrGrG

rGrUrUrArGrGrGrCrArGrArUrCrCrGrGrCrUrCrUrUrGrG

rUrCrCrUrCrUrCrCrUrGrGrCrCrCrUrUrUrUrCrGrGrGrC

rUrCrCrGrArGrArGrGrArArGrCrCrUrUrCrCrGrGrCrArU

rGrUrCrUrUrCrGrGrArCrArGrGrArUrGrUrGrArGrCrCrU

rUrU*mU*mU*mU

1133
MG102-39 TRAC D1
mA*mU*mU*rCrUrGrArUrGrUrGrUrArUrArUrCrArCrArG

rArCrArGrUrUrUrCrArGrUrUrArCrCrCrUrGrArGrArArA

rUrCrArGrGrCrUrGrArArGrCrUrGrArArArArGrArGrCrA

rUrCrCrGrUrCrCrGrGrArArGrGrUrCrCrArCrUrCrCrGrG

rGrUrUrArGrGrGrCrArGrArUrCrCrGrGrCrUrCrUrUrGrG

rUrCrCrUrCrUrCrCrUrGrGrCrCrCrUrUrUrUrCrGrGrGrC

rUrCrCrGrArGrArGrGrArArGrCrCrUrUrCrCrGrGrCrArU

rGrUrCrUrUrCrGrGrArCrArGrGrArUrGrUrGrArGrCrCrU

rUrU*mU*mU*mU

1134
MG102-39 TRAC
mA*mC*mA*rGrCrCrGrCrArGrCrGrUrCrArUrGrArGrCr

B11
ArGrArUrGrUrUrUrCrArGrUrUrArCrCrCrUrGrArGrArAr

ArUrCrArGrGrCrUrGrArArGrCrUrGrArArArArGrArGrCr

ArUrCrCrGrUrCrCrGrGrArArGrGrUrCrCrArCrUrCrCrGr

GrGrUrUrArGrGrGrCrArGrArUrCrCrGrGrCrUrCrUrUrGr

GrUrCrCrUrCrUrCrCrUrGrGrCrCrCrUrUrUrUrCrGrGrGr

CrUrCrCrGrArGrArGrGrArArGrCrCrUrUrCrCrGrGrCrAr

UrGrUrCrUrUrCrGrGrArCrArGrGrArUrGrUrGrArGrCrCr

UrUrU*mU*mU*mU

1135
MG102-39 TRAC D4
mA*mA*mA*rGrCrUrGrCrCrCrUrUrArCrCrUrGrGrGrCrU

rGrGrGrGrUrUrUrCrArGrUrUrArCrCrCrUrGrArGrArArA

rUrCrArGrGrCrUrGrArArGrCrUrGrArArArArGrArGrCrA

rUrCrCrGrUrCrCrGrGrArArGrGrUrCrCrArCrUrCrCrGrG

rGrUrUrArGrGrGrCrArGrArUrCrCrGrGrCrUrCrUrUrGrG

rUrCrCrUrCrUrCrCrUrGrGrCrCrCrUrUrUrUrCrGrGrGrC

rUrCrCrGrArGrArGrGrArArGrCrCrUrUrCrCrGrGrCrArU

rGrUrCrUrUrCrGrGrArCrArGrGrArUrGrUrGrArGrCrCrU

rUrU*mU*mU*mU

1136
MG102-39 TRAC F2
mC*mA*mA*rCrArGrUrGrCrUrGrUrGrGrCrCrUrGrGrAr

GrCrArArGrUrUrUrCrArGrUrUrArCrCrCrUrGrArGrArAr

ArUrCrArGrGrCrUrGrArArGrCrUrGrArArArArGrArGrCr

ArUrCrCrGrUrCrCrGrGrArArGrGrUrCrCrArCrUrCrCrGr

GrGrUrUrArGrGrGrCrArGrArUrCrCrGrGrCrUrCrUrUrGr

GrUrCrCrUrCrUrCrCrUrGrGrCrCrCrUrUrUrUrCrGrGrGr

CrUrCrCrGrArGrArGrGrArArGrCrCrUrUrCrCrGrGrCrAr

UrGrUrCrUrUrCrGrGrArCrArGrGrArUrGrUrGrArGrCrCr

UrUrU*mU*mU*mU

1137
MG102-39 TRAC G1
mG*mC*mU*rArGrArCrArUrGrArGrGrUrCrUrArUrGrGr

ArCrUrUrGrUrUrUrCrArGrUrUrArCrCrCrUrGrArGrArAr

ArUrCrArGrGrCrUrGrArArGrCrUrGrArArArArGrArGrCr

ArUrCrCrGrUrCrCrGrGrArArGrGrUrCrCrArCrUrCrCrGr

GrGrUrUrArGrGrGrCrArGrArUrCrCrGrGrCrUrCrUrUrGr

GrUrCrCrUrCrUrCrCrUrGrGrCrCrCrUrUrUrUrCrGrGrGr

CrUrCrCrGrArGrArGrGrArArGrCrCrUrUrCrCrGrGrCrAr

UrGrUrCrUrUrCrGrGrArCrArGrGrArUrGrUrGrArGrCrCr

UrUrU*mU*mU*mU

1138
MG102-42 TRAC
mG*mU*mU*rCrCrGrArArUrCrCrUrCrCrUrCrCrUrGrArA

D10
rArGrUrGrUrUrUrCrArGrCrCrArArCrCrUrGrArArArArG

rGrUrGrGrUrGrArCrUrGrArArArArGrArGrCrCrArCrArG

rCrCrGrGrCrArGrCrCrArGrCrArCrCrCrGrGrGrArArUrG

rGrGrArCrArGrUrUrCrCrCrGrGrCrCrCrUrGrCrArArGrG

rCrArGrCrArCrArGrArGrArArGrCrGrUrGrCrCrGrArArA

rUrGrGrCrGrCrCrGrGrCrUrUrArUrGrUrGrGrUrGrArGrU

rCrCrArUrUrUrArUrU*mU*mU*mU

1139
MG102-42 TRAC
mG*mC*mC*rArCrUrUrUrCrArGrGrArGrGrArGrGrArUr

D12
UrCrGrGrGrUrUrUrCrArGrCrCrArArCrCrUrGrArArArAr

GrGrUrGrGrUrGrArCrUrGrArArArArGrArGrCrCrArCrAr

GrCrCrGrGrCrArGrCrCrArGrCrArCrCrCrGrGrGrArArUr

GrGrGrArCrArGrUrUrCrCrCrGrGrCrCrCrUrGrCrArArGr

GrCrArGrCrArCrArGrArGrArArGrCrGrUrGrCrCrGrArAr

ArUrGrGrCrGrCrCrGrGrCrUrUrArUrGrUrGrGrUrGrArGr

UrCrCrArUrUrUrArUrUmUxmU*mU

1140
MG102-42 TRAC
mC*mA*mG*rGrArGrGrArGrGrArUrUrCrGrGrArArCrCr

E12
CrArArUrGrUrUrUrCrArGrCrCrArArCrCrUrGrArArArAr

GrGrUrGrGrUrGrArCrUrGrArArArArGrArGrCrCrArCrAr

GrCrCrGrGrCrArGrCrCrArGrCrArCrCrCrGrGrGrArArUr

GrGrGrArCrArGrUrUrCrCrCrGrGrCrCrCrUrGrCrArArGr

GrCrArGrCrArCrArGrArGrArArGrCrGrUrGrCrCrGrArAr

ArUrGrGrCrGrCrCrGrGrCrUrUrArUrGrUrGrGrUrGrArGr

UrCrCrArUrUrUrArUrU*mU*mU*mU

1141
MG102-45 TRAC B1
mU*mG*mU*rCrCrCrArCrArGrArUrArUrCrCrArGrArArC

rCrCrUrGrUrUrUrCrArArUrCrArArGrCrUrGrArArArArG

rCrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGrU

rCrUrGrArUrArGrCrCrArUrGrCrArCrUrCrCrGrGrArArU

rGrGrGrGrCrArGrUrUrCrCrGrGrCrUrCrUrUrGrCrGrArC

rUrCrArArUrGrGrGrUrGrUrArUrGrCrUrCrArUrUrGrArG

rCrCrArArCrUrGrUrCrArGrArCrArCrGrUrCrUrCrUrCrUr

GrArGrArCrArGrGrArUrGrUrGrArGrCrCrCrUrUrA*mUx

mU*mU

1142
MG102-45 TRAC
mC*mU*mU*rCrArArGrGrCrCrCrCrUrCrArCrCrUrCrArG

C11
rCrUrGrGrUrUrUrCrArArUrCrArArGrCrUrGrArArArArG

rCrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrCrGrU

rCrUrGrArUrArGrCrCrArUrGrCrArCrUrCrCrGrGrArArU

rGrGrGrGrCrArGrUrUrCrCrGrGrCrUrCrUrUrGrCrGrArC

rUrCrArArUrGrGrGrUrGrUrArUrGrCrUrCrArUrUrGrArG

rCrCrArArCrUrGrUrCrArGrArCrArCrGrUrCrUrCrUrCrUr

GrArGrArCrArGrGrArUrGrUrGrArGrCrCrCrUrUrA*mU*

mU*mU

1143
MG102-48 TRAC A1
mU*mC*mC*rUrCrUrUrGrUrCrCrCrArCrArGrArUrArUrC

rCrArGrGrUrUrUrCrArArUrCrArArCrCrGrGrArArArCrG

rGrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrGrGrU

rCrUrGrArArGrGrArUrGrCrArCrUrCrCrGrGrGrArUrArG

rGrGrCrArGrUrCrCrCrGrGrCrUrCrUrUrGrCrUrGrUrUrU

rCrCrCrCrGrGrUrArArGrArCrCrUrCrGrGrArArGrCrArA

rGrUrCrCrUrUrCrArGrCrArArGrUrCrGrArArArGrArCrA

rCrGrArUrGrUrGrArGrCrCrUrArU*mU*mU*mU

1144
MG102-48 TRAC
mG*mC*mC*rArCrUrUrUrCrArGrGrArGrGrArGrGrArUr

D12
UrCrGrGrGrUrUrUrCrArArUrCrArArCrCrGrGrArArArCr

GrGrUrCrCrGrGrUrUrGrArArArArGrArGrCrArUrCrGrGr

UrCrUrGrArArGrGrArUrGrCrArCrUrCrCrGrGrGrArUrAr

GrGrGrCrArGrUrCrCrCrGrGrCrUrCrUrUrGrCrUrGrUrUr

UrCrCrCrCrGrGrUrArArGrArCrCrUrCrGrGrArArGrCrAr

ArGrUrCrCrUrUrCrArGrCrArArGrUrCrGrArArArGrArCr

ArCrGrArUrGrUrGrArGrCrCrUrArU*mU*mU*mU

1145
MG102-36 TRAC
GCCACTTTCAGGAGGAGGATTCGG

D12

1146
MG102-36 TRAC F1
GACCCTGCCGTGTACCAGCTGAGA

1147
MG102-36 TRAC H6
TTGAAGTCCATAGACCTCATGTCT

1148
MG102-39 TRAC F4
GCTGCCCTTACCTGGGCTGGGGAA

1149
MG102-39 TRAC A9
TCTTGGTTTTACAGATACGAACCT

1150
MG102-39 TRAC
GGCCACTTTCAGGAGGAGGATTCG

G11

1151
MG102-39 TRAC
CAGCCGCAGCGTCATGAGCAGATT

C11

1152
MG102-39 TRAC B6
CCAGGCCACAGCACTGTTGCTCTT

1153
MG102-39 TRAC B5
GTCTTCTGGAATAATGCTGTTGTT

1154
MG102-39 TRAC G9
GATTGGGTTCCGAATCCTCCTCCT

1155
MG102-39 TRAC D1
ATTCTGATGTGTATATCACAGACA

1156
MG102-39 TRAC
ACAGCCGCAGCGTCATGAGCAGAT

B11

1157
MG102-39 TRAC D4
AAAGCTGCCCTTACCTGGGCTGGG

1158
MG102-39 TRAC F2
CAACAGTGCTGTGGCCTGGAGCAA

1159
MG102-39 TRAC G1
GCTAGACATGAGGTCTATGGACTT

1160
MG102-42 TRAC
GTTCCGAATCCTCCTCCTGAAAGT

D10

1161
MG102-42 TRAC
GCCACTTTCAGGAGGAGGATTCGG

D12

1162
MG102-42 TRAC
CAGGAGGAGGATTCGGAACCCAAT

E12

1163
MG102-45 TRAC B1
TGTCCCACAGATATCCAGAACCCT

1164
MG102-45 TRAC
CTTCAAGGCCCCTCACCTCAGCTG

C11

1165
MG102-48 TRAC A1
TCCTCTTGTCCCACAGATATCCAG

1166
MG102-48 TRAC
GCCACTTTCAGGAGGAGGATTCGG

D12

1167
MG33-34 TRAC F6
mA*mC*mC*rCrGrGrCrCrArCrUrUrUrCrArGrGrArGrGr

CrUrUrUrCrArCrUrCrUrArGrCrGrArArArGrCrUrArGrAr

GrUrGrArArArGrArArGrCrCrCrArGrGrCrGrCrUrGrCrUr

CrCrArGrUrCrCrUrCrGrCrCrGrArUrGrUrArArCrCrCrAr

GrCrArUrCrGrGrCrArCrCrUrArGrGrUrGrUrArGrGrCrAr

GrCrCrCrCrGrCrArGrGrCrCrGrGrUrArCrUrCrGrGrArCr

CrCrCrGrGrCrArArArGrGrGrCrArArGrGrGrUrU*mG*m

G*mU

1168
MG33-34 TRAC E6
mU*mA*mA*rArCrCrCrGrGrCrCrArCrUrUrUrCrArGrGrC

rUrUrUrCrArCrUrCrUrArGrCrGrArArArGrCrUrArGrArG

rUrGrArArArGrArArGrCrCrCrArGrGrCrGrCrUrGrCrUrC

rCrArGrUrCrCrUrCrGrCrCrGrArUrGrUrArArCrCrCrArG

rCrArUrCrGrGrCrArCrCrUrArGrGrUrGrUrArGrGrCrArG

rCrCrCrCrGrCrArGrGrCrCrGrGrUrArCrUrCrGrGrArCrC

rCrCrGrGrCrArArArGrGrGrCrArArGrGrGrUrU*mG*mG*

mU

1169
MG33-34 TRAC F6
ACCCGGCCACTTTCAGGAGG

1170
MG33-34 TRAC E6
TAAACCCGGCCACTTTCAGG

r = native ribose base, m = 2′-O methyl modified base, F = 2′ Fluro modified base, * = phosphorothioate bond

Example 16—SMART HEARO Enzymes are Active Nucleases
In Silico Prediction of SMART HEARO Guide RNAs

To identify guide (HEARO) RNAs associated with novel SMART HEARO nucleases, the nucleotide sequence corresponding to the 5′ UTR regions of 305 putative effectors were extracted. These 5′ UTR nucleotide sequences were aligned with MAFFT (Katoh K, Standley D M. MAFFT multiple sequence alignment software version 7: improvements in performance and usability. Mol Biol Evol. 2013, 30(4), 772-780, which is incorporated by reference in its entirety herein) with parameter mafft-xinsi (https:H/mafft.cbrc.jp/alignment/software/), and regions of conservation were used to delineate the HEARO RNA boundaries (FIG. 31). In addition, the HEARO RNA sequences of active SMART HEARO nucleases were used to generate covariance models to predict additional HEARO RNAs in genomic fragments encoding novel SMART HEARO nucleases. Covariance models are built from a multiple sequence alignment (MSA) of the active HEARO RNA sequences with mafft-xinsi (https://mafft.cbrc.jp/alignment/software/). The secondary structure of the MSA was determined with RNAalifold (Vienna Package, https://www.tbi.univie.ac.at/RNA/) and the covariance models were built with Infemal packages (http://eddylab.org/infemal/). Contigs containing candidate SMART HEARO nucleases and the 305 5′ UTR regions were searched using the covariance models with the Infernal command ‘cmsearch’. HEARO RNAs predicted from 5′ UTR alignments and from covariance models for novel candidates were tested in vitro.

