The present invention is related to methods and systems for genome editing and diagnosis. Specifically, the invention relates to use of Peptide Nucleic Acids (PNAs) to direct the Cas proteins to their DNA or RNA targets.
This disclosure relates to endonuclease acid complexes, preferably Cas acid complexes and related uses thereto.
RNA-mediated adaptive immune systems in bacteria and archaea rely on Clustered Regularly Interspaced Short Palindromic Repeat (CRISPR) genomic loci and CRISPR-associated (Cas) proteins that function together to provide protection from invading viruses and plasmids. In Type II CRISPR-Cas systems, Cas9 functions as an RNA-guided endonuclease that uses a dual-guide RNA consisting of crRNA and trans-activating crRNA (tracrRNA) for target recognition and cleavage by a mechanism involving two nuclease active sites that together generate double-stranded DNA breaks (DSBs).
CRISPR utilizes an enzyme called Cas9 that uses an RNA molecule as a guide to navigate towards its targeted DNA. It then edits or modifies the DNA which can deactivate genes or insert the desired sequence to achieve a behavior. Its most promising application is genetically modifying cells to overcome genetic defects, and their potential to cure diseases like cancer.
The CRISPR/Cas9, developed in 2012 from S. pyogenes bacterial adaptive immune system, was the first genome editing (GE) tool based on CRISPR systems and also the first one that use RNA to target the nuclease to the intended site. Jinek et al (Science 337, 816-821) showed that the natural CRISPR/Cas9 can be redesigned to target any DNA sequence with the only requirement of having a PAM sequence consisting of an NGG. Although the original system uses two RNAs molecule, a crRNA sequence that is specific to the DNA/RNA target, and a tracrRNA sequence that interacts with the effector Cas9 protein, the authors showed that this system also worked using an engineered single guide RNA (sgRNA). The crRNA:tracrRNA:Cas9 or sgRNA:Cas9 complexes cause site-specific double-stranded DNA cleavage on the target sequence. This DNA damage is repair by cellular DNA repair mechanisms, principally by the non-homologous end joining (NHEJ) or by the homology-directed repair (HDR) pathways.
The first applications of the CRISPR systems used the ability of redirect Cas9 to cut into specific sites in the genome of the cells and the NHEJ or the HDR repair mechanisms as tools to introduce the desired modifications (genome editing). In the NHEJ pathway, the targeted sequences are processed by the cellular machinery generating small insertions and deletions (indels). This strategy is used to generate gene-knockout cells and organisms (transgenic animals and plants). NHEJ have also been used to recover expression of genes with frameshift mutations. When a donor DNA is delivered to the cell, together with the CRISPR system, the new DNA molecules are incorporated into the target sequence through homologous recombination, enabling precise modifications. Due to the efficacy, NHEJ-mediated GE was the first to reach the clinic. NHEJ-based GE strategies have already been used for the treatment of sickle cell disease (SCD), B-thalassemia, AIDS, and acute lymphoblastic leukemia.
The specificity of the CRISPR/Cas9 system depends on RNA-DNA recognition and it is a 20 bp crRNA (or the equivalent domain in the sgRNA), the molecule that determines the exact sequence in which the CAS9 endonuclease must bind and cut. The binding of Cas9 protein to PAM-like sequences followed by binding of the gRNA to sequences with homology to the target site generate cuts outside of the target site (off-targets). This is an important problem that is been tackle by different angles in the GE field. To start with, finding real off-targets is very challenging with no standard protocols to measure them. In fact, several studies point to higher off-targets levels to that found by standards techniques, due to the properties of the sgRNA. Reducing off-target activity of GE tools is crucial for clinical application.