In Vitro TAM Determination Assays

The sgRNA (HEARO RNAs) with a targeting spacer at the 5′ end was constructed via assembly PCR and purified with SPRI beads or ordered as a gene fragments (IDT), and then in vitro transcribed (IVT, HiScribe T7 kit, New England Biolabs) following the manufacturer's recommended protocol for short RNA transcripts. RNA reactions were cleaned with the Monarch RNA kit and checked for purity via a Tapestation (Agilent). Cleavage and TAM determination assays were performed with PURExpress (New England Biolabs). Briefly, the protein was codon optimized for E. coli and cloned into a vector with a T7 promoter and C-terminal His tag. The gene was PCR amplified with primer binding sites 150 bp upstream and downstream from the T7 promoter and terminator sequences, respectively. This PCR product was added to PURExpress (New England Biolabs) at 5 nM final concentration and expressed for 2 hr at 37° C. A cleavage reaction was assembled in 10 mM Tris pH 7.5, 100 mM NaCl, and 10 mM MgCl₂with a 5-fold dilution of PURExpress, 5 nM of an 8N PAM plasmid library, and 50 nM of sgRNA targeting the PAM library. The cleavage products from the PURExpress reactions were recovered via clean up with SPRI beads (AMPure Beckman Coulter or HighPrep Sigma-Aldritch). The DNA was blunted via addition of Klenow fragments and dNTPs (New England Biolabs). Blunt-end products were ligated with a 100-fold excess of double-stranded adapter sequences and used as template for the preparation of an NGS library, from which PAM requirements were determined from sequence analysis. Raw NGS reads were filtered by Phred quality score >20. The 14-24 bp representing the documented DNA sequence from the backbone adjacent to the PAM was used as a reference to find the PAM-proximal region, and the 8 bp adjacent were identified as the putative target adjacent motif (TAM). The distance between the TAM and the ligated adapter was also measured for each read. Reads that did not have an exact match to the reference sequence or adapter sequence were excluded. TAM sequences were filtered by cut site frequency such that only TAMs with the most frequent cut site+2 bp were included in the analysis. The filtered list of TAM sequences was used to generate a sequence logo using Logomaker (Tareen, A. & Kinney, J. B. Logomaker: beautiful sequence logos in Python. Bioinformatics 2020, 36, 2272-2274).

SMART II (HEARO) effectors are short (˜400-600 aa long) nucleases that interact with a guide (HEARO) RNA encoded in their 5′ UTR region for targeted dsDNA cleavage (FIGS. 32A and 32D). In most cases, SMART HEARO systems are not CRISPR-associated, but few SMART HEARO nucleases may be associated with CRISPRs. For example, the SMART HEARO MG35-463 (SEQ ID No. 530) is encoded downstream from a CRISPR array (FIG. 32B). The 5′ end of a HEARO guide RNA predicted from covariance models overlaps with the last CRISPR repeat of the array (FIGS. 32B and 32F, sg3) suggesting that a full targeting single guide RNA comprises the last spacer and the last repeat of the array, as well as the HEARO RNA (FIG. 32F, sg3). Furthermore, covariance models for this candidate predicted a second HEARO RNA upstream from, and unrelated to, the CRISPR array (FIGS. 32B and 32E, sg2). Another example of a CRISPR-associated SMART HEARO system is MG35-556 (SEQ ID No. 659) (FIG. 32C), where the HEARO RNA is encoded in the 5′ UTR region of the effector, which contains an antirepeat complementary to one of the CRISPR repeats (FIG. 32C). This represents an example of a dual guide RNA-guided HEARO system, where one CRISPR repeat (likely carrying a targeting spacer at its 5′ end) anneals to the 5′ end of the HEARO RNA folding into a structure that resembles other single guide HEARO RNAs (FIG. 32G).

When tested for cleavage activity, many SMART HEARO nucleases were active in in vitro TAM determination assays, some of them with multiple sgRNA designs (FIGS. 33A-33C). MG35-104 (SEQ ID No. 128), HEARO MG35-463 (SEQ ID No. 530), and MG35-518 (SEQ ID No. 621) were among the most active nucleases, as shown by the strong band intensity readout (FIG. 33). Furthermore, the SMART HEARO MG35-463 (SEQ ID No. 530) is functional with both its CRISPR-associated (SEQ ID No. 1237) and CRISPR-independent (SEQ ID No. 1236) HEARO RNAs, despite the guide RNAs sharing only 65% pairwise nucleotide identity (FIGS. 32D, 32E, and 33C). Active MG35 candidates recognize diverse TAMs and display a cleavage selectivity for positions 5 or 7 from the TAM motif (FIG. 34).

Example 17—SMART HEARO Enzymes are Efficient Nucleases
In Vitro Cleavage Assays

MG35 nucleases were expressed using in vitro transcription/translation (IVTT) (New England Biolabs) at 37° C. for 2 hours. Transcription was driven by a T7 promoter on a linear DNA template coding for the nuclease. The guide RNA was in vitro transcribed separately and added into the IVTT mix at a chosen concentration, usually between 0.4 at 4 μM. In vitro cleavage reactions were performed by adding 3 μL of the RNP samples to 5 nM of supercoiled DNA in a 10 μL reaction volume in 1× Effector Buffer (10 mM Tris-HCl pH 7.5, 100 mM NaCl, 10 mM MgCl₂) or 1× New England Biolabs 2.1 buffer (10 mM Tris-HCl pH 7.9, 50 mM NaCl, 10 mM MgCl₂, 100 μg/ml BSA). The reactions were incubated at 37° C. for 1 hour and then quenched by adding 0.2 μg of RNAse A (New England Biolabs), followed by incubation at 37° C. for 20 minutes. Then, addition of 4 units of proteinase K (New England Biolabs) was followed by incubation at 55° C. for 30 minutes. Reactions were analyzed by capillary electrophoresis using a D5000 Tapestation kit (Agilent) following the instructions recommended by the manufacturer for analysis and visualization. Successful cleavage results in the supercoiled 2200 bp DNA being cut into linear dsDNA.

After identifying an active guide RNA and TAM recognition motif, SMART HEARO nucleases were tested for in vitro cleavage efficiency via in vitro transcription/translation co-expression of the nuclease with their guide RNA and subsequent incubation with a target plasmid containing the spacer targeted by the guide RNA and the TAM identified in the TAM/PAM enrichment screen. Cleavage is measured by the transition of non-cleaved product (supercoiled) to cleaved linear DNA (FIGS. 35A and 35B). Results indicate that MG35-104 (SEQ ID No. 128) is highly efficient at dsDNA cleavage compared to other active SMART HEARO nucleases (FIGS. 35A and 35B).

Example 18—SMART HEARO Guide Engineering

The guide RNA of some active SMART II nucleases contains one or more poly-T regions (four or more T bases sequentially) (FIG. 36A), which can limit transcription efficiency. Three PolyT mutant sgRNAs per candidate were designed and tested for cleavage activity in vitro, and their activity was compared to the candidate's activity with their native guide RNA (FIGS. 36A and 36B). Results indicate that MG35-94 is active with mutant guides M2 and M3, while MG35-104 is active with all three guide mutations M1-M3, where guide M3 retains the highest activity compared to other guides. MG35-518 is active with all three mutants tested but M1 shows the highest activity (FIG. 36B).

TABLE 6

Variant Guide RNAs tested in Example 18

SEQ ID

NO:
Description
Sequence

1258
MG35-94_M2 single guide
(N20)GUAAUCGUCCAUAAAUAACUUAGGCAACUAAGU

RNA
AGUUUAAGGUUACCCGCUUUGGUUCUUCGGAACUCC

GUUAGGGGCGAAAAUAUAGGUACUCUUGGAUGCAUC

UCCAGUCCGAGACUCUACGGGGAACGAUUAAACAGG

UCUGAUGGAAAGGCCAGUGUCGUUUCCAUUUAAAAC

CGCUUUCUAACAUUAGCUAGGAAACCAUUACUCGCG

CAAGCGAAGAUAUGUAACAAUUU

1259
MG35-94_M3 single guide
(N20)GUAAUCGUCCAUAAAUAACUUAGGCAACUAAGU

RNA
AGAUUAAGGUUACCCGCUUUGGUUCUUCGGAACUCC

GUUAGGGGCGAAAAUAUAGGUACUCUUGGAUGCAUC

UCCAGUCCGAGACUCUACGGGGAACGAUUAAACAGG

UCUGAUGGAAAGGCCAGUGUCGUUUCCAUUUAAAAC

CGCUUUCUAACAUUAGCUAGGAAACCAUUACUCGCG

CAAGCGAAGAUAUGUAACAAUUU

1249
MG35-104_Ml single guide
(N20)GUAAGGAACCCCGUAGCUAAAGCUAGGGGCUAU

RNA
UCAUCCCCGUCCCUUCGGGCGGGCUUAGAUAGCCGA

ACCUUACCAGCCUAAGACCUUCGAGGUCUACGUAUU

CAAGGUCACGAUACCUAUCAAUGCGUCGCUAGUUGU

UAGCUCUAUCGCUGGUUGUUAAACAUCUGUAAUGGG

UUAAGGAAGUGCAAUCAGCCCAACAAGCCUUGAAUA

CAUUGGCGAAGCGAACAUCACCCAGCAAUGGAGUCC

UUCAAUCA

1250
MG35-104_M2 single guide
(N20)GUAAGGAACCCCGUAGCUAAAGCUAGGGGCUUA

RNA
UCAUCCCCGUCCCUUCGGGCGGGCUUAGUAAGCCGA

ACCUUACCAGCCUAAGACCUUCGAGGUCUACGUAUU

CAAGGUCACGAUACCUAUCAAUGCGUCGCUAGUUGU

UAGCUCUAUCGCUGGUUGUUAAACAUCUGUAAUGGG

UUAAGGAAGUGCAAUCAGCCCAACAAGCCUUGAAUA

CAUUGGCGAAGCGAACAUCACCCAGCAAUGGAGUCC

UUCAAUCA

1251
MG35-104_M3 single guide
(N20)GUAAGGAACCCCGUAGCUAAAGCUAGGGGCUAU

RNA
UCAUCCCCGUCCCUUCGGGCGGGCUUAGAUAGCCGA

ACCUUACCAGCCUAAGACCUUCGAGGUCUACGUUCU

CAAGGUCACGAUACCUAUCAAUGCGUCGCUAGUUGU

UAGCUCUAUCGCUGGUUGUUAAACAUCUGUAAUGGG

UUAAGGAAGUGCAAUCAGCCCAACAAGCCUUGAGAA

CAUUGGCGAAGCGAACAUCACCCAGCAAUGGAGUCC

UUCAAUCA

1252
MG35-518_M1 single guide
(N20)AUCAAUAACCAACCCACUAAGUGGGCGGAUUGC

RNA
UUGACUCUUAUACAAUGAGUUGAGAAACCGUGAUUG

AUUAGCCUCAGUUAUAAACUACGUUAUUUGUAAAUAU

AUAGGUACCGUCGGAUGUCCGCCUAGUCCUACGCGC

UACGCUUUAUUAUUAAACAGUUCUGAUUGGUAGGAA

CAGUGUAAUAAAGAUAUAAAACUACAAGAUAACAUUG

GCGAAGGCAAUAAAGGGUUUGUUUAUACCCGCUUAC

CGCAUUAAAUAAACAU

1253
MG35-518_M2 single guide
(N20)AUCAAUAACCAACCCACUAAGUGGGCGGAUUGC

RNA
UUGACUCUAUUACAAUGAGUUGAGAAACCGUGAUUG

AUUAGCCUCAGUUAUAAACUACGUUAUUUGUAAAUAU

AUAGGUACCGUCGGAUGUCCGCCUAGUCCUACGCGC

UACGCUUUAUUAUUAAACAGUUCUGAUUGGUAGGAA

CAGUGUAAUAAAGAUAUAAAACUACAAGAUAACAUUG

GCGAAGGCAAUAAAGGGUUUGUUUAUACCCGCUUAC

CGCAUUAAAUAAACAU

1254
MG35-518_M3 single guide
(N20)AUCAAUAACCAACCCACUAAGUGGGCGGAUUGC

RNA
UUGACUCUGUUACAAUGAGUUGAGAAACCGUGAUUG

AUUAGCCUCAGUUAUAAACUACGUUAUUUGUAAAUAU

AUAGGUACCGUCGGAUGUCCGCCUAGUCCUACGCGC

UACGCUUUAUUAUUAAACAGUUCUGAUUGGUAGGAA

CAGUGUAAUAAAGAUAUAAAACUACAAGAUAACAUUG

GCGAAGGCAAUAAAGGGUUUGUUUAUACCCGCUUAC

CGCAUUAAAUAAACAU

1255
MG35-553_M1 single guide
(N20)GUCAACUACCCACGACUAAAGUCGCGGGCUUGU

RNA
AAUAAGGAUAGUGCUAUGUACUAGCCUUAUUCAGCC

CGGUUGACUAGCCUAAGCACCAAUUGUGCUACGUUA

UGCAGGAAAUAGGUACCUCGGGAUGUACAGCCUAGU

CCCGGGCUCUACGGUAUGAGGUUAAACAGCUCUGAC

GGGUAGGAGCAGUGCUUCAUGCGUUAAACCCUGCAA

UAACAUUGGCGAAGGCUAACUAACGGAUGCUGCAUC

CGGCUUACAGCAAUAAUGCAGCAGAAAA

1256
MG35-553_M2 single guide
(N20)GUCAACUACCCACGACUAAAGUCGCGGGCUUGU

RNA
AUUAAGGAUAGUGCUAUGUACUAGCCUUAAUCAGCC

CGGUUGACUAGCCUAAGCACCAAUUGUGCUACGUUA

UGCAGGAAAUAGGUACCUCGGGAUGUACAGCCUAGU

CCCGGGCUCUACGGUAUGAGGUUAAACAGCUCUGAC

GGGUAGGAGCAGUGCUUCAUGCGUUAAACCCUGCAA

UAACAUUGGCGAAGGCUAACUAACGGAUGCUGCAUC

CGGCUUACAGCAAUAAUGCAGCAGAAAA

1257
MG35-553_M3 single guide
(N20)GUCAACUACCCACGACUAAAGUCGCGGGCUUGU

RNA
AAUUAGGAUAGUGCUAUGUACUAGCCUAAUUCAGCC

CGGUUGACUAGCCUAAGCACCAAUUGUGCUACGUUA

UGCAGGAAAUAGGUACCUCGGGAUGUACAGCCUAGU

CCCGGGCUCUACGGUAUGAGGUUAAACAGCUCUGAC

GGGUAGGAGCAGUGCUUCAUGCGUUAAACCCUGCAA

UAACAUUGGCGAAGGCUAACUAACGGAUGCUGCAUC

CGGCUUACAGCAAUAAUGCAGCAGAAAA

Example 19—Computational Reconstruction of Novel SMART I Nucleases
In Silico Reconstruction of Novel Sequences

In an effort to generate further diversity of SMART I nucleases, ancestral sequence reconstruction algorithms were used to reconstruct divergent nuclease sequences. Ancestral sequence reconstruction is a computational technique that uses existing protein sequences and the relationships inferred between them to reconstruct the sequences of ancient, now extinct, proteins (Harms, M. & Thornton J. W. Analyzing protein structure and function using ancestral gene reconstruction. Current Opinion in Structural Biology 2010, 20, 360-366). This technique was used to computationally reconstruct novel sequences of the SMART I MG34 family. For this analysis, 190 SMART I protein sequences were aligned using MAFFT with parameters L-INS-i or G-INS-i (Katoh K, Standley D M. MAFFT multiple sequence alignment software version 7: improvements in performance and usability. Mol Biol Evol. 2013, 30(4), 772-780), and a phylogenetic tree was built using either Fasttree (Price, M. N., Dehal, P. S., and Arkin, A. P. FastTree 2—Approximately Maximum-Likelihood Trees for Large Alignments. PLoS ONE 2010, 5(3), e9490) or RAxML (Stamatakis, A. RAxML version 8: a tool for phylogenetic analysis and post-analysis of large phylogenies. Bioinformatics 2014, 30(9), 1312-1313) (FIG. 37). The trees were rooted using SpCas9 and SaCas9. Sequence reconstruction was done using the codeml package in PAML 4.8 (Yang, Z. PAML 4: a program package for phylogenetic analysis by maximum likelihood. Molecular Biology and Evolution 2007, 24, 1586-1591) and applied to all four combinations of alignment and tree building methods to account for uncertainties in the phylogenies. Insertions and deletions were identified manually for each reconstructed node.