Since the generation of the CRISPR/Cas9, a wide variety of new CRISPR systems have been developed based on CRISPR/Cas9 variations and also based in CRISPR systems from other bacteria. Although the composition varies between different systems, all have two modules: 1) the targeting module, based on 1 or 2 RNAs that bind the target sequence and link this sequence with the Cas protein. 2) the effector module, the Cas protein with endonuclease activity. In general, CRISPR-Cas systems fall into two classes: Class 1 systems, divided into types I, III, and IV, rely on a complex of multiple proteins to degrade foreign nucleic acids; and class 2 systems, divided into types II, V, and VI, utilize a single effector Cas protein, such as the well-studied Cas9 (a type II CRISPR system).
Most GE systems have been developed using Class 2 systems (HajizadehDastjerdi, 2019). The signature protein of Type I systems is Cas3, a single-stranded DNA nuclease and ATP-dependent helicase. Type III systems are characterized by Cas10, which assembles into a Cascade-like interference complex. Type IV systems have Csf1, a protein proposed to form part of a Cascade-like complex, though these systems consist of isolated cas genes without an associated CRISPR array. Type V systems also contain a Cas9-like single nuclease, either Cpf1(Cas12a), C2c1, or C2c3. Type VI systems have Cas13 (formerly C2c2), a large protein with two HEPN (higher eukaryotes and prokaryotes nucleotide-binding) RNase domains (Shmakov et al., 2015).
The types based on multi-subunit effector complexes (class 1 systems) have also been used, although their architecture makes them less manageable, for gene editing. However, its large size and stable binding make them more appropriate for other applications, such as transcription silencing (Rath et al, 2015).
There are certain problems with CRISPR such as unwanted off-target mutations. It works by cutting the double-stranded DNA at precise locations in the genome. When the cell's natural repair process takes over, it can cause damage. Further, it could create unwanted off-target mutations where the modified DNA is inserted at the cut site.
US20190032036A1 describes a modification of the CRISPR enzyme to solve the off-target effect. Because DNA is negatively charged, it binds itself to a groove in Cas9 protein which is positively charged. Inventors replaced some of the positively charged amino acids with neutral ones to decrease the binding of “off-target” sequences.
Zhang's team found that mutations in three amino acids dramatically reduced “off-target” cuts. They have created a newly engineered enzyme—“enhanced” S. pyogenes Cas9, or eSpCas9, which will be useful for specific genome editing applications.
Other solution is the implementation of second guide RNA (US20170247671A1). During a CRISPR based edit, a strand of molecules called a guide RNA leads the DNA-slicing protein Cas9 to the section of DNA targeted for editing. Once the guide RNA binds to the DNA, Cas9 makes the cut so that new DNA can be inserted or deleted, and an additional second guide RNA can be used having a blocking guide sequence that is complementary to an off-target nucleic acid sequence. There could be quite a bit of randomness in what happens during these CRISPR edits, and that randomness can potentially create unexpected outcomes. To minimize them, in U.S. Pat. No. 10,354,746B they developed an algorithm that takes in data and identifies cleavage locations of Cas9 nuclease and selects the nuclease having fewest off-target cleavage locations.
To validate off-target sites, an in vitro Cas9-digested whole-genome sequencing technique, Digenome-seq, was developed in US20190153530A1. This in vitro method yields sequences that can be computationally identified to profile genome-wide Cas9 off-target effects in human cells. Digenome-seq is a robust, sensitive, unbiased, and cost-effective method for profiling genome-wide off-target effects of programmable nucleases including Cas9.
In Anzalone et al (Nature 576, 149-157, 2019) they developed a technique (CRISPR prime) that has the potential to fix more than 90% of known genetic diseases including Tay-Sachs disease. This versatile and precise genome editing method works by directly writing new genetic information into a specified DNA site using a catalytically impaired Cas9 endonuclease fused to an engineered reverse transcriptase, programmed with a prime editing guide RNA (pegRNA) that both specify the target site and encodes the desired edit. CRISPR prime also offers the versatile function of multi-letter base-editing [Can tackle four DNA letters mutation genetic disorders like Tay-Sachs] with minimized DNA damage, less off-target effect, and efficient DNA healing. A guide RNA called pegRNA guides the Cas9 enzyme to snip out only a single strand of DNA and prevents the double-strand breaks which can induce unintended disruptions. After that, the reverse transcriptase enzyme directly copies the edited genetic information contained in the pegRNA to the targeted genomic site. This helps to generate cells, which will help patients to recover and heal as well as help develop new vaccines against deadly diseases.