In Vitro PAM Determination Assays

Candidate proteins were codon optimized for E. coli and cloned into a vector with a T7 promoter and C-terminal His tag. The gene was PCR amplified with primer binding sites 150 bp upstream and downstream from the T7 promoter and terminator sequences, respectively. This PCR product was added to PURExpress (New England Biolabs) at 5 nM final concentration and expressed for 2 hr at 37° C. A cleavage reaction was assembled in 10 mM Tris pH 7.5, 100 mM NaCl, and 10 mM MgCl₂with a 5-fold dilution of PURExpress, 5 nM of an 8N PAM plasmid library, and 50 nM of sgRNA targeting the PAM library. The cleavage products from the PURExpress reactions were recovered via clean up with SPRI beads (AMPure Beckman Coulter or HighPrep Sigma-Aldritch). The DNA was blunted via addition of Klenow fragments and dNTPs (New England Biolabs). Blunt-end products were ligated with a 100-fold excess of double-stranded adapter sequences and used as template for the preparation of an NGS library, from which PAM requirements were determined from sequence analysis. Raw NGS reads were filtered by Phred quality score >20. The 14-24 bp representing the documented DNA sequence from the backbone adjacent to the PAM was used as a reference to find the PAM-proximal region, and the 8 bp adjacent were identified as the putative PAM. The distance between the PAM and the ligated adapter was also measured for each read. Reads that did not have an exact match to the reference sequence or adapter sequence were excluded. PAM sequences were filtered by cut site frequency such that only PAMs with the most frequent cut site+2 bp were included in the analysis. The filtered list of PAM sequences was used to generate a sequence logo using Logomaker (Tareen, A. & Kinney, J. B. Logomaker: beautiful sequence logos in Python. Bioinformatics 2020, 36, 2272-2274).

Six sequences of the MG34 family were reconstructed with high confidence (Table 5 and FIG. 37) and catalytic and binding domains were confirmed from multiple sequence alignments and 3D structure prediction (FIG. 38).

TABLE 7

Comparison of computationally-derived MG34

candidates vs. the SMART I nuclease MG34-1

SEQ

Length

ID
Mean
MG34-1
(amino

Candidate
NO.
Support
% Identity
acids)

MG34-26
1313
0.73
66
768

MG34-27
1314
0.93
78
745

MG34-28
1315
0.75
70
765

MG34-29
1316
0.92
79
748

MG34-30
1317
0.74
79
766

MG34-31
1318
0.74
72
768

Mean support values indicate the average probability for the reconstructed sequence, on a scale from 0 to 1. Support values >0.7 indicate high confidence in the reconstructed sequence.

The primary differences between the structures are in the recognition lobe, which suggests that these reconstructed effectors may display similar nuclease activity to MG34-1. Given the strong support for newly reconstructed candidates, the six novel nucleases were tested for in vitro cleavage activity in PAM enrichment assays with the guide RNAs from three active MG34 nucleases: MG34-1 sgRNA 1 (SEQ ID No. 613), MG34-9 sgRNA 1 (SEQ ID No. 615), and MG34-16 sgRNA 1 (SEQ ID No. 616). Novel nucleases MG34-27 (SEQ ID No. 1314) and MG34-29 (SEQ ID No. 1316) were active with all three tested sgRNAs, as shown by the expected cleavage band at approximately 180 bp (FIG. 39). The PAM targeted by these novel nucleases is likely 3′ nRR, with nGG being the most commonly recognized PAM (FIG. 40). Results indicate that the newly reconstructed nucleases have a more relaxed PAM recognition vs. other active MG34 nucleases (e.g. MG34-1 recognizes a 3′ nGG PAM), with a flexible cleavage preference at position 6-9 from the PAM (FIG. 40).

TABLE 8

Listing of additional protein and nucleic acid sequences referred to herein not included in the sequence listing

I.

SEQ

Comments or

Category
ID:
Description
Type
Organism
Other Information
Sequence

MG33
1
MG33-1 effector
protein
unknown
uncultivated organism

active

effectors

MG34
2
MG34-1 effector
protein
unknown
uncultivated organism

active

effectors

MG34
3
MG34-2 effector
protein
unknown
uncultivated organism

effectors

MG34
4
MG34-3 effector
protein
unknown
uncultivated organism

effectors

MG34
5
MG34-4 effector
protein
unknown
uncultivated organism

effectors

MG34
6
MG34-5 effector
protein
unknown
uncultivated organism

effectors

MG34
7
MG34-6 effector
protein
unknown
uncultivated organism

effectors

MG34
8
MG34-7 effector
protein
unknown
uncultivated organism

effectors

MG34
9
MG34-8 effector
protein
unknown
uncultivated organism

effectors

MG34
10
MG34-9 effector
protein
unknown
uncultivated organism

effectors

MG34
11
MG34-10 effector
protein
unknown
uncultivated organism

effectors

MG34
12
MG34-11 effector
protein
unknown
uncultivated organism

effectors

MG34
13
MG34-12 effector
protein
unknown
uncultivated organism

effectors

MG34
14
MG34-13 effector
protein
unknown
uncultivated organism

effectors

MG34
15
MG34-14 effector
protein
unknown
uncultivated organism

effectors

MG34
16
MG34-15 effector
protein
unknown
uncultivated organism

effectors

MG34
17
MG34-16 effector
protein
unknown
uncultivated organism

effectors

MG34
18
MG34-17 effector
protein
unknown
uncultivated organism

effectors

MG34
19
MG34-18 effector
protein
unknown
uncultivated organism

effectors

MG34
20
MG34-19 effector
protein
unknown
uncultivated organism

effectors

MG34
21
MG34-20 effector
protein
unknown
uncultivated organism

effectors

MG34
22
MG34-21 effector
protein
unknown
uncultivated organism

effectors

MG34
23
MG34-22 effector
protein
unknown
uncultivated organism

effectors

MG34
24
MG34-23 effector
protein
unknown
uncultivated organism

effectors

MG35
25
MG35-1 effector
protein
unknown
uncultivated organism

effectors

MG35
26
MG35-2 effector
protein
unknown
uncultivated organism

effectors

MG35
27
MG35-3 effector
protein
unknown
uncultivated organism

effectors

MG35
28
MG35-4 effector
protein
unknown
uncultivated organism

effectors

MG35
29
MG35-5 effector
protein
unknown
uncultivated organism

effectors

MG35
30
MG35-6 effector
protein
unknown
uncultivated organism

effectors

MG35
31
MG35-7 effector
protein
unknown
uncultivated organism

effectors

MG35
32
MG35-8 effector
protein
unknown
uncultivated organism

effectors

MG35
33
MG35-9 effector
protein
unknown
uncultivated organism

effectors

MG35
34
MG35-10 effector
protein
unknown
uncultivated organism

effectors

MG35
35
MG35-11 effector
protein
unknown
uncultivated organism

effectors

MG35
36
MG35-12 effector
protein
unknown
uncultivated organism

effectors

MG35
37
MG35-13 effector
protein
unknown
uncultivated organism

effectors

MG35
38
MG35-14 effector
protein
unknown
uncultivated organism

effectors

MG35
39
MG35-15 effector
protein
unknown
uncultivated organism

effectors

MG35
40
MG35-16 effector
protein
unknown
uncultivated organism

effectors

MG35
41
MG35-17 effector
protein
unknown
uncultivated organism

effectors

MG35
42
MG35-18 effector
protein
unknown
uncultivated organism

effectors

MG35
43
MG35-19 effector
protein
unknown
uncultivated organism

effectors

MG35
44
MG35-20 effector
protein
unknown
uncultivated organism

effectors

MG35
45
MG35-21 effector
protein
unknown
uncultivated organism

effectors

MG35
46
MG35-22 effector
protein
unknown
uncultivated organism

effectors

MG35
47
MG35-23 effector
protein
unknown
uncultivated organism

effectors

MG35
48
MG35-24 effector
protein
unknown
uncultivated organism

effectors

MG35
49
MG35-25 effector
protein
unknown
uncultivated organism

effectors

MG35
50
MG35-26 effector
protein
unknown
uncultivated organism

effectors

MG35
51
MG35-27 effector
protein
unknown
uncultivated organism

effectors

MG35
52
MG35-28 effector
protein
unknown
uncultivated organism

effectors

MG35
53
MG35-29 effector
protein
unknown
uncultivated organism

effectors

MG35
54
MG35-30 effector
protein
unknown
uncultivated organism

effectors

MG35
55
MG35-31 effector
protein
unknown
uncultivated organism

effectors

MG35
56
MG35-32 effector
protein
unknown
uncultivated organism

effectors

MG35
57
MG35-33 effector
protein
unknown
uncultivated organism

effectors

MG35
58
MG35-34 effector
protein
unknown
uncultivated organism

effectors

MG35
59
MG35-35 effector
protein
unknown
uncultivated organism

effectors

MG35
50
MG35-36 effector
protein
unknown
uncultivated organism

effectors

MG35
61
MG35-37 effector
protein
unknown
uncultivated organism

effectors

MG35
62
MG35-38 effector
protein
unknown
uncultivated organism

effectors

MG35
63
MG35-39 effector
protein
unknown
uncultivated organism

effectors

MG35
64
MG35-40 effector
protein
unknown
uncultivated organism

effectors

MG35
65
MG35-41 effector
protein
unknown
uncultivated organism

effectors

MG35
66
MG35-42 effector
protein
unknown
uncultivated organism

effectors

MG35
67
MG35-43 effector
protein
unknown
uncultivated organism

effectors

MG35
68
MG35-44 effector
protein
unknown
uncultivated organism

effectors

MG35
69
MG35-45 effector
protein
unknown
uncultivated organism

effectors

MG35
70
MG35-46 effector
protein
unknown
uncultivated organism

effectors

MG35
71
MG35-47 effector
protein
unknown
uncultivated organism

effectors

MG35
72
MG35-48 effector
protein
unknown
uncultivated organism

effectors

MG35
73
MG35-49 effector
protein
unknown
uncultivated organism

effectors

MG35
74
MG35-50 effector
protein
unknown
uncultivated organism

effectors

MG35
75
MG35-51 effector
protein
unknown
uncultivated organism

effectors

MG35
76
MG35-52 effector
protein
unknown
uncultivated organism

effectors

MG35
77
MG35-53 effector
protein
unknown
uncultivated organism

effectors

MG35
78
MG35-54 effector
protein
unknown
uncultivated organism

effectors

MG35
79
MG35-55 effector
protein
unknown
uncultivated organism

effectors

MG35
80
MG35-56 effector
protein
unknown
uncultivated organism

effectors

MG35
81
MG35-57 effector
protein
unknown
uncultivated organism

effectors

MG35
82
MG35-58 effector
protein
unknown
uncultivated organism

effectors

MG35
83
MG35-59 effector
protein
unknown
uncultivated organism

effectors

MG35
84
MG35-60 effector
protein
unknown
uncultivated organism

effectors

MG35
85
MG35-61 effector
protein
unknown
uncultivated organism

effectors

MG35
86
MG35-62 effector
protein
unknown
uncultivated organism

effectors

MG35
87
MG35-63 effector
protein
unknown
uncultivated organism

effectors

MG35
88
MG35-64 effector
protein
unknown
uncultivated organism

effectors

MG35
89
MG35-65 effector
protein
unknown
uncultivated organism

effectors

MG35
90
MG35-66 effector
protein
unknown
uncultivated organism

effectors

MG35
91
MG35-67 effector
protein
unknown
uncultivated organism

effectors

MG35
92
MG35-68 effector
protein
unknown
uncultivated organism

effectors

MG35
93
MG35-69 effector
protein
unknown
uncultivated organism

effectors

MG35
94
MG35-70 effector
protein
unknown
uncultivated organism

effectors

MG35
95
MG35-71 effector
protein
unknown
uncultivated organism

effectors

MG35
96
MG35-72 effector
protein
unknown
uncultivated organism

effectors

MG35
97
MG35-73 effector
protein
unknown
uncultivated organism

effectors

MG35
98
MG35-74 effector
protein
unknown
uncultivated organism

effectors

MG35
99
MG35-75 effector
protein
unknown
uncultivated organism

effectors

MG35
100
MG35-76 effector
protein
unknown
uncultivated organism

effectors

MG35
101
MG35-77 effector
protein
unknown
uncultivated organism

effectors

MG35
102
MG35-78 effector
protein
unknown
uncultivated organism

effectors

MG35
103
MG35-79 effector
protein
unknown
uncultivated organism

effectors

MG35
104
MG35-80 effector
protein
unknown
uncultivated organism

effectors

MG35
105
MG35-81 effector
protein
unknown
uncultivated organism

effectors

MG35
106
MG35-82 effector
protein
unknown
uncultivated organism

effectors

MG35
107
MG35-83 effector
protein
unknown
uncultivated organism

effectors

MG35
108
MG35-84 effector
protein
unknown
uncultivated organism

effectors

MG35
109
MG35-85 effector
protein
unknown
uncultivated organism

effectors

MG35
110
MG35-86 effector
protein
unknown
uncultivated organism

effectors

MG35
111
MG35-87 effector
protein
unknown
uncultivated organism

effectors

MG35
112
MG35-88 effector
protein
unknown
uncultivated organism

effectors

MG35
113
MG35-89 effector
protein
unknown
uncultivated organism

effectors

MG35
114
MG35-90 effector
protein
unknown
uncultivated organism

effectors

MG35
115
MG35-91 effector
protein
unknown
uncultivated organism

effectors

MG35
116
MG35-92 effector
protein
unknown
uncultivated organism

effectors

MG35
117
MG35-93 effector
protein
unknown
uncultivated organism

effectors

MG35
118
MG35-94 effector
protein
unknown
uncultivated organism

effectors

MG35
119
MG35-95 effector
protein
unknown
uncultivated organism

effectors

MG35
120
MG35-96 effector
protein
unknown
uncultivated organism

effectors

MG35
121
MG35-97 effector
protein
unknown
uncultivated organism

effectors

MG35
122
MG35-98 effector
protein
unknown
uncultivated organism

effectors

MG35
123
MG35-99 effector
protein
unknown
uncultivated organism

effectors

MG35
124
MG35-100 effector
protein
unknown
uncultivated organism

effectors

MG35
125
MG35-101 effector
protein
unknown
uncultivated organism

effectors

MG35
126
MG35-102 effector
protein
unknown
uncultivated organism

effectors

MG35
127
MG35-103 effector
protein
unknown
uncultivated organism

effectors

MG35
128
MG35-104 effector
protein
unknown
uncultivated organism

effectors

MG35
129
MG35-105 effector
protein
unknown
uncultivated organism

effectors

MG35
130
MG35-106 effector
protein
unknown
uncultivated organism

effectors

MG35
131
MG35-107 effector
protein
unknown
uncultivated organism

effectors

MG35
132
MG35-108 effector
protein
unknown
uncultivated organism

effectors

MG35
133
MG35-109 effector
protein
unknown
uncultivated organism

effectors

MG35
134
MG35-110 effector
protein
unknown
uncultivated organism

effectors

MG35
135
MG35-111 effector
protein
unknown
uncultivated organism

effectors

MG35
136
MG35-112 effector
protein
unknown
uncultivated organism

effectors

MG35
137
MG35-113 effector
protein
unknown
uncultivated organism

effectors

MG35
138
MG35-114 effector
protein
unknown
uncultivated organism

effectors

MG35
139
MG35-115 effector
protein
unknown
uncultivated organism

effectors

MG35
140
MG35-116 effector
protein
unknown
uncultivated organism

effectors

MG35
141
MG35-117 effector
protein
unknown
uncultivated organism

effectors

MG35
142
MG35-118 effector
protein
unknown
uncultivated organism

effectors

MG35
143
MG35-119 effector
protein
unknown
uncultivated organism

effectors

MG35
144
MG35-120 effector
protein
unknown
uncultivated organism

effectors

MG35
145
MG35-121 effector
protein
unknown
uncultivated organism

effectors

MG35
146
MG35-122 effector
protein
unknown
uncultivated organism

effectors

MG35
147
MG35-123 effector
protein
unknown
uncultivated organism

effectors

MG35
148
MG35-124 effector
protein
unknown
uncultivated organism

effectors

MG35
149
MG35-125 effector
protein
unknown
uncultivated organism

effectors

MG35
150
MG35-126 effector
protein
unknown
uncultivated organism

effectors

MG35
151
MG35-127 effector
protein
unknown
uncultivated organism

effectors

MG35
152
MG35-128 effector
protein
unknown
uncultivated organism

effectors

MG35
153
MG35-129 effector
protein
unknown
uncultivated organism

effectors

MG35
154
MG35-130 effector
protein
unknown
uncultivated organism

effectors

MG35
155
MG35-131 effector
protein
unknown
uncultivated organism

effectors

MG35
156
MG35-132 effector
protein
unknown
uncultivated organism

effectors

MG35
157
MG35-133 effector
protein
unknown
uncultivated organism

effectors

MG35
158
MG35-134 effector
protein
unknown
uncultivated organism

effectors

MG35
159
MG35-135 effector
protein
unknown
uncultivated organism

effectors

MG35
160
MG35-136 effector
protein
unknown
uncultivated organism

effectors

MG35
161
MG35-137 effector
protein
unknown
uncultivated organism

effectors

MG35
162
MG35-138 effector
protein
unknown
uncultivated organism

effectors

MG35
163
MG35-139 effector
protein
unknown
uncultivated organism

effectors

MG35
164
MG35-140 effector
protein
unknown
uncultivated organism

effectors

MG35
165
MG35-141 effector
protein
unknown
uncultivated organism

effectors

MG35
166
MG35-142 effector
protein
unknown
uncultivated organism

effectors

MG35
167
MG35-143 effector
protein
unknown
uncultivated organism

effectors

MG35
168
MG35-144 effector
protein
unknown
uncultivated organism

effectors

MG35
169
MG35-146 effector
protein
unknown
uncultivated organism

effectors

MG35
170
MG35-147 effector
protein
unknown
uncultivated organism

effectors

MG35
171
MG35-148 effector
protein
unknown
uncultivated organism

effectors

MG35
172
MG35-149 effector
protein
unknown
uncultivated organism

effectors

MG35
173
MG35-150 effector
protein
unknown
uncultivated organism

effectors

MG35
174
MG35-151 effector
protein
unknown
uncultivated organism

effectors

MG35
175
MG35-152 effector
protein
unknown
uncultivated organism

effectors

MG35
176
MG35-153 effector
protein
unknown
uncultivated organism

effectors

MG35
177
MG35-154 effector
protein
unknown
uncultivated organism

effectors

MG35
178
MG35-155 effector
protein
unknown
uncultivated organism

effectors

MG35
179
MG35-156 effector
protein
unknown
uncultivated organism

effectors

MG35
180
MG35-157 effector
protein
unknown
uncultivated organism

effectors

MG35
181
MG35-158 effector
protein
unknown
uncultivated organism

effectors

MG35
182
MG35-159 effector
protein
unknown
uncultivated organism

effectors

MG35
183
MG35-160 effector
protein
unknown
uncultivated organism

effectors

MG35
184
MG35-161 effector
protein
unknown
uncultivated organism

effectors

MG35
185
MG35-162 effector
protein
unknown
uncultivated organism

effectors

MG35
186
MG35-163 effector
protein
unknown
uncultivated organism

effectors

MG35
187
MG35-164 effector
protein
unknown
uncultivated organism

effectors

MG35
188
MG35-165 effector
protein
unknown
uncultivated organism

effectors

MG35
189
MG35-166 effector
protein
unknown
uncultivated organism

effectors

MG35
190
MG35-167 effector
protein
unknown
uncultivated organism

effectors

MG35
191
MG35-168 effector
protein
unknown
uncultivated organism

effectors

MG35
192
MG35-169 effector
protein
unknown
uncultivated organism

effectors

MG35
193
MG35-170 effector
protein
unknown
uncultivated organism

effectors

MG35
194
MG35-171 effector
protein
unknown
uncultivated organism

effectors

MG35
195
MG35-172 effector
protein
unknown
uncultivated organism

effectors

MG35
196
MG35-173 effector
protein
unknown
uncultivated organism

effectors

MG35
197
MG35-174 effector
protein
unknown
uncultivated organism

effectors

MG35
198
MG35-175 effector
protein
unknown
uncultivated organism

effectors

MG33
199
MG33-1 tracrRNA sequence
nucleotide
artificial sequence

active

effectors

tracrRNA

sequence

MG34
200
MG34-1 tracrRNA sequence
nucleotide
artificial sequence

active

effectors

tracrRNA

sequence

putative
201
putative MG33-1 sgRNA
nucleotide
artificial sequence

sgRNA

putative
202
putative MG34-1 sgRNA
nucleotide
artificial sequence

sgRNA

putative
203
putative MG34-1 sgRNA
nucleotide
artificial sequence

sgRNA

target
204
test target sequence
nucleotide
artificial sequence

NLS
205
SV40 NLS
protein
Simian

vacuolating virus

40 T

NLS
206
nucleoplasmin bipartite NLS
protein
Human

NLS
207
c-myc NLS
protein
Human

NLS
208
c-myc NLS
protein
Human

NLS
209
hnRNPA1 M9 NLS
protein
Mouse

NLS
210
Importin-alpha IBB domain NLS
protein
Human

NLS
211
Myoma T protein NLS
protein
Murine

polyomavirus

NLS
212
Myoma T protein NLS
protein
Murine

polyomavirus

NLS
213
p53 NLS
protein
Human

NLS
214
mouse c-abl IV NLS
protein
Mouse

NLS
215
influenza virus NS1 NLS
protein
Influenza virus

NS1

NLS
216
influenza virus NS1 NLS
protein
Influenza virus

NS1

NLS
217
Hepatitis virus delta antigen NLS
protein
Hepatitis virus

delta

NLS
218
mouse Mx1 protein NLS
protein
Mouse

NLS
219
human poly(ADP-ribose)
protein
Human

polymerase NLS

NLS
220
steroid hormone receptors
protein
Human

glucocorticoid NLS

MG35
221
MG35-4 effector
protein
unknown
uncultivated organism

effectors

MG35
222
MG35-419 effector
protein
unknown
uncultivated organism

effectors

MG35
223
MG35-420 effector
protein
unknown
uncultivated organism

effectors

MG35
224
MG35-421 effector
protein
unknown
uncultivated organism

effectors

MG35
225
MG35-176 effector
protein
unknown
uncultivated organism

effectors

MG35
226
MG35-177 effector
protein
unknown
uncultivated organism

effectors

MG35
227
MG35-178 effector
protein
unknown
uncultivated organism

effectors

MG35
228
MG35-179 effector
protein
unknown
uncultivated organism

effectors

MG35
229
MG35-180 effector
protein
unknown
uncultivated organism

effectors

MG35
230
MG35-181 effector
protein
unknown
uncultivated organism

effectors

MG35
231
MG35-183 effector
protein
unknown
uncultivated organism

effectors

MG35
232
MG35-184 effector
protein
unknown
uncultivated organism

effectors

MG35
233
MG35-185 effector
protein
unknown
uncultivated organism

effectors

MG35
234
MG35-186 effector
protein
unknown
uncultivated organism

effectors

MG35
235
MG35-187 effector
protein
unknown
uncultivated organism

effectors

MG35
236
MG35-188 effector
protein
unknown
uncultivated organism

effectors

MG35
237
MG35-189 effector
protein
unknown
uncultivated organism

effectors

MG35
238
MG35-190 effector
protein
unknown
uncultivated organism

effectors

MG35
239
MG35-191 effector
protein
unknown
uncultivated organism

effectors

MG35
240
MG35-192 effector
protein
unknown
uncultivated organism

effectors

MG35
241
MG35-193 effector
protein
unknown
uncultivated organism

effectors

MG35
242
MG35-194 effector
protein
unknown
uncultivated organism

effectors

MG35
243
MG35-195 effector
protein
unknown
uncultivated organism

effectors

MG35
244
MG35-196 effector
protein
unknown
uncultivated organism

effectors

MG35
245
MG35-197 effector
protein
unknown
uncultivated organism

effectors

MG35
246
MG35-198 effector
protein
unknown
uncultivated organism

effectors

MG35
247
MG35-199 effector
protein
unknown
uncultivated organism

effectors

MG35
248
MG35-200 effector
protein
unknown
uncultivated organism

effectors

MG35
249
MG35-201 effector
protein
unknown
uncultivated organism

effectors

MG35
250
MG35-202 effector
protein
unknown
uncultivated organism

effectors

MG35
251
MG35-203 effector
protein
unknown
uncultivated organism

effectors

MG35
252
MG35-204 effector
protein
unknown
uncultivated organism

effectors

MG35
253
MG35-205 effector
protein
unknown
uncultivated organism

effectors

MG35
254
MG35-206 effector
protein
unknown
uncultivated organism

effectors

MG35
255
MG35-207 effector
protein
unknown
uncultivated organism

effectors

MG35