CRISPR/Cas systems are powerful technologies that are changing the way scientists tackle unsolved problems in basic biology, therapy and diagnosis. In its present forms, the different CRISPR/Cas systems require RNA molecules (crRNAs or sgRNAs) to direct the different Cas proteins to their DNA or RNA targets. In spite of their potency and specificity, the RNA molecules are unstable and can allow several mismatches when binding to their target, and this can lead to lack of reproducibility, mutations in undesired genes and false positives.
This invention combines the versatility of CRISPR-associated enzymes (Cas) with the robustness, stability and specificity of peptide nucleic acids (PNAs) to generate the “CRISPNA” technology, with improved characteristics over CRISPR systems.
Peptide Nucleic Acids (PNAs) are artificially synthetic oligonucleotides that display higher affinity to complementary DNA and RNA than do normal oligonucleotides. Therefore, PNA-RNA and PNA-DNA bindings are more stable and specific than RNA-DNA. In addition, their uncharged backbone makes PNAs extremely stable in biological fluids, since they are resistant to proteases and nucleases.
CRISPNA is an alternative to CRISPR systems and can be used to improve the efficacy and specificity of all applications in which CRISPR has been used. Therefore, CRISPNA can be used to manipulate DNA and RNA, as well as a tool to detect and/or image specific DNA and RNA sequences. Importantly, it can be used in living cells as well as in different fluids.
The present invention uses PNAs, instead of crRNAs or sgRNAs, to direct the Cas proteins to their DNA or RNA targets.
Thus, a first aspect of the invention relates to the use of PNAs to direct the Cas proteins to their DNA or RNA targets.
“Peptide Nucleic Acids” or “PNAs” are synthetic mimics of oligonucleotides in which the sugar-phosphate backbone is replaced by a peptide to which the nucleobases are linked.
A second aspect of the invention relates to a CRISPNA complex or system (for recognition and cleavage of a target nucleotide, preferably a target DNA, sequence) comprising:
Preferably, said complex or system forms or is comprised in a composition or in a kit of parts, hereinafter composition or kit of parts of the invention.
In a preferred embodiment, the guide system is a single guide system comprising an RNA-PNA chimera (crRPNA) in which the RNA domain will bind the Cas polypeptide and the PNA domain will bind the target oligonucleotide sequence.
In the present specification, “Cas polypeptide” refers to an endonuclease, preferably a CRISPR endonuclease. Cas polypeptides (part of the CRISPR or CRISPNA system) are endonucleases, meaning that they cut DNA somewhere in the middle of a strand, rather than taking bases off the end. Cas enzymes are guided to its cut a site by an single guide RNA (sgRNA) which uniquely targets the DNA sequence to which it is complementary thereto. This means that instead of engineering a whole new protein, if we want to target a specific site we can simply change the sgRNA sequence. The Cas polypeptide in order to start the cleaving reaction needs a double interaction with the DNA and the tracrRNA. Most Cas proteins, also, in order for the reaction to take place—need a consensus sequence named PAM. Each PAM is specific for each Cas polypeptide.
The “tracrRNA” or “trans-activating crRNA” is made of up of a longer stretch of bases that are constant and provide the “stem loop” structure bound by the CRISPR or CRISPNA nuclease (i.e. Cas9).
When tracrRNA hybridizes with the crPNA they form a guide RNA-PNA which “programmably” targets CRISPR or CRISPNA nucleases to DNA or RNA sequences depending on the complementarity of the crPNA and the presence of other DNA or RNA features (PAM sequences recognized by the different Cas nucleases).
The “single guide RNA” or “sgRNA” is a single RNA molecule that contains both the custom-designed short crRNA sequence fused to the scaffold tracrRNA sequence. sgRNA can be synthetically generated or made in vitro or in vivo from a DNA template.