256
MG35-208 effector
protein
unknown
uncultivated organism

effectors

MG35
257
MG35-209 effector
protein
unknown
uncultivated organism

effectors

MG35
258
MG35-210 effector
protein
unknown
uncultivated organism

effectors

MG35
259
MG35-211 effector
protein
unknown
uncultivated organism

effectors

MG35
260
MG35-212 effector
protein
unknown
uncultivated organism

effectors

MG35
261
MG35-213 effector
protein
unknown
uncultivated organism

effectors

MG35
262
MG35-214 effector
protein
unknown
uncultivated organism

effectors

MG35
263
MG35-215 effector
protein
unknown
uncultivated organism

effectors

MG35
264
MG35-216 effector
protein
unknown
uncultivated organism

effectors

MG35
265
MG35-217 effector
protein
unknown
uncultivated organism

effectors

MG35
266
MG35-218 effector
protein
unknown
uncultivated organism

effectors

MG35
267
MG35-219 effector
protein
unknown
uncultivated organism

effectors

MG35
268
MG35-220 effector
protein
unknown
uncultivated organism

effectors

MG35
269
MG35-221 effector
protein
unknown
uncultivated organism

effectors

MG35
270
MG35-222 effector
protein
unknown
uncultivated organism

effectors

MG35
271
MG35-223 effector
protein
unknown
uncultivated organism

effectors

MG35
272
MG35-224 effector
protein
unknown
uncultivated organism

effectors

MG35
273
MG35-225 effector
protein
unknown
uncultivated organism

effectors

MG35
274
MG35-226 effector
protein
unknown
uncultivated organism

effectors

MG35
275
MG35-227 effector
protein
unknown
uncultivated organism

effectors

MG35
276
MG35-228 effector
protein
unknown
uncultivated organism

effectors

MG35
277
MG35-229 effector
protein
unknown
uncultivated organism

effectors

MG35
278
MG35-230 effector
protein
unknown
uncultivated organism

effectors

MG35
279
MG35-231 effector
protein
unknown
uncultivated organism

effectors

MG35
280
MG35-232 effector
protein
unknown
uncultivated organism

effectors

MG35
281
MG35-233 effector
protein
unknown
uncultivated organism

effectors

MG35
282
MG35-234 effector
protein
unknown
uncultivated organism

effectors

MG35
283
MG35-235 effector
protein
unknown
uncultivated organism

effectors

MG35
284
MG35-236 effector
protein
unknown
uncultivated organism

effectors

MG35
285
MG35-237 effector
protein
unknown
uncultivated organism

effectors

MG35
286
MG35-238 effector
protein
unknown
uncultivated organism

effectors

MG35
287
MG35-239 effector
protein
unknown
uncultivated organism

effectors

MG35
288
MG35-240 effector
protein
unknown
uncultivated organism

effectors

MG35
289
MG35-241 effector
protein
unknown
uncultivated organism

effectors

MG35
290
MG35-242 effector
protein
unknown
uncultivated organism

effectors

MG35
291
MG35-243 effector
protein
unknown
uncultivated organism

effectors

MG35
292
MG35-244 effector
protein
unknown
uncultivated organism

effectors

MG35
293
MG35-245 effector
protein
unknown
uncultivated organism

effectors

MG35
294
MG35-246 effector
protein
unknown
uncultivated organism

effectors

MG35
295
MG35-247 effector
protein
unknown
uncultivated organism

effectors

MG35
296
MG35-248 effector
protein
unknown
uncultivated organism

effectors

MG35
297
MG35-249 effector
protein
unknown
uncultivated organism

effectors

MG35
298
MG35-250 effector
protein
unknown
uncultivated organism

effectors

MG35
299
MG35-251 effector
protein
unknown
uncultivated organism

effectors

MG35
300
MG35-252 effector
protein
unknown
uncultivated organism

effectors

MG35
301
MG35-253 effector
protein
unknown
uncultivated organism

effectors

MG35
302
MG35-254 effector
protein
unknown
uncultivated organism

effectors

MG35
303
MG35-255 effector
protein
unknown
uncultivated organism

effectors

MG35
304
MG35-256 effector
protein
unknown
uncultivated organism

effectors

MG35
305
MG35-257 effector
protein
unknown
uncultivated organism

effectors

MG35
306
MG35-258 effector
protein
unknown
uncultivated organism

effectors

MG35
307
MG35-259 effector
protein
unknown
uncultivated organism

effectors

MG35
308
MG35-260 effector
protein
unknown
uncultivated organism

effectors

MG35
309
MG35-261 effector
protein
unknown
uncultivated organism

effectors

MG35
310
MG35-262 effector
protein
unknown
uncultivated organism

effectors

MG35
311
MG35-263 effector
protein
unknown
uncultivated organism

effectors

MG35
312
MG35-264 effector
protein
unknown
uncultivated organism

effectors

MG35
313
MG35-265 effector
protein
unknown
uncultivated organism

effectors

MG35
314
MG35-266 effector
protein
unknown
uncultivated organism

effectors

MG35
315
MG35-267 effector
protein
unknown
uncultivated organism

effectors

MG35
316
MG35-268 effector
protein
unknown
uncultivated organism

effectors

MG35
317
MG35-269 effector
protein
unknown
uncultivated organism

effectors

MG35
318
MG35-270 effector
protein
unknown
uncultivated organism

effectors

MG35
319
MG35-271 effector
protein
unknown
uncultivated organism

effectors

MG35
320
MG35-272 effector
protein
unknown
uncultivated organism

effectors

MG35
321
MG35-273 effector
protein
unknown
uncultivated organism

effectors

MG35
322
MG35-274 effector
protein
unknown
uncultivated organism

effectors

MG35
323
MG35-275 effector
protein
unknown
uncultivated organism

effectors

MG35
324
MG35-276 effector
protein
unknown
uncultivated organism

effectors

MG35
325
MG35-277 effector
protein
unknown
uncultivated organism

effectors

MG35
326
MG35-278 effector
protein
unknown
uncultivated organism

effectors

MG35
327
MG35-279 effector
protein
unknown
uncultivated organism

effectors

MG35
328
MG35-280 effector
protein
unknown
uncultivated organism

effectors

MG35
329
MG35-281 effector
protein
unknown
uncultivated organism

effectors

MG35
330
MG35-282 effector
protein
unknown
uncultivated organism

effectors

MG35
331
MG35-283 effector
protein
unknown
uncultivated organism

effectors

MG35
332
MG35-284 effector
protein
unknown
uncultivated organism

effectors

MG35
333
MG35-285 effector
protein
unknown
uncultivated organism

effectors

MG35
334
MG35-286 effector
protein
unknown
uncultivated organism

effectors

MG35
335
MG35-287 effector
protein
unknown
uncultivated organism

effectors

MG35
336
MG35-288 effector
protein
unknown
uncultivated organism

effectors

MG35
337
MG35-289 effector
protein
unknown
uncultivated organism

effectors

MG35
338
MG35-290 effector
protein
unknown
uncultivated organism

effectors

MG35
339
MG35-291 effector
protein
unknown
uncultivated organism

effectors

MG35
340
MG35-292 effector
protein
unknown
uncultivated organism

effectors

MG35
341
MG35-293 effector
protein
unknown
uncultivated organism

effectors

MG35
342
MG35-294 effector
protein
unknown
uncultivated organism

effectors

MG35
343
MG35-295 effector
protein
unknown
uncultivated organism

effectors

MG35
344
MG35-296 effector
protein
unknown
uncultivated organism

effectors

MG35
345
MG35-297 effector
protein
unknown
uncultivated organism

effectors

MG35
346
MG35-298 effector
protein
unknown
uncultivated organism

effectors

MG35
347
MG35-299 effector
protein
unknown
uncultivated organism

effectors

MG35
348
MG35-300 effector
protein
unknown
uncultivated organism

effectors

MG35
349
MG35-301 effector
protein
unknown
uncultivated organism

effectors

MG35
350
MG35-302 effector
protein
unknown
uncultivated organism

effectors

MG35
351
MG35-303 effector
protein
unknown
uncultivated organism

effectors

MG35
352
MG35-304 effector
protein
unknown
uncultivated organism

effectors

MG35
353
MG35-305 effector
protein
unknown
uncultivated organism

effectors

MG35
354
MG35-307 effector
protein
unknown
uncultivated organism

effectors

MG35
355
MG35-308 effector
protein
unknown
uncultivated organism

effectors

MG35
356
MG35-309 effector
protein
unknown
uncultivated organism

effectors

MG35
357
MG35-310 effector
protein
unknown
uncultivated organism

effectors

MG35
358
MG35-311 effector
protein
unknown
uncultivated organism

effectors

MG35
359
MG35-312 effector
protein
unknown
uncultivated organism

effectors

MG35
360
MG35-313 effector
protein
unknown
uncultivated organism

effectors

MG35
361
MG35-314 effector
protein
unknown
uncultivated organism

effectors

MG35
362
MG35-315 effector
protein
unknown
uncultivated organism

effectors

MG35
363
MG35-316 effector
protein
unknown
uncultivated organism

effectors

MG35
364
MG35-317 effector
protein
unknown
uncultivated organism

effectors

MG35
365
MG35-318 effector
protein
unknown
uncultivated organism

effectors

MG35
366
MG35-319 effector
protein
unknown
uncultivated organism

effectors

MG35
367
MG35-320 effector
protein
unknown
uncultivated organism

effectors

MG35
368
MG35-321 effector
protein
unknown
uncultivated organism

effectors

MG35
369
MG35-322 effector
protein
unknown
uncultivated organism

effectors

MG35
370
MG35-323 effector
protein
unknown
uncultivated organism

effectors

MG35
371
MG35-324 effector
protein
unknown
uncultivated organism

effectors

MG35
372
MG35-325 effector
protein
unknown
uncultivated organism

effectors

MG35
373
MG35-326 effector
protein
unknown
uncultivated organism

effectors

MG35
374
MG35-327 effector
protein
unknown
uncultivated organism

effectors

MG35
375
MG35-328 effector
protein
unknown
uncultivated organism

effectors

MG35
376
MG35-329 effector
protein
unknown
uncultivated organism

effectors

MG35
377
MG35-330 effector
protein
unknown
uncultivated organism

effectors

MG35
378
MG35-331 effector
protein
unknown
uncultivated organism

effectors

MG35
379
MG35-333 effector
protein
unknown
uncultivated organism

effectors

MG35
380
MG35-334 effector
protein
unknown
uncultivated organism

effectors

MG35
381
MG35-335 effector
protein
unknown
uncultivated organism

effectors

MG35
382
MG35-336 effector
protein
unknown
uncultivated organism

effectors

MG35
383
MG35-337 effector
protein
unknown
uncultivated organism

effectors

MG35
384
MG35-338 effector
protein
unknown
uncultivated organism

effectors

MG35
385
MG35-339 effector
protein
unknown
uncultivated organism

effectors

MG35
386
MG35-340 effector
protein
unknown
uncultivated organism

effectors

MG35
387
MG35-341 effector
protein
unknown
uncultivated organism

effectors

MG35
388
MG35-342 effector
protein
unknown
uncultivated organism

effectors

MG35
389
MG35-343 effector
protein
unknown
uncultivated organism

effectors

MG35
390
MG35-344 effector
protein
unknown
uncultivated organism

effectors

MG35
391
MG35-345 effector
protein
unknown
uncultivated organism

effectors

MG35
392
MG35-346 effector
protein
unknown
uncultivated organism

effectors

MG35
393
MG35-347 effector
protein
unknown
uncultivated organism

effectors

MG35
394
MG35-348 effector
protein
unknown
uncultivated organism

effectors

MG35
395
MG35-349 effector
protein
unknown
uncultivated organism

effectors

MG35
396
MG35-350 effector
protein
unknown
uncultivated organism

effectors

MG35
397
MG35-351 effector
protein
unknown
uncultivated organism

effectors

MG35
398
MG35-352 effector
protein
unknown
uncultivated organism

effectors

MG35
399
MG35-353 effector
protein
unknown
uncultivated organism

effectors

MG35
400
MG35-354 effector
protein
unknown
uncultivated organism

effectors

MG35
401
MG35-355 effector
protein
unknown
uncultivated organism

effectors

MG35
402
MG35-356 effector
protein
unknown
uncultivated organism

effectors

MG35
403
MG35-357 effector
protein
unknown
uncultivated organism

effectors

MG35
404
MG35-358 effector
protein
unknown
uncultivated organism

effectors

MG35
405
MG35-359 effector
protein
unknown
uncultivated organism

effectors

MG35
406
MG35-360 effector
protein
unknown
uncultivated organism

effectors

MG35
407
MG35-361 effector
protein
unknown
uncultivated organism

effectors

MG35
408
MG35-362 effector
protein
unknown
uncultivated organism

effectors

MG35
409
MG35-363 effector
protein
unknown
uncultivated organism

effectors

MG35
410
MG35-364 effector
protein
unknown
uncultivated organism

effectors

MG35
411
MG35-365 effector
protein
unknown
uncultivated organism

effectors

MG35
412
MG35-366 effector
protein
unknown
uncultivated organism

effectors

MG35
413
MG35-367 effector
protein
unknown
uncultivated organism

effectors

MG35
414
MG35-368 effector
protein
unknown
uncultivated organism

effectors

MG35
415
MG35-369 effector
protein
unknown
uncultivated organism

effectors

MG35
416
MG35-370 effector
protein
unknown
uncultivated organism

effectors

MG35
417
MG35-371 effector
protein
unknown
uncultivated organism

effectors

MG35
418
MG35-372 effector
protein
unknown
uncultivated organism

effectors

MG35
419
MG35-373 effector
protein
unknown
uncultivated organism

effectors

MG35
420
MG35-374 effector
protein
unknown
uncultivated organism

effectors

MG35
421
MG35-375 effector
protein
unknown
uncultivated organism

effectors

MG35
422
MG35-376 effector
protein
unknown
uncultivated organism

effectors

MG35
423
MG35-377 effector
protein
unknown
uncultivated organism

effectors

MG35
424
MG35-378 effector
protein
unknown
uncultivated organism

effectors

MG35
425
MG35-379 effector
protein
unknown
uncultivated organism

effectors

MG35
426
MG35-384 effector
protein
unknown
uncultivated organism

effectors

MG35
427
MG35-385 effector
protein
unknown
uncultivated organism

effectors

MG35
428
MG35-386 effector
protein
unknown
uncultivated organism

effectors

MG35
429
MG35-387 effector
protein
unknown
uncultivated organism

effectors

MG35
430
MG35-388 effector
protein
unknown
uncultivated organism

effectors

MG35
431
MG35-389 effector
protein
unknown
uncultivated organism

effectors

MG35
432
MG35-390 effector
protein
unknown
uncultivated organism

effectors

MG35
433
MG35-391 effector
protein
unknown
uncultivated organism

effectors

MG35
434
MG35-392 effector
protein
unknown
uncultivated organism

effectors

MG35
435
MG35-393 effector
protein
unknown
uncultivated organism

effectors

MG35
436
MG35-394 effector
protein
unknown
uncultivated organism

effectors

MG35
437
MG35-395 effector
protein
unknown
uncultivated organism

effectors

MG35
438
MG35-396 effector
protein
unknown
uncultivated organism

effectors

MG35
439
MG35-397 effector
protein
unknown
uncultivated organism

effectors

MG35
440
MG35-398 effector
protein
unknown
uncultivated organism

effectors

MG35
441
MG35-399 effector
protein
unknown
uncultivated organism

effectors

MG35
442
MG35-400 effector
protein
unknown
uncultivated organism

effectors

MG35
443
MG35-401 effector
protein
unknown
uncultivated organism

effectors

MG35
444
MG35-402 effector
protein
unknown
uncultivated organism

effectors

MG35
445
MG35-403 effector
protein
unknown
uncultivated organism

effectors

MG35
446
MG35-404 effector
protein
unknown
uncultivated organism

effectors

MG35
447
MG35-405 effector
protein
unknown
uncultivated organism

effectors

MG35
448
MG35-406 effector
protein
unknown
uncultivated organism

effectors

MG35
449
MG35-408 effector
protein
unknown
uncultivated organism

effectors

MG35
450
MG35-409 effector
protein
unknown
uncultivated organism

effectors

MG35
451
MG35-410 effector
protein
unknown
uncultivated organism

effectors

MG35
452
MG35-411 effector
protein
unknown
uncultivated organism

effectors

MG35
453
MG35-412 effector
protein
unknown
uncultivated organism

effectors

MG35
454
MG35-413 effector
protein
unknown
uncultivated organism

effectors

MG35
455
MG35-414 effector
protein
unknown
uncultivated organism

effectors

MG35
456
MG35-415 effector
protein
unknown
uncultivated organism

effectors

MG35
457
MG35-416 effector
protein
unknown
uncultivated organism

effectors

MG35
458
MG35-417 effector
protein
unknown
uncultivated organism

effectors

MG35
459
MG35-418 effector
protein
unknown
uncultivated organism

effectors

MG35
460
MG35-4 tracrRNA sequence
nucleotide
artificial sequence

effectors

tracrRNA

sequence

putative
461
putative MG35-3 tracrRNA
nucleotide
artificial sequence

tracrRNA

repeat
462
MG35-3 repeat
nucleotide
artificial sequence

MG33
463
MG33-2 effector
protein
unknown
uncultivated organism

effectors

MG33
464
MG33-3 effector
protein
unknown
uncultivated organism

effectors

MG33
465
MG33-4 effector
protein
unknown
uncultivated organism

effectors

MG33
466
MG33-5 effector
protein
unknown
uncultivated organism

effectors

MG33
467
MG33-6 effector
protein
unknown
uncultivated organism

effectors

MG33
468
MG33-7 effector
protein
unknown
uncultivated organism

effectors

MG33
469
MG33-8 effector
protein
unknown
uncultivated organism

effectors

MG33
470
MG33-9 effector
protein
unknown
uncultivated organism

effectors

MG33
471
MG33-10 effector
protein
unknown
uncultivated organism

effectors

MG33
472
MG33-11 effector
protein
unknown
uncultivated organism

effectors

MG33
473
MG33-12 effector
protein
unknown
uncultivated organism

effectors

MG33
474
MG33-13 effector
protein
unknown
uncultivated organism

effectors

MG33
475
MG33-14 effector
protein
unknown
uncultivated organism

effectors

MG33
476
MG33-15 effector
protein
unknown
uncultivated organism

effectors

MG33
477
MG33-16 effector
protein
unknown
uncultivated organism

effectors

MG33
478
MG33-17 effector
protein
unknown
uncultivated organism

effectors

MG33
479
MG33-18 effector
protein
unknown
uncultivated organism

effectors

MG33
480
MG33-19 effector
protein
unknown
uncultivated organism

effectors

MG33
481
MG33-20 effector
protein
unknown
uncultivated organism

effectors

MG33
482
MG33-21 effector
protein
unknown
uncultivated organism

effectors

MG33
483
MG33-22 effector
protein
unknown
uncultivated organism

effectors

MG33
484
MG33-23 effector
protein
unknown
uncultivated organism

effectors

MG33
485
MG33-24 effector
protein
unknown
uncultivated organism

effectors

MG33
486
MG33-26 effector
protein
unknown
uncultivated organism

effectors

MG34
487
MG34-23 effector
protein
unknown
uncultivated organism

effectors

MG34
488
MG34-24 effector
protein
unknown
uncultivated organism

effectors

MG35
489
MG35-422 effector
protein
unknown
uncultivated organism

effectors

MG35
490
MG35-423 effector
protein
unknown
uncultivated organism

effectors

MG35
491
MG35-424 effector
protein
unknown
uncultivated organism

effectors

MG35
492
MG35-425 effector
protein
unknown
uncultivated organism

effectors

MG35
493
MG35-426 effector
protein
unknown
uncultivated organism

effectors

MG35
494
MG35-427 effector
protein
unknown
uncultivated organism

effectors

MG35
495
MG35-428 effector
protein
unknown
uncultivated organism

effectors

MG35
496
MG35-429 effector
protein
unknown
uncultivated organism

effectors

MG35
497
MG35-430 effector
protein
unknown
uncultivated organism

effectors

MG35
498
MG35-431 effector
protein
unknown
uncultivated organism

effectors

MG35
499
MG35-432 effector
protein
unknown
uncultivated organism

effectors

MG35
500
MG35-433 effector
protein
unknown
uncultivated organism

effectors

MG35
501
MG35-434 effector
protein
unknown
uncultivated organism

effectors

MG35
502
MG35-435 effector
protein
unknown
uncultivated organism

effectors

MG35
503
MG35-436 effector
protein
unknown
uncultivated organism

effectors

MG35
504
MG35-437 effector
protein
unknown
uncultivated organism

effectors

MG35
505
MG35-438 effector
protein
unknown
uncultivated organism

effectors

MG35
506
MG35-439 effector
protein
unknown
uncultivated organism

effectors

MG35
507
MG35-440 effector
protein
unknown
uncultivated organism

effectors

MG35
508
MG35-441 effector
protein
unknown
uncultivated organism

effectors

MG35
509
MG35-442 effector
protein
unknown
uncultivated organism

effectors

MG35
510
MG35-443 effector
protein
unknown
uncultivated organism

effectors

MG35
511
MG35-444 effector
protein
unknown
uncultivated organism

effectors

MG35
512
MG35-445 effector
protein
unknown
uncultivated organism

effectors

MG35
513
MG35-446 effector
protein
unknown
uncultivated organism

effectors

MG35
514
MG35-447 effector
protein
unknown
uncultivated organism

effectors

MG35
515
MG35-448 effector
protein
unknown
uncultivated organism

effectors

MG35
516
MG35-449 effector
protein
unknown
uncultivated organism

effectors

MG35
517
MG35-450 effector
protein
unknown
uncultivated organism

effectors

MG35
518
MG35-451 effector
protein
unknown
uncultivated organism

effectors

MG35
519
MG35-452 effector
protein
unknown
uncultivated organism

effectors

MG35
520
MG35-453 effector
protein
unknown
uncultivated organism

effectors

MG35
521
MG35-454 effector
protein
unknown
uncultivated organism

effectors

MG35
522
MG35-455 effector
protein
unknown
uncultivated organism

effectors

MG35
523
MG35-456 effector
protein
unknown
uncultivated organism

effectors

MG35
524
MG35-457 effector
protein
unknown
uncultivated organism

effectors

MG35
525
MG35-458 effector
protein
unknown
uncultivated organism

effectors

MG35
526
MG35-459 effector
protein
unknown
uncultivated organism

effectors

MG35
527
MG35-460 effector
protein
unknown
uncultivated organism

effectors

MG35
528
MG35-461 effector
protein
unknown
uncultivated organism

effectors

MG35
529
MG35-462 effector
protein
unknown
uncultivated organism

effectors

MG35
530
MG35-463 effector
protein
unknown
uncultivated organism

effectors

MG35
531
MG35-464 effector
protein
unknown
uncultivated organism

effectors

MG35
532
MG35-465 effector
protein
unknown
uncultivated organism

effectors

MG35
533
MG35-466 effector
protein
unknown
uncultivated organism

effectors

MG35
534
MG35-467 effector
protein
unknown
uncultivated organism

effectors

MG35
535
MG35-468 effector
protein
unknown
uncultivated organism

effectors

MG35
536
MG35-469 effector
protein
unknown
uncultivated organism

effectors

MG35
537
MG35-470 effector
protein
unknown
uncultivated organism

effectors

MG35
538
MG35-471 effector
protein
unknown
uncultivated organism

effectors

MG35
539
MG35-472 effector
protein
unknown
uncultivated organism

effectors

MG35
540
MG35-473 effector
protein
unknown
uncultivated organism

effectors

MG35
541
MG35-474 effector
protein
unknown
uncultivated organism

effectors

MG35
542
MG35-475 effector
protein
unknown
uncultivated organism

effectors

MG35
543
MG35-476 effector
protein
unknown
uncultivated organism

effectors

MG35
544
MG35-477 effector
protein
unknown
uncultivated organism

effectors

MG35
545
MG35-478 effector
protein
unknown
uncultivated organism

effectors

MG35
546
MG35-479 effector
protein
unknown
uncultivated organism

effectors

MG35
547
MG35-480 effector
protein
unknown
uncultivated organism

effectors

MG35
548
MG35-481 effector
protein
unknown
uncultivated organism

effectors

MG35
549
MG35-482 effector
protein
unknown
uncultivated organism

effectors

MG35
550
MG35-483 effector
protein
unknown
uncultivated organism

effectors

MG35
551
MG35-484 effector
protein
unknown
uncultivated organism

effectors

MG35
552
MG35-485 effector
protein
unknown
uncultivated organism

effectors

MG35
553
MG35-486 effector
protein
unknown
uncultivated organism

effectors

MG35
554
MG35-487 effector
protein
unknown
uncultivated organism

effectors

MG35
555
MG35-488 effector
protein
unknown
uncultivated organism

effectors

MG35
556
MG35-489 effector
protein
unknown
uncultivated organism

effectors

MG35
557
MG35-490 effector
protein
unknown
uncultivated organism

effectors

MG35
558
MG35-491 effector
protein
unknown
uncultivated organism

effectors

MG35
559
MG35-492 effector
protein
unknown
uncultivated organism

effectors

MG35
560
MG35-493 effector
protein
unknown
uncultivated organism

effectors

MG35
561
MG35-494 effector
protein
unknown
uncultivated organism

effectors

MG35
562
MG35-495 effector
protein
unknown
uncultivated organism

effectors

MG35
563
MG35-496 effector
protein
unknown
uncultivated organism

effectors

MG35
564
MG35-497 effector
protein
unknown
uncultivated organism

effectors

MG35
565
MG35-498 effector
protein
unknown
uncultivated organism

effectors

MG35
566
MG35-499 effector
protein
unknown
uncultivated organism

effectors

MG35
567
MG35-500 effector
protein
unknown
uncultivated organism

effectors

MG35
568
MG35-501 effector
protein
unknown
uncultivated organism

effectors

MG35
569
MG35-502 effector
protein
unknown
uncultivated organism

effectors

MG35
570
MG35-503 effector
protein
unknown
uncultivated organism

effectors

MG35
571
MG35-504 effector
protein
unknown
uncultivated organism

effectors

MG35
572
MG35-505 effector
protein
unknown
uncultivated organism

effectors

MG35
573
MG35-506 effector
protein
unknown
uncultivated organism

effectors

MG35
574
MG35-507 effector
protein
unknown
uncultivated organism

effectors

MG35
575
MG35-508 effector
protein
unknown
uncultivated organism

effectors

MG35
576
MG35-509 effector
protein
unknown
uncultivated organism

effectors

MG35
577
MG35-510 effector
protein
unknown
uncultivated organism

effectors

MG35
578
MG35-511 effector
protein
unknown
uncultivated organism

effectors

MG35
579
MG35-512 effector
protein
unknown
uncultivated organism

effectors

MG35
580
MG35-513 effector
protein
unknown
uncultivated organism

effectors

MG102
581
MG102-1 effector
protein
unknown
uncultivated organism

effectors

MG102
582
MG102-2 effector
protein
unknown
uncultivated organism

effectors

MG102
583
MG102-3 effector
protein
unknown
uncultivated organism

effectors

MG102
584
MG102-4 effector
protein
unknown
uncultivated organism

effectors

MG102
585
MG102-5 effector
protein
unknown
uncultivated organism

effectors

MG102
586
MG102-6 effector
protein
unknown
uncultivated organism

effectors

MG102
587
MG102-7 effector
protein
unknown
uncultivated organism

effectors

MG102
588
MG102-8 effector
protein
unknown
uncultivated organism

effectors

MG102
589
MG102-9 effector
protein
unknown
uncultivated organism

effectors

MG102
590
MG102-10 effector
protein
unknown
uncultivated organism

effectors

MG102
591
MG102-11 effector
protein
unknown
uncultivated organism

effectors

MG102
592
MG102-12 effector
protein
unknown
uncultivated organism

effectors

MG102
593
MG102-13 effector
protein
unknown
uncultivated organism

effectors

MG102
594
MG102-14 effector
protein
unknown
uncultivated organism

effectors

MG102
595
MG102-15 effector
protein
unknown
uncultivated organism

effectors

MG102
596
MG102-16 effector
protein
unknown
uncultivated organism

effectors

MG102
597
MG102-17 effector
protein
unknown
uncultivated organism

effectors

MG102
598
MG102-18 effector
protein
unknown
uncultivated organism

effectors

MG102
599
MG102-19 effector
protein
unknown
uncultivated organism

effectors

MG102
600
MG102-20 effector
protein
unknown
uncultivated organism

effectors

MG102
601
MG102-21 effector
protein
unknown
uncultivated organism

effectors

MG102
602
MG102-22 effector
protein
unknown
uncultivated organism

effectors

MG102
603
MG102-23 effector
protein
unknown
uncultivated organism

effectors

MG102
604
MG102-24 effector
protein
unknown
uncultivated organism

effectors

MG102
605
MG102-25 effector
protein
unknown
uncultivated organism

effectors

MG102
606
MG102-27 effector
protein
unknown
uncultivated organism

effectors

MG102
607
MG102-28 effector
protein
unknown
uncultivated organism

effectors

MG102
608
MG102-29 effector
protein
unknown
uncultivated organism

effectors

MG102
609
MG102-30 effector
protein
unknown
uncultivated organism

effectors

MG102
610
MG102-31 effector
protein
unknown
uncultivated organism

effectors

MG102
611
MG102-32 effector
protein
unknown
uncultivated organism

effectors

MG102
612
MG102-33 effector
protein
unknown
uncultivated organism

effectors

MG34
613
MG34-1 active effectors sgRNA 1
nucleotide
unknown
uncultivated organism

sgRNA

MG34
614
MG34-1 active effectors sgRNA 2
nucleotide
unknown
uncultivated organism

sgRNA

MG34
615
MG34-9 active effectors sgRNA 1
nucleotide
unknown
uncultivated organism

sgRNA

MG34
616
MG34-16 active effectors sgRNA 1
nucleotide
unknown
uncultivated organism

sgRNA

MG35
617
MG35-514 effector
protein
unknown
uncultivated organism

effectors

MG35
618
MG35-515 effector
protein
unknown
uncultivated organism

effectors

MG35
619
MG35-516 effector
protein
unknown
uncultivated organism

effectors

MG35
620
MG35-517 effector
protein
unknown
uncultivated organism

effectors

MG35
621
MG35-518 effector
protein
unknown
uncultivated organism

effectors

MG35
622
MG35-519 effector
protein
unknown
uncultivated organism

effectors

MG35
623
MG35-520 effector
protein
unknown
uncultivated organism

effectors

MG35
624
MG35-521 effector
protein
unknown
uncultivated organism

effectors

MG35
625
MG35-522 effector
protein
unknown
uncultivated organism

effectors

MG35
626
MG35-523 effector
protein
unknown
uncultivated organism

effectors

MG35
627
MG35-524 effector
protein
unknown
uncultivated organism

effectors

MG35
628
MG35-525 effector
protein
unknown
uncultivated organism

effectors

MG35
629
MG35-526 effector
protein
unknown
uncultivated organism

effectors

MG35
630
MG35-527 effector
protein
unknown
uncultivated organism

effectors

MG35
631
MG35-528 effector
protein
unknown
uncultivated organism

effectors

MG35
632
MG35-529 effector
protein
unknown
uncultivated organism

effectors

MG35
633
MG35-530 effector
protein
unknown
uncultivated organism

effectors

MG35
634
MG35-531 effector
protein
unknown
uncultivated organism

effectors

MG35
635
MG35-532 effector
protein
unknown
uncultivated organism

effectors

MG35
636
MG35-533 effector
protein
unknown
uncultivated organism

effectors

MG35
637
MG35-534 effector
protein
unknown
uncultivated organism

effectors

MG35
638
MG35-535 effector
protein
unknown
uncultivated organism

effectors

MG35
639
MG35-536 effector
protein
unknown
uncultivated organism

effectors

MG35
640
MG35-537 effector
protein
unknown
uncultivated organism

effectors

MG35
641
MG35-538 effector
protein
unknown
uncultivated organism

effectors

MG35
642
MG35-539 effector
protein
unknown
uncultivated organism

effectors

MG35
643
MG35-540 effector
protein
unknown
uncultivated organism

effectors

MG35
644
MG35-541 effector
protein
unknown
uncultivated organism

effectors

MG35
645
MG35-542 effector
protein
unknown
uncultivated organism

effectors

MG35
646
MG35-543 effector
protein
unknown
uncultivated organism

effectors

MG35
647
MG35-544 effector
protein
unknown
uncultivated organism

effectors

MG35
648
MG35-545 effector
protein
unknown
uncultivated organism

effectors

MG35
649
MG35-546 effector
protein
unknown
uncultivated organism

effectors

MG35
650
MG35-547 effector
protein
unknown
uncultivated organism

effectors

MG35
651
MG35-548 effector
protein
unknown
uncultivated organism

effectors

MG35
652
MG35-549 effector
protein
unknown
uncultivated organism

effectors

MG35
653
MG35-550 effector
protein
unknown
uncultivated organism

effectors

MG35
654
MG35-551 effector
protein
unknown
uncultivated organism

effectors

MG35
655
MG35-552 effector
protein
unknown
uncultivated organism

effectors

MG35
656
MG35-553 effector
protein
unknown
uncultivated organism

effectors

MG35
657
MG35-554 effector
protein
unknown
uncultivated organism

effectors

MG35
658
MG35-555 effector
protein
unknown
uncultivated organism

effectors

MG35
659
MG35-556 effector
protein
unknown
uncultivated organism

effectors

MG35
660
MG35-557 effector
protein
unknown
uncultivated organism

effectors

MG35
661
MG35-558 effector
protein
unknown
uncultivated organism

effectors

MG35
662
MG35-559 effector
protein
unknown
uncultivated organism

effectors

MG35
663
MG35-560 effector
protein
unknown
uncultivated organism

effectors

MG35
664
MG35-561 effector
protein
unknown
uncultivated organism

effectors

MG35
665
MG35-562 effector
protein
unknown
uncultivated organism

effectors

MG35
666
MG35-563 effector
protein
unknown
uncultivated organism

effectors

MG35
667
MG35-564 effector
protein
unknown
uncultivated organism

effectors

MG35
668
MG35-565 effector
protein
unknown
uncultivated organism

effectors

MG33
669
MG33-2 tracrRNA 1
nucleotide
artificial sequence
MG33 tracrRNA

tracrRNA

MG33
670
MG33-2 tracrRNA 2
nucleotide
artificial sequence
MG33 tracrRNA

tracrRNA

MG33
671
MG33-3 tracrRNA 1
nucleotide
artificial sequence
MG33 tracrRNA

tracrRNA

MG102
672
MG102-1 tracrRNA 1
nucleotide
artificial sequence
MG102 tracrRNA

tracrRNA

MG102
673
MG102-2 tracrRNA 1
nucleotide
artificial sequence
MG102 tracrRNA

tracrRNA

MG35
674
MG35-566 effector
protein
unknown
uncultivated organism

effectors

MG35
675
MG35-567 effector
protein
unknown
uncultivated organism

effectors

MG35
676
MG35-420 predicted CRISPR repeat
nucleotide
unknown
uncultivated organism

predicted

CRISPR

repeat

MG35
677
MG35-1 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA 1

single

guide

RNAs

MG35
678
MG35-1 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA 2

single

guide

RNAs

MG35
679
MG35-2 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA 1

single

guide

RNAs

MG35
680
MG35-3 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA 1

single

guide

RNAs

MG35
681
MG35-3 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA 2

single

guide

RNAs

MG35
682
MG35-419 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA 1

single

guide

RNAs

MG35
683
MG35-419 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA 2

single

guide

RNAs

MG35
684
MG35-420 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA 1

single

guide

RNAs

MG35
685
MG35-421 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA 1

single

guide

RNAs

MG35
686
MG35-102 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA 1

single

guide

RNAs

MG35
687
MG35-1, MG35-90 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
688
MG35-2, MG35-50, MG35-51
nucleotide
unknown
uncultivated organism

putative

effectors putative single guide RNA

single

encoding sequence

guide

RNA

encoding

sequences

MG35
689
MG35-3, MG35-85 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
690
MG35-32 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
691
MG35-36, MG35-152, MG35-153,
nucleotide
unknown
uncultivated organism

putative

MG35-154, MG35-155 effectors

single

putative single guide RNA encoding

guide

sequence

RNA

encoding

sequences

MG35
692
MG35-37 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
693
MG35-38 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
694
MG35-40, MG35-42, MG35-43
nucleotide
unknown
uncultivated organism

putative

effectors putative single guide RNA

single

encoding sequence

guide

RNA

encoding

sequences

MG35
695
MG35-41 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
696
MG35-44 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
697
MG35-45, MG35-39, MG35-116,
nucleotide
unknown
uncultivated organism

putative

MG35-219 effectors putative single

single

guide RNA encoding sequence

guide

RNA

encoding

sequences

MG35
698
MG35-46 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
699
MG35-48 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
700
MG35-49 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
701
MG35-52 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
702
MG35-53, MG35-54 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
703
MG35-55 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
704
MG35-56, MG35-287 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
705
MG35-57 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
706
MG35-58, MG35-59 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
707
MG35-60 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
708
MG35-62 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
709
MG35-63 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
710
MG35-65 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
711
MG35-66 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
712
MG35-67, MG35-71 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
713
MG35-68, MG35-64, MG35-69,
nucleotide
unknown
uncultivated organism

putative

MG35-70, MG35-75 effectors

single

putative single guide RNA encoding

guide

sequence

RNA

encoding

sequences

MG35
714
MG35-72 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
715
MG35-73 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
716
MG35-74 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
717
MG35-77 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
718
MG35-78 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
719
MG35-79, MG35-97, MG35-98
nucleotide
unknown
uncultivated organism

putative

effectors putative single guide RNA

single

encoding sequence

guide

RNA

encoding

sequences

MG35
720
MG35-80, MG35-81 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
721
MG35-82, MG35-95, MG35-96
nucleotide
unknown
uncultivated organism

putative

effectors putative single guide RNA

single

encoding sequence

guide

RNA

encoding

sequences

MG35
722
MG35-86 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
723
MG35-87, MG35-88, MG35-89
nucleotide
unknown
uncultivated organism

putative

effectors putative single guide RNA

single

encoding sequence

guide

RNA

encoding

sequences

MG35
724
MG35-91, MG35-92 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
725
MG35-93, MG35-94 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
726
MG35-99 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
727
MG35-101 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
728
MG35-102 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
729
MG35-103, MG35-104 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
730
MG35-105 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
731
MG35-106 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
732
MG35-107 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
733
MG35-108 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
734
MG35-109 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
735
MG35-110, MG35-112 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
736
MG35-111 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
737
MG35-113 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
738
MG35-114 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
739
MG35-115 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
740
MG35-116 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
741
MG35-117, MG35-118, MG35-119
nucleotide
unknown
uncultivated organism