In the context of the present invention, the “guide system” of the invention comprising the tracrRNA sequence and the crPNA, is equivalent to the sgRNA. As said previously, the guide system may be also a RNA-PNA chimera, named crRPNA, that is equivalent to the sgRNA.
The “kit of parts” or “system” of the invention refers to a combination of a set of components suitable for targeting specific DNA or RNA sequences which may or may not be administered together. The components of the kit (the CRISPR enzyme—Cas polynucleotide—and the guide system) can be provided in separate vials (in the form of “kit of parts”) or in a single vial.
Parts of the kit of the invention can be jointly or separately sold/administered.
It should be emphasized that the term “kit of parts” in this specification, means that the components of the system of the invention (CRISPR or CRISPNA enzyme/Cas polynucleotide, tracRNA, crPNA—or the RNA-PNA chimera—) do not need to be present in the same composition, in order to be available for their combined, separate or sequential application. Thus, the expression “kit of parts” implies that a true combination does not necessarily result, in view of the physical separation of the components.
In some embodiments, the CRISPNA complex or system comprises one or more nuclear localization sequences of sufficient strength to drive accumulation of said CRISPNA complex into the nucleus of eukaryotic cells. Then, in a preferred embodiment, the CRISPNA complex or system, the composition, or the kit of parts of the invention comprises nuclear localization sequences.
In a preferred embodiment, the guide system from the CRISPNA complex or system, the composition, or the kit of parts of the invention comprises or consists of a structure of Formula (I):
Ac—NH—Y-link-Z—CONH2 Formula (I)
wherein
In another preferred embodiment, the guide system from the CRISPNA complex or system, the composition, or the kit of parts of the invention is a RNA-PNA chimera (crRPNA), comprising or consisting of a structure of Formula (II):
Ac—NH—Y-link-RNA Formula (II)
wherein
In another preferred embodiment, the Cas polypeptide or the polynucleotide encoding the same is selected from the group consisting of: Cas1, Cas2, Cas3, Cas4, Cas5, Cas6, Cas7, Cas8, Cas9, Cas10, Cas11, Cas12, Cas13, Csy1, Csy2, Csy3, Cse1, Cse2, Csa5, Csn2, Csm2, Csm3, Csm4, Csm5 and/or Csm6
In another preferred embodiment, the Cas polypeptide belongs to the type II, type V or type VI CRISPR or CRISPNA systems.
Another embodiment refers to the CRISPNA complex or system, the composition, or the kit of parts of the invention, wherein the Cas polypeptide is Cas9 and the guide system comprises:
More preferably the guide system comprises:
and
In another preferred embodiment, the guide PNA (crPNA) of the CRISPNA complex or system, the composition, or the kit of parts of the invention has the structure of a RNA-PNA chimera (crRPNA), having the structure previously defined.
Double-stranded DNA (dsDNA) recognition and cleavage by Cas9 strictly require the presence of a “PAM sequence” or “protospacer-adjacent-motif” (for Cas9 recognition, nGG, n=any nucleotide)in the non-complementary, DNA strand (ntDNA) and the complementarity of the target DNA strand (tDNA) to the 10-12 nucleotide (nt) PAM-proximal “seed” region in the guide RNA. Once the guide RNA binds to the target sequence, the Cas9 enzyme recognizes the site and makes a double strand break in the DNA sequence 3-4 nucleotides upstream the PAM sequence. In nature, Cas nucleases derived from different bacterial species recognize different PAMs. In the case of the spCas9 (Streptococcus pyogenes) the PAM sequence is NGG. So the guide system (formed by the tracrRNA and the crPNA—instead the sgRNA—) targets the Cas9 where you want it to cleave and the interaction with the PAM is needed for the conformational rearrangements of the Cas9 to start cleaving the DNA.