putative

effectors putative single guide RNA

single

encoding sequence

guide

RNA

encoding

sequences

MG35
742
MG35-120 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
743
MG35-121 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
744
MG35-122 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
745
MG35-123, MG35-124 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
746
MG35-125 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
747
MG35-126, MG35-377 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
748
MG35-127 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
749
MG35-128 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
750
MG35-129 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
751
MG35-130 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
752
MG35-131 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
753
MG35-147 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
754
MG35-148 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
755
MG35-149 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
756
MG35-150 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
757
MG35-151 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
758
MG35-152 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
759
MG35-153 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
760
MG35-156, MG35-161 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
761
MG35-157 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
762
MG35-159, MG35-158 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
763
MG35-160 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
764
MG35-165, MG35-166 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
765
MG35-171 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
766
MG35-214 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
767
MG35-217 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
768
MG35-218 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
769
MG35-220 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
770
MG35-221, MG35-222, MG35-351,
nucleotide
unknown
uncultivated organism

putative

MG35-352, MG35-353 effectors

single

putative single guide RNA encoding

guide

sequence

RNA

encoding

sequences

MG35
771
MG35-223 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
772
MG35-224 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
773
MG35-225 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
774
MG35-226 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
775
MG35-227 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
776
MG35-228 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
777
MG35-229 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
778
MG35-230 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
779
MG35-231 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
780
MG35-232 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
781
MG35-233 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
782
MG35-235 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
783
MG35-236 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
784
MG35-238, MG35-237 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
785
MG35-239, MG35-240, MG35-241
nucleotide
unknown
uncultivated organism

putative

effectors putative single guide RNA

single

encoding sequence

guide

RNA

encoding

sequences

MG35
786
MG35-242 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
787
MG35-243 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
788
MG35-244 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
789
MG35-245 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
790
MG35-246 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
791
MG35-247 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
792
MG35-248 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
793
MG35-249 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
794
MG35-250, MG35-251 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
795
MG35-252 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
796
MG35-253 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
797
MG35-255 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
798
MG35-256 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
799
MG35-257 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
800
MG35-258 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
801
MG35-259 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
802
MG35-260 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
803
MG35-262, MG35-263 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
804
MG35-266, MG35-270 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
805
MG35-267 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
806
MG35-268 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
807
MG35-269, MG35-264, MG35-265
nucleotide
unknown
uncultivated organism

putative

effectors putative single guide RNA

single

encoding sequence

guide

RNA

encoding

sequences

MG35
808
MG35-271 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
809
MG35-272 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
810
MG35-273 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
811
MG35-274 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
812
MG35-275 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
813
MG35-276 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
814
MG35-277 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
815
MG35-278 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
816
MG35-279 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
817
MG35-280 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
818
MG35-281 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
819
MG35-282, MG35-283 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
820
MG35-284 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
821
MG35-285 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
822
MG35-286 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
823
MG35-292, MG35-293 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
824
MG35-296 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
825
MG35-298, MG35-299 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
826
MG35-300 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
827
MG35-302 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
828
MG35-303 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
829
MG35-305 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
830
MG35-307 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
831
MG35-308 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
832
MG35-309 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
833
MG35-310 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
834
MG35-311 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
835
MG35-312 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
836
MG35-313 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
837
MG35-314, MG35-261 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
838
MG35-315 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
839
MG35-316 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
840
MG35-317 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
841
MG35-318 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
842
MG35-319 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
843
MG35-321 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
844
MG35-322 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
845
MG35-325 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
846
MG35-326 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
847
MG35-327 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
848
MG35-328 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
849
MG35-329 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
850
MG35-330 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
851
MG35-331 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
852
MG35-332, MG35-333, MG35-335
nucleotide
unknown
uncultivated organism

putative

effectors putative single guide RNA

single

encoding sequence

guide

RNA

encoding

sequences

MG35
853
MG35-334 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
854
MG35-336 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
855
MG35-340 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
856
MG35-341 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
857
MG35-342 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
858
MG35-343 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
859
MG35-344, MG35-345 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
860
MG35-346, MG35-347 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
861
MG35-348 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
862
MG35-349 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
863
MG35-350 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
864
MG35-354 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
865
MG35-355, MG35-356 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
866
MG35-357 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
867
MG35-358 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
868
MG35-359 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
869
MG35-360, MG35-361 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
870
MG35-362 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
871
MG35-363 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
872
MG35-364 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
873
MG35-365 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
874
MG35-366 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
875
MG35-367 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
876
MG35-368, MG35-369 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
877
MG35-370 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
878
MG35-371 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
879
MG35-372, MG35-373 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
880
MG35-374 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
881
MG35-375 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
882
MG35-376 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
883
MG35-378 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
884
MG35-379 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
885
MG35-384 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
886
MG35-386 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
887
MG35-388 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
888
MG35-419, MG35-339 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
889
MG35-420, MG35-337 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
890
MG35-421, MG35-338 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
891
MG35-422 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
892
MG35-423 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
893
MG35-424 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
894
MG35-426 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
895
MG35-427 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
896
MG35-428, MG35-436, MG35-437,
nucleotide
unknown
uncultivated organism

putative

MG35-457 effectors putative single

single

guide RNA encoding sequence

guide

RNA

encoding

sequences

MG35
897
MG35-429, MG35-449 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
898
MG35-430 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
899
MG35-431, MG35-442 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
900
MG35-432 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
901
MG35-433, MG35-425 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
902
MG35-434, MG35-455 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
903
MG35-435 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
904
MG35-438 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
905
MG35-439 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
906
MG35-440 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
907
MG35-441, MG35-443 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
908
MG35-444 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
909
MG35-445 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
910
MG35-446, MG35-448, MG35-456
nucleotide
unknown
uncultivated organism

putative

effectors putative single guide RNA

single

encoding sequence

guide

RNA

encoding

sequences

MG35
911
MG35-447 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
912
MG35-450 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
913
MG35-451 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
914
MG35-452 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
915
MG35-453 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
916
MG35-454 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
917
MG35-458, MG35-523 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
918
MG35-459 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
919
MG35-460 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
920
MG35-461 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
921
MG35-462 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
922
MG35-463 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
923
MG35-464 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
924
MG35-465 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
925
MG35-466 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
926
MG35-510 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
927
MG35-511, MG35-512 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
928
MG35-513 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
929
MG35-514 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
930
MG35-515 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
931
MG35-516 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
932
MG35-517 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
933
MG35-518 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
934
MG35-519 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
935
MG35-520 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
936
MG35-521 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
937
MG35-522, MG35-526, MG35-546,
nucleotide
unknown
uncultivated organism

putative

MG35-548 effectors putative single

single

guide RNA encoding sequence

guide

RNA

encoding

sequences

MG35
938
MG35-524 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
939
MG35-525, MG35-537 effectors
nucleotide
unknown
uncultivated organism

putative

putative single guide RNA encoding

single

sequence

guide

RNA

encoding

sequences

MG35
940
MG35-527 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
941
MG35-528 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
942
MG35-529 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
943
MG35-530 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
944
MG35-531 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
945
MG35-532 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
946
MG35-533 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
947
MG35-534 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
948
MG35-535 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
949
MG35-536 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
950
MG35-538 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
951
MG35-539 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
952
MG35-540 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
953
MG35-541 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
954
MG35-542 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
955
MG35-543 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
956
MG35-544 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
957
MG35-545 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
958
MG35-547 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
959
MG35-549 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
960
MG35-550 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
961
MG35-552 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
962
MG35-553 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
963
MG35-554 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
964
MG35-555 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
965
MG35-556 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
966
MG35-557 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
967
MG35-558 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
968
MG35-559 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
969
MG35-560 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
970
MG35-561 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
971
MG35-562 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
972
MG35-563 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
973
MG35-564 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG35
974
MG35-565 effector putative single
nucleotide
unknown
uncultivated organism

putative

guide RNA encoding sequence

single

guide

RNA

encoding

sequences

MG143
975
MG143-1 effector
protein
unknown
uncultivated organism

effectors

MG144
976
MG144-1 effector
protein
unknown
uncultivated organism

effectors

MG144
977
MG144-2 effector
protein
unknown
uncultivated organism

effectors

MG144
978
MG144-3 effector
protein
unknown
uncultivated organism

effectors

MG144
979
MG144-4 effector
protein
unknown
uncultivated organism

effectors

MG145
980
MG145-1 effector
protein
unknown
uncultivated organism

effectors

MG33
981
MG33-27 effector
protein
unknown
uncultivated organism

effectors

MG33
982
MG33-28 effector
protein
unknown
uncultivated organism

effectors

MG33
983
MG33-29 effector
protein
unknown
uncultivated organism

effectors

MG33
984
MG33-30 effector
protein
unknown
uncultivated organism

effectors

MG33
985
MG33-31 effector
protein
unknown
uncultivated organism

effectors

MG33
986
MG33-32 effector
protein
unknown
uncultivated organism

effectors

MG33
987
MG33-33 effector
protein
unknown
uncultivated organism

effectors

MG33
988
MG33-34 effector
protein
unknown
uncultivated organism

effectors

MG102
989
MG102-35 effector
protein
unknown
uncultivated organism

effectors

MG102
990
MG102-36 effector
protein
unknown
uncultivated organism

effectors

MG102
991
MG102-37 effector
protein
unknown
uncultivated organism

effectors

MG102
992
MG102-38 effector
protein
unknown
uncultivated organism

effectors

MG102
993
MG102-39 effector
protein
unknown
uncultivated organism

effectors

MG102
994
MG102-40 effector
protein
unknown
uncultivated organism

effectors

MG102
995
MG102-41 effector
protein
unknown
uncultivated organism

effectors

MG102
996
MG102-42 effector
protein
unknown
uncultivated organism

effectors

MG102
997
MG102-43 effector
protein
unknown
uncultivated organism

effectors

MG102
998
MG102-44 effector
protein
unknown
uncultivated organism

effectors

MG102
999
MG102-45 effector
protein
unknown
uncultivated organism

effectors

MG102
1000
MG102-46 effector
protein
unknown
uncultivated organism

effectors

MG102
1001
MG102-47 effector
protein
unknown
uncultivated organism

effectors

MG102
1002
MG102-48 effector
protein
unknown
uncultivated organism

effectors

MG33
1003
MG33-3 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG33
1004
MG33-31 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG33
1005
MG33-34 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG35
1006
MG35-1 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG35
1007
MG35-2 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG35
1008
MG35-3 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG35
1009
MG35-4 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG35
1010
MG35-5 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG35
1011
MG35-6 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG35
1012
MG35-102 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG102
1013
MG102-2 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG102
1014
MG102-14 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG102
1015
MG102-35 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG102
1016
MG102-36 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG102
1017
MG102-39 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG102
1018
MG102-42 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG102
1019
MG102-43 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG102
1020
MG102-45 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG102
1021
MG102-47 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG102
1022
MG102-48 active effectors sgRNA
nucleotide
artificial sequence
N/A

active

effectors

sgRNA

MG33
1023
MG34-1, MG34-9, MG34-16,
nucleotide
artificial sequence
N/A
nGG

active

MG33-3, MG33-31, MG33-34 active

effectors

effectors PAM

PAM

MG33
1024
MG33-31, MG33-34 active effectors
nucleotide
artificial sequence
N/A
nGGnnnnn

active

PAM

effectors

PAM

MG33
1025
MG33-31, MG33-34 active effectors
nucleotide
artificial sequence
N/A
nGGnnnnn

active

PAM

effectors

PAM

MG34
1026
MG34-1, MG34-9, MG34-16,
nucleotide
artificial sequence
N/A
nGG

active

MG33-3 active effectors PAM

effectors

PAM

MG34
1027
MG34-1, MG34-9, MG34-16,
nucleotide
artificial sequence
N/A
nGG

active

MG33-3 active effectors PAM

effectors

PAM

MG34
1028
MG34-1, MG34-9, MG34-16,
nucleotide
artificial sequence
N/A
nGG

active

MG33-3 active effectors PAM

effectors

PAM

MG35
1029
MG35-1 active effectors PAM
nucleotide
artificial sequence
N/A
AnGg

active

effectors

PAM

MG35
1030
MG35-2 active effectors PAM
nucleotide
artificial sequence
N/A
nARAA

active

effectors

PAM

MG35
1031
MG35-3 active effectors PAM
nucleotide
artificial sequence
N/A
ATGaaa

active

effectors

PAM

MG35
1032
MG35-4 active effectors PAM
nucleotide
artificial sequence
N/A
ATGA

active

effectors

PAM

MG35
1033
MG35-5 active effectors PAM
nucleotide
artificial sequence
N/A
WTGG

active

effectors

PAM

MG35
1034
MG35-102 active effectors PAM
nucleotide
artificial sequence
N/A
RTGA

active

effectors

PAM

MG102
1035
MG102-2 active effectors PAM
nucleotide
artificial sequence
N/A
nRC

active

effectors

PAM

MG102
1036
MG102-14, MG102-35, MG102-36,
nucleotide
artificial sequence
N/A
nRCnnnnn

active

MG102-42, MG102-43, MG102-45,

effectors

MG102-47, MG102-48 active

PAM

effectors PAM

MG102
1037
MG102-14, MG102-35, MG102-36,
nucleotide
artificial sequence
N/A
nRCnnnnn

active

MG102-42, MG102-43, MG102-45,

effectors

MG102-47, MG102-48 active

PAM

effectors PAM

MG102
1038
MG102-14, MG102-35, MG102-36,
nucleotide
artificial sequence
N/A
nRCnnnnn

active

MG102-42, MG102-43, MG102-45,

effectors

MG102-47, MG102-48 active

PAM

effectors PAM

MG102
1039
MG102-39 active effectors PAM
nucleotide
artificial sequence
N/A
naRnnnnn

active

effectors

PAM

MG102
1040
MG102-14, MG102-35, MG102-36,
nucleotide
artificial sequence
N/A
nRCnnnnn

active

MG102-42, MG102-43, MG102-45,

effectors

MG102-47, MG102-48 active

PAM

effectors PAM

MG102
1041
MG102-14, MG102-35, MG102-36,
nucleotide
artificial sequence
N/A
nRCnnnnn

active

MG102-42, MG102-43, MG102-45,

effectors

MG102-47, MG102-48 active

PAM

effectors PAM

MG102
1042
MG102-14, MG102-35, MG102-36,
nucleotide
artificial sequence
N/A
nRCnnnnn

active

MG102-42, MG102-43, MG102-45,

effectors

MG102-47, MG102-48 active

PAM

effectors PAM

MG102
1043
MG102-14, MG102-35, MG102-36,
nucleotide
artificial sequence
N/A
nRCnnnnn

active

MG102-42, MG102-43, MG102-45,

effectors

MG102-47, MG102-48 active

PAM

effectors PAM

MG102
1044
MG102-14, MG102-35, MG102-36,
nucleotide
artificial sequence
N/A
nRCnnnnn

active

MG102-42, MG102-43, MG102-45,

effectors

MG102-47, MG102-48 active

PAM

effectors PAM

MG33
1045
MG33-1 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG33
1046
MG33-2 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG33
1047
MG33-3 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG33
1048
MG33-27 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG33
1049
MG33-28 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG33
1050
MG33-29 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG33
1051
MG33-30 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG33
1052
MG33-31 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG33
1053
MG33-33 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG33
1054
MG33-34 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG34
1055
MG34-1, MG34-9 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG34
1056
MG34-1, MG34-9 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG34
1057
MG34-25 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102
1058
MG102-1 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102
1059
MG102-2 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102
1060
MG102-3 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102
1061
MG102-10 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102
1062
MG102-14 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102
1063
MG102-35 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102
1064
MG102-36 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102
1065
MG102-38 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102
1066
MG102-39 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102
1067
MG102-42 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102
1068
MG102-43 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102
1069
MG102-44 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102
1070
MG102-45 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102
1071
MG102-47 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102
1072
MG102-48 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG143
1073
MG143-1 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG144
1074
MG144-1 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG144
1075
MG144-2 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG144
1076
MG144-3, MG144-4 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG144
1077
MG144-3, MG144-4 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG145
1078
MG145-1 CRISPR repeat
nucleotide
unknown
uncultivated organism