Another preferred embodiment refers to the CRISPNA complex or system, the composition, or the kit of parts of the invention, wherein the Cas polypeptide is selected from the list consisting of Cas 5, Cas 7, Cas 12 and/or Cas 13; and the guide system comprises:
Another preferred embodiment refers to the CRISPNA complex or system, the composition, or the kit of parts of the invention, wherein
and wherein Z′ is a polynucleotide having between 5 and 70 nucleotides that hybridizes the Z sequence of the PNA sequence binding the tracrRNA of formula I.
Other aspect of the present invention refers to a non-viral vector, hereinafter non-viral vector of the invention, comprising the system, the composition or the kit of parts of the invention.
The Cas polypeptide, the tracrRNA and the crPNA can form a ribonucleopeptide complex than can act as non-viral vectors (
In one embodiment of the present aspect the non-viral vector of the invention is transferred into a target cell using a non-viral system. More preferably the non-viral system is selected from the list consisting on: an electroporator, a liposome, a polycation, a nanoparticle, or combinations thereof.
Another aspect of the invention refers to the use of the CRISPNA complex or system, the composition, the kit of parts or the non-viral vectors of the invention for genome editing. The present invention can be used, without limitation, to generate gene-modified cells and organisms (transgenic animals and plants). Also, can be used to modulate gene expression of cells and organisms. For example, for increasing expression of a chromosomal sequence in a cell or embryo.
Preferably, the cell is a human cell, a non-human mammalian cell, a stem cell, a non-mammalian vertebrate cell, an invertebrate cell, a plant cell, or a single cell eukaryotic organism.
Then, another aspect of the invention refers to the CRISPNA complex or system, the composition, the kit of parts or the non-viral vectors of the invention for use in medicine.
Another aspect of the invention refers to the CRISPNA complex or system, the composition, the kit of parts or the non-viral vectors of the invention for the prevention, amelioration or treatment of a disease or disorder.
The CRISPNA-based gene editing can be used to inactivate or correct gene mutations causing diseases, for example dystrophies and/or microsatellite expansion diseases, thereby providing a gene therapy approach for these groups of diseases.
Then, another aspect refers to the CRISPNA complex or system, the composition, the kit of parts or the non-viral vectors of the invention for the treatment of genetic diseases.
The guided nuclease system of the present invention can target any specific region of the microorganism's genome (bacteria, virus . . . ). Thus, the CRISPNA complex or system, the composition, the kit of parts or the non-viral vectors of the invention can be plausibly used for killing a bacterium contacting the bacterium and creating a double-stranded break in the chromosomal DNA of the bacterium. Another strategy could be making a bacterium more susceptible to an antibiotic, cleaving an antibiotic resistance gene encoded by the bacterium. Also, methods of the invention may be used to remove latent virus genetic material from a host organism, without interfering with the integrity of the host's genetic material.
Then, another aspect refers to the CRISPNA complex or system, the composition, the kit of parts or the non-viral vectors of the invention for the treatment of infectious diseases.
The CRISPNA complex or system, the composition, the kit of parts or the non-viral vectors of the invention could be used to therapeutically target oncogene mutations or to repair defective tumor suppressor genes. That is, they can be used to inactivate or correct oncogene mutations causing cancer, thereby providing a gene therapy approach for treating the underlying causes of cancer.
Also, the CRISPNA complex or system, the composition, the kit of parts or the non-viral vectors of the invention can be plausibly used to eliminate immune checkpoint genes from T cells for cancer immunotherapy approaches.
Also, the CRISPNA complex or system, the composition, the kit of parts or the non-viral vectors of the invention could be used to generated universal CAR-T cells by eliminating the TCR.
Then, another aspect of the invention relates to the CRISPNA complex or system, the composition, the kit of parts or the non-viral vectors of the invention for preventing, inhibiting, or treating cancer in a subject. For example, the guide system comprises at least one targeted genomic sequence, such as an oncogenic mutation or tumor suppressor gene.
Another aspect of the invention refers to a method, hereinafter first method of the invention, for generating specific cleavage in a double stranded DNA, in a single stranded DNA or in a single stranded RNA using the CRISPNA complex, the composition, the kit of parts or the non-viral vectors of the invention. More preferably said cleavage is in a cell in vitro or ex vivo. Still more preferably said cleavage is in a cell in vivo and the delivery of the ribonucleo-peptide complex is performed as mentioned previously.
In another preferred embodiment, the aim of such cleavage is to modify the target sequence. In another preferred embodiment, the aim of such cleavage is to repair existing mutations. In another preferred embodiment, the aim of such cleavage is to disrupt the function of a functional protein. In another preferred embodiment, the aim of such cleavage is to restore the function of a mutated protein.
Another aspect of the invention refers to a method. Hereinafter second method of the invention, for specific binding to double stranded DNA, a single stranded DNA or a single stranded RNA, using the CRISPNA complex, the composition, the kit of parts or the non-viral vectors of the invention wherein the Cas polypeptides are mutated for their cleavage activity. More preferably said binding is in a cell in vitro or ex vivo and the delivery of the ribonucleopeptide complex is performed as mentioned previously.
In another preferred embodiment, the aim of such binding is to visualize the target sequence.
In another preferred embodiment, the aim of such binding is to detect the target sequence.
Another aspect of the invention refers to the composition, the kit of parts or the non-viral vectors of the invention for monitoring a disease or disorder.
Some traditional diagnostic methods such as PCR are time consuming assays that require multiple steps and specific equipment. So, an ideal rapid diagnostic test would be sensitive and specific, easy to perform and affordable. CRISPR-based assays require minimal to no equipment and can be run as single reaction tests. They are easy to use and can deliver fast and accurate results. The CRISPNA system could also take these advantages but increasing efficacy and specificity of the systems.
Several groups have taken advantage of the characteristics of class 2 Type V and Type IV CRISPR systems, based mainly on Cas12a and Cas13a nucleases, respectively, developing different platforms for rapid and accurate nucleic acids detection. Firstly, the Professor Doudna and her team demonstrated that combining the processing and interference activities of Cas13a it is possible the detection of cellular transcripts (East-Seletsky, et al. (2016). Nature 538, 270-273).
Later, the RNA-activated ssRNA-degradation activity of Cas13a was functionalized to create the SHERLOCK (Specific High Sensitivity Enzymatic Reporter UnLOCKing) platform. A paper-based assay that uses isothermal amplification and Cas13a for in vitro detection of specific strains of Dengue and Zika virus with attomolar sensitivity, distinguishes pathogenic bacteria, identifies low frequency DNA mutations (e.g. SNP) correlated with cancer and other diseases, or human genotyping7. Combination of orthogonal CRISPR enzymes, which present discrete crRNA and substrate, and other advances, promoted a more advanced SHERLOCK platform, known as SHERLOCKv2, which allows simultaneously detection of Zika and Dengue virus, and mutations in liquid biopsy samples8. Similarly, exploiting the multiple-turnover nuclease activity of Cas12a Chen et al have developed DETECTR (DNA endonuclease-targeted CRISPR trans reporter), a method that with attomolar sensitivity allows specific nucleic acid detection between two types of human papillomavirus (HPV). This platform has been applied for detection of betacoronavirus severe acute respiratory syndrome (SARS)-CoV-2 (COVID-19) from respiratory swab RNA extracts in a portable, easy to perform, rapid and accurate manner.
CRISPR-Cas9 system has also been used for developing infectious disease diagnostics. In fact, it can be also applied to fight against the antibiotic-resistance bacteria problem, targeting virulence and resistance genes. It has also been used in the field of cancer genomics. For instance, to enrich KRAS mutations so that depleting wild-type copies to increase the downstream sensibility of the assay.
CRISPR/Cas 9 is also a very powerful tool to do targeted sequencing of long DNA fragments without the need of amplifying DNA. This is key to do methylation studies of long DNA regions12
Then, another aspect of the invention refers to the first or the second method of the invention for the diagnosis of a disease or disorder.
The term “subject” or “patient” as used herein includes all members of the animal kingdom including non-human primates and humans.