CRISPR

repeats

MG102-2
1079
MG102-2 TRAC A1 24nt
nucleotide
artificial sequence
N/A

human

TRAC

target site

MG102-2
1080
MG102-2 TRAC B1 24nt
nucleotide
artificial sequence
N/A

human

TRAC

target site

MG102-2
1081
MG102-2 TRAC A1 20nt
nucleotide
artificial sequence
N/A

human

TRAC

target site

MG102-2
1082
MG102-2 TRAC B1 20nt
nucleotide
artificial sequence
N/A

human

TRAC

target site

MG102-2
1083
MG102-2 TRAC A1 24nt sgRNA
nucleotide
artificial sequence
N/A

human

TRAC

sgRNA

MG102-2
1084
MG102-2 TRAC B1 24nt sgRNA
nucleotide
artificial sequence
N/A

human

TRAC

sgRNA

MG102-2
1085
MG102-2 TRAC A1 20nt sgRNA
nucleotide
artificial sequence
N/A

human

TRAC

sgRNA

MG102-2
1086
MG102-2 TRAC B1 20nt sgRNA
nucleotide
artificial sequence
N/A

human

TRAC

sgRNA

MG102-2
1087
MG102-2 AAVS1 A5
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1088
MG102-2 AAVS1 H8
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1089
MG102-2 AAVS1 H9
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1090
MG102-2 AAVS1 D11
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1091
MG102-2 AAVS1 E7
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1092
MG102-2 AAVS1 D7
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1093
MG102-2 AAVS1 B7
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1094
MG102-2 AAVS1 D12
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1095
MG102-2 AAVS1 C8
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1096
MG102-2 AAVS1 A8
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1097
MG102-2 AAVS1 G6
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1098
MG102-2 AAVS1 E5
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1099
MG102-2 AAVS1 G7
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1100
MG102-2 AAVS1 C3
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1101
MG102-2 AAVS1 E1
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1102
MG102-2 AAVS1 E2
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1103
MG102-2 AAVS1 H6
nucleotide
artificial sequence

guide

targeting

AAVS1

MG102-2
1104
MG102-2 AAVS1 H11
nucleotide
artificial sequence

guide

targeting

AAVS1

DNA
1105
MG102-2 AAVS1 A5
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1106
MG102-2 AAVS1 H8
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1107
MG102-2 AAVS1 H9
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1108
MG102-2 AAVS1 D11
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1109
MG102-2 AAVS1 E7
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1110
MG102-2 AAVS1 D7
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1111
MG102-2 AAVS1 B7
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1112
MG102-2 AAVS1 D12
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1113
MG102-2 AAVS1 C8
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1114
MG102-2 AAVS1 A8
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1115
MG102-2 AAVS1 G6
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1116
MG102-2 AAVS1 E5
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1117
MG102-2 AAVS1 G7
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1118
MG102-2 AAVS1 C3
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1119
MG102-2 AAVS1 E1
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1120
MG102-2 AAVS1 E2
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1121
MG102-2 AAVS1 H6
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

DNA
1122
MG102-2 AAVS1 H11
nucleotide
artificial sequence

Sequence

of

AAVS1

Target

Site

MG102-
1123
MG102-36 TRAC D12
nucleotide
artificial sequence

36 guide

targeting

TRAC

MG102-
1124
MG102-36 TRAC F1
nucleotide
artificial sequence

36 guide

targeting

TRAC

MG102-
1125
MG102-36 TRAC H6
nucleotide
artificial sequence

36 guide

targeting

TRAC

MG102-
1126
MG102-39 TRAC F4
nucleotide
artificial sequence

39 guide

targeting

TRAC

MG102-
1127
MG102-39 TRAC A9
nucleotide
artificial sequence

39 guide

targeting

TRAC

MG102-
1128
MG102-39 TRAC G11
nucleotide
artificial sequence

39 guide

targeting

TRAC

MG102-
1129
MG102-39 TRAC C11
nucleotide
artificial sequence

39 guide

targeting

TRAC

MG102-
1130
MG102-39 TRAC B6
nucleotide
artificial sequence

39 guide

targeting

TRAC

MG102-
1131
MG102-39 TRAC B5
nucleotide
artificial sequence

39 guide

targeting

TRAC

MG102-
1132
MG102-39 TRAC G9
nucleotide
artificial sequence

39 guide

targeting

TRAC

MG102-
1133
MG102-39 TRAC D1
nucleotide
artificial sequence

39 guide

targeting

TRAC

MG102-
1134
MG102-39 TRAC B11
nucleotide
artificial sequence

39 guide

targeting

TRAC

MG102-
1135
MG102-39 TRAC D4
nucleotide
artificial sequence

39 guide

targeting

TRAC

MG102-
1136
MG102-39 TRAC F2
nucleotide
artificial sequence

39 guide

targeting

TRAC

MG102-
1137
MG102-39 TRAC G1
nucleotide
artificial sequence

39 guide

targeting

TRAC

MG102-
1138
MG102-42 TRAC D10
nucleotide
artificial sequence

42 guide

targeting

TRAC

MG102-
1139
MG102-42 TRAC D12
nucleotide
artificial sequence

42 guide

targeting

TRAC

MG102-
1140
MG102-42 TRAC E12
nucleotide
artificial sequence

42 guide

targeting

TRAC

MG102-
1141
MG102-45 TRAC B1
nucleotide
artificial sequence

45 guide

targeting

TRAC

MG102-
1142
MG102-45 TRAC C11
nucleotide
artificial sequence

45 guide

targeting

TRAC

MG102-
1143
MG102-48 TRAC A1
nucleotide
artificial sequence

48 guide

targeting

TRAC

MG102-
1144
MG102-48 TRAC D12
nucleotide
artificial sequence

48 guide

targeting

TRAC

DNA
1145
MG102-36 TRAC D12
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1146
MG102-36 TRAC F1
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1147
MG102-36 TRAC H6
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1148
MG102-39 TRAC F4
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1149
MG102-39 TRAC A9
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1150
MG102-39 TRAC G11
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1151
MG102-39 TRAC C11
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1152
MG102-39 TRAC B6
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1153
MG102-39 TRAC B5
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1154
MG102-39 TRAC G9
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1155
MG102-39 TRAC D1
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1156
MG102-39 TRAC B11
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1157
MG102-39 TRAC D4
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1158
MG102-39 TRAC F2
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1159
MG102-39 TRAC G1
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1160
MG102-42 TRAC D10
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1161
MG102-42 TRAC D12
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1162
MG102-42 TRAC E12
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1163
MG102-45 TRAC B1
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1164
MG102-45 TRAC C11
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1165
MG102-48 TRAC A1
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1166
MG102-48 TRAC D12
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

MG33-34
1167
MG33-34 TRAC F6
nucleotide
artificial sequence

guide

targeting

TRAC

MG33-34
1168
MG33-34 TRAC E6
nucleotide
artificial sequence

guide

targeting

TRAC

DNA
1169
MG33-34 TRAC F6
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

DNA
1170
MG33-34 TRAC E6
nucleotide
artificial sequence

Sequence

of TRAC

Target

Site

MG102
1171
MG102-33 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1172
MG35-3 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1173
MG35-7 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1174
MG35-15 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1175
MG35-20 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1176
MG35-46 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1177
MG35-58 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1178
MG35-59 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1179
MG35-76 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1180
MG35-99 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1181
MG35-100 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1182
MG35-102 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1183
MG35-103 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1184
MG35-104 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1185
MG35-114 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1186
MG35-132 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1187
MG35-168 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1188
MG35-176 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1189
MG35-177 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1190
MG35-179 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1191
MG35-201 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1192
MG35-231 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1193
MG35-232 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1194
MG35-233 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1195
MG35-237 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1196
MG35-238 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1197
MG35-240 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1198
MG35-291 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1199
MG35-296 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1200
MG35-298 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1201
MG35-299 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1202
MG35-302 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1203
MG35-309 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1204
MG35-323 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1205
MG35-326 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1206
MG35-337 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1207
MG35-339 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1208
MG35-344 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1209
MG35-345 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1210
MG35-346 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1211
MG35-347 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1212
MG35-348 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1213
MG35-349 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1214
MG35-350 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1215
MG35-354 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1216
MG35-357 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1217
MG35-358 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1218
MG35-359 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1219
MG35-364 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1220
MG35-366 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1221
MG35-393 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1222
MG35-404 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1223
MG35-411 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1224
MG35-418 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1225
MG35-419 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1226
MG35-420 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1227
MG35-421 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1228
MG35-423 locus encoding effector
nucleotide
unknown
uncultivated organism

locus

encoding

effectors

MG35
1229
MG35-463 CRISPR repeat
nucleotide
artificial sequence

predicted

CRISPR

repeat

MG35
1230
MG35-556 CRISPR repeat
nucleotide
artificial sequence

predicted

CRISPR

repeat

MG35
1231
MG35-94 sg1 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1232
MG35-94 sg2 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1233
MG35-94 sg3 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1234
MG35-104 sg1 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1235
MG35-350 sg3 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1236
MG35-463 sg2 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1237
MG35-463 sg3 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1238
MG35-515 sg2 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1239
MG35-515 sg3 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1240
MG35-517 sg2 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1241
MG35-518 sg1 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1242
MG35-519 sg1 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1243
MG35-519 sg2 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1244
MG35-519 sg3 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1245
MG35-550 sg1 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1246
MG35-553 sg1 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1247
MG35-554 sg3 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1248
MG35-554 sg4 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1249
MG35-104_M1 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1250
MG35-104_M2 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1251
MG35-104_M3 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1252
MG35-518_M1 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1253
MG35-518_M2 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1254
MG35-518_M3 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1255
MG35-553_M1 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1256
MG35-553_M2 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1257
MG35-553_M3 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1258
MG35-94_M2 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG35
1259
MG35-94_M3 single guide RNA
nucleotide
artificial sequence

active

effectors

sgRNA

MG102
1260
MG102-49 effector
protein
unknown
uncultivated organism

effectors

MG102
1261
MG102-50 effector
protein
unknown
uncultivated organism

effectors

MG102
1262
MG102-51 effector
protein
unknown
uncultivated organism

effectors

MG102
1263
MG102-52 effector
protein
unknown
uncultivated organism

effectors

MG102
1264
MG102-53 effector
protein
unknown
uncultivated organism

effectors

MG102
1265
MG102-54 effector
protein
unknown
uncultivated organism

effectors

MG102
1266
MG102-55 effector
protein
unknown
uncultivated organism

effectors

MG102
1267
MG102-56 effector
protein
unknown
uncultivated organism

effectors

MG102
1268
MG102-57 effector
protein
unknown
uncultivated organism

effectors

MG102
1269
MG102-58 effector
protein
unknown
uncultivated organism

effectors

MG102
1270
MG102-59 effector
protein
unknown
uncultivated organism

effectors

MG102
1271
MG102-60 effector
protein
unknown
uncultivated organism

effectors

MG102
1272
MG102-61 effector
protein
unknown
uncultivated organism

effectors

MG102
1273
MG102-62 effector
protein
unknown
uncultivated organism

effectors

MG144
1274
MG144-5 effector
protein
unknown
uncultivated organism

effectors

MG144
1275
MG144-6 effector
protein
unknown
uncultivated organism

effectors

MG144
1276
MG144-7 effector
protein
unknown
uncultivated organism

effectors

MG144
1277
MG144-8 effector
protein
unknown
uncultivated organism

effectors

MG144
1278
MG144-9 effector
protein
unknown
uncultivated organism

effectors

MG144
1279
MG144-10 effector
protein
unknown
uncultivated organism

effectors

MG144
1280
MG144-11 effector
protein
unknown
uncultivated organism

effectors

MG144
1281
MG144-12 effector
protein
unknown
uncultivated organism

effectors

MG144
1282
MG144-13 effector
protein
unknown
uncultivated organism

effectors

MG144
1283
MG144-14 effector
protein
unknown
uncultivated organism

effectors

MG144
1284
MG144-15 effector
protein
unknown
uncultivated organism

effectors

MG144
1285
MG144-16 effector
protein
unknown
uncultivated organism

effectors

MG144
1286
MG144-17 effector
protein
unknown
uncultivated organism

effectors

MG144
1287
MG144-18 effector
protein
unknown
uncultivated organism

effectors

MG144
1288
MG144-19 effector
protein
unknown
uncultivated organism

effectors

MG33
1289
MG33-36 effector
protein
unknown
uncultivated organism

effectors

MG33
1290
MG33-37 effector
protein
unknown
uncultivated organism

effectors

MG33
1291
MG33-38 effector
protein
unknown
uncultivated organism

effectors

MG33
1292
MG33-39 effector
protein
unknown
uncultivated organism

effectors

MG33
1293
MG33-40 effector
protein
unknown
uncultivated organism

effectors

MG33
1294
MG33-41 effector
protein
unknown
uncultivated organism

effectors

MG33
1295
MG33-42 effector
protein
unknown
uncultivated organism

effectors

MG33
1296
MG33-43 effector
protein
unknown
uncultivated organism

effectors

MG33
1297
MG33-44 effector
protein
unknown
uncultivated organism

effectors

MG33
1298
MG33-45 effector
protein
unknown
uncultivated organism

effectors

MG33
1299
MG33-46 effector
protein
unknown
uncultivated organism

effectors

MG33
1300
MG33-47 effector
protein
unknown
uncultivated organism

effectors

MG33
1301
MG33-48 effector
protein
unknown
uncultivated organism

effectors

MG33
1302
MG33-49 effector
protein
unknown
uncultivated organism

effectors

MG33
1303
MG33-50 effector
protein
unknown
uncultivated organism

effectors

MG33
1304
MG33-51 effector
protein
unknown
uncultivated organism

effectors

MG33
1305
MG33-52 effector
protein
unknown
uncultivated organism

effectors

MG33
1306
MG33-53 effector
protein
unknown
uncultivated organism

effectors

MG33
1307
MG33-54 effector
protein
unknown
uncultivated organism

effectors

MG33
1308
MG33-55 effector
protein
unknown
uncultivated organism

effectors

MG33
1309
MG33-56 effector
protein
unknown
uncultivated organism

effectors

MG33
1310
MG33-57 effector
protein
unknown
uncultivated organism

effectors

MG33
1311
MG33-58 effector
protein
unknown
uncultivated organism

effectors

MG33
1312
MG33-59 effector
protein
unknown
uncultivated organism

effectors

MG34
1313
MG34-26 effector
protein
unknown
uncultivated organism

effectors

MG34
1314
MG34-27 effector
protein
unknown
uncultivated organism

effectors

MG34
1315
MG34-28 effector
protein
unknown
uncultivated organism

effectors

MG34
1316
MG34-29 effector
protein
unknown
uncultivated organism

effectors

MG34
1317
MG34-30 effector
protein
unknown
uncultivated organism

effectors

MG34
1318
MG34-31 effector
protein
unknown
uncultivated organism

effectors

MG34
1319
MG34-32 effector
protein
unknown
uncultivated organism

effectors

MG34
1320
MG34-33 effector
protein
unknown
uncultivated organism

effectors

MG34
1321
MG34-34 effector
protein
unknown
uncultivated organism

effectors

While preferred embodiments of the present invention have been shown and described herein, it will be obvious to those skilled in the art that such embodiments are provided by way of example only. It is not intended that the invention be limited by the specific examples provided within the specification. While the invention has been described with reference to the aforementioned specification, the descriptions and illustrations of the embodiments herein are not meant to be construed in a limiting sense. Numerous variations, changes, and substitutions will now occur to those skilled in the art without departing from the invention. Furthermore, it shall be understood that all aspects of the invention are not limited to the specific depictions, configurations or relative proportions set forth herein which depend upon a variety of conditions and variables. It should be understood that various alternatives to the embodiments of the invention described herein may be employed in practicing the invention. It is therefore contemplated that the invention shall also cover any such alternatives, modifications, variations or equivalents. It is intended that the following claims define the scope of the invention and that methods and structures within the scope of these claims and their equivalents be covered thereby.

Number	Date	Country
63282999	Nov 2021	US
63289981	Dec 2021	US
63356908	Jun 2022	US

	Number	Date	Country
Parent	PCT/US2022/080437	Nov 2022	WO
Child	18669712		US

ENDONUCLEASE SYSTEMS

Information

Publication Number

Date Filed

Date Published

Inventors

Original Assignees

CPC

International Classifications

Abstract

Description

Claims

CROSS-REFERENCE

Provisional Applications (3)

Continuations (1)