The above written description of the invention provides a manner and process of making and using it such that any person skilled in this art is enabled to make and use the same, this enablement being provided in particular for the subject matter of the appended claims, which make up a part of the original description.
Where a numerical limit or range is stated herein, the endpoints are included. Also, all values and subranges within a numerical limit or range are specifically included as if explicitly written out.
The above description is presented to enable a person skilled in the art to make and use the invention and is provided in the context of a particular application and its requirements. Various modifications to the preferred embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments and applications without departing from the spirit and scope of the invention. Thus, this invention is not intended to be limited to the embodiments shown but is to be accorded the widest scope consistent with the principles and features disclosed herein.
It is noted herein that this invention is also directed to the following clauses or embodiments
Ac—NH—Y-link-Z—CONH2 Formula (I)
Ac—NH—Y-link-RNA Formula (II)
NH2—Y-link-Z—CONH2 Formula (I)
and wherein Z′ is a polynucleotide having between 5 and 70 nucleotides that hybridizes the Z sequence of the PNA guide as described in clause 3.
Having generally described this invention, a further understanding can be obtained by reference to certain specific examples, which are provided herein for purposes of illustration only, and are not intended to be limiting unless otherwise specified.
The design of the CRISPNA systems are based on the replacement of the crRNA spacer (that redirect the Cas enzymes to their targets) by a more stable and specific PNA molecule. Since different CRISPR have different compositions, the CRISPNA design will differ depending on the origin of the CRISPR system.
Type II CRISPNA requires the design of a PNA (named crPNA) that will replace the crRNA in the original CRISPR/Cas system while still using the tracrRNA (
To adapt type V and type VI CRISPR system to CRISPNA, we have two possibilities:
CRISPNA/Cas is an alternative to the well-known CRISPR/Cas systems and can therefore be applied to every application of this powerful technology. One of the applications that have revolutionized basic and applied research is the possibility to manipulate DNA and RNA of living cells (genome editing). CRISPR technology has been used to develop new therapeutic strategies (Gene Therapy), to engineer stem cells, generate animal models, and to develop transgenic animals and plants that are resistant to diseases or severe conditions or have improved nutritionals values. To do so, actual CRISPR systems rely on the RNA molecules that can allow several mismatches when binding to their target leading to cut outside of the intended target (off-targets). Although for basic research this is not a mayor problem, for gene therapy applications and transgenesis is a serious concern.
PNAs display higher affinity and specificity to complementary DNA and RNA than do normal oligonucleotides and therefore, our CRISPNA system, directing the Cas proteins through PNA-DNA interactions, will be more specific and efficient than actual CRISPR systems.
We will first generate ribonucleoprotein (RNP) complexes harboring Cas9, tracrRNA and crRNA (CRISPR) or crPNA (CRISPNA) targeting the eGFP, the GAA and the TRAC loci and, in all cases, we will perform the following common procedure (
The SEWAS84S-C1 cells (Development of Cellular Models to Study Efficiency and Safety of Gene Edition by Homologous Directed Recombination Using the CRISPR/Cas9 System. Sánchez-Hernández S, Aguilar-González A, Guijarro-Albaladejo B, Maldonado-Pérez N, Ramos-Hernández I, Cortijo-Gutiérrez M, Sánchez Martín R M, Benabdellah K, Martin F. Cells. 2020 Jun. 18;9 (6):1492. doi: 10.3390/cells9061492) were used to evaluate the efficacy of genome editing in the eGFP locus. The crPNA was directed to the eGFP target, in particular to the TTGCTCACCATGGTGGCGAC sequence. To form the complex, we selected the ratio 0.5:1 (crPNA:tracPNA).
To form CRISPNA, the PNA was synthesised by Destina genomics (eGFP(N-C): TTGCTCACCATGGTGGCGAC-O-O-TCGTTTACAGATAG, where O=miniPEGspacer, 100 uM) and the chemically synthesised tracrRNA was obtained from Synthego (Silicon Valley, CA, USA) (200 μM). The crPNA-tracrRNA complex was formed at a ratio 0.5:1 (crPNA:tracrRNA) and at a concentration of 25 μM. The hybridization was performed in a thermal cycler with the following temperature reduction profile: 95° C., 5 min; 85° C., 1 min; 75° C., 1 min; 65° C., 5 min; 55° C., 1 min; 45° C., 1 min; 35° C., 5 min. Next, this crPNA-tracrRNA was mixed in a 1:2.23 ratio in terms of volume with High fidelity Cas9 (IDT, Coralville, IA, USA) and incubated at room temperature 15 min to form RNP. Then, it was delivered to cells by means of nucleofection.
Nucleofection will be performed with an AmaxaNucleofector 4-D and solution SF cell line (Lonza, Basel, Switzerland), applying program FF-120 and following the nucleofection protocol for K-562 cells. The efficiency of genome editing will be determined by TIDE analysis.
Primary human T cells (isolated from Apheresis products from healthy donors and activated for 48 h), will be nucleofected with CRISPR or CRISPNA RNPs designed to cut in the first exon of the constant chain of the TCRα gene (TRAC) using TCAGGGTTCTGGATATCTGT as the target sequence. To form the ribonucleoproteins (RNP) prior to nucleofection, different molar ratios will be tested, as well as several times and temperatures of incubation. T cells will be nucleofected with each RNP using P3 primary cell kit and the 4D-Electroporator (Lonza), following the protocol for stimulated human T cells (program EO-115). The efficiency of edition will be determined as described in
We have generated different cellular model in K562 cells to evaluate the efficacy of genome editing (Sanchez-Hernandez et al under revision). Using this model and a fluorescence-based pattern we will study the efficacy of genome editing (eGFP turn-off) trigger by the CRISPR versus the CRIPNA systems. As before the crRNA and the crPNA will be directed to the same target, in this case, the TTGCTCACCATGGTGGCGAC sequence. To form the ribonucleoproteins (RNP) prior to nucleofection, different molar ratios will be tested, as well as several times and temperatures of incubation. Nucleofection will be performed with an AmaxaNucleofector 4-D and solution SF cell line (Lonza, Basel, Switzerland), applying program FF-120 and following the nucleofection protocol for K-562 cells. The efficiency of genome editing will be determined by eGFP silencing by ICE analysis (ice.synthego.com).
We will next explore the ability of CRISPNA to discriminate single base variations. To do this we will target an SNP present in HER2 that is associated with cardiomyopathy in patient treated with Trastuzumab. CRISPR and CRISPNA will be designed to target different SNP and the cutting efficacies of both systems will be investigated in the different haplotypes as shown before.
As mentioned before, in its present forms, the different CRISPR/Cas systems require RNA molecules (crRNAs or sgRNAs) to direct the different Cas proteins to their DNA or RNA targets. RNA molecules are instable and can allow several mismatches when binding to their target. Moreover, RNA hybridizations are limited to certain salt concentrations and temperatures while PNA molecules are able to hybridize complementary nucleic acid targets in a broader range of conditions.
We will develop different tools for diagnostic based on the CRISPNA system:
crPNA is designed to be fully complementary to the antisense strand of gDNA containing mutation G12D. crPNA is composed by a 20mers strand complementary to gDNA plus a 12mers strand which is used to hybridize tracrRNA. Cas13 is activated when mutation G12D is present, hence activating its unspecific nuclease activity. gDNA, following an amplification step is transformed to RNA using a T7 transcription step. Then, Cas13 plus crPNA and tracrRNA (Table 1) are added. In one example, a FRET reporter (reporter 1) is used. A fluorescent plate-reader is used to detect the presence of G12D mutation. In another example, a lateral flow system is used so that when a reporter is cleaved (reporter 2) it could be identified in a lateral flow system. The sequences are shown in Table 1:
GTTGGAGCTG
A
GG
CGTAGGCAAGA . . .
GGCGTAGG
GGCGTAGGCAAGA . . .
The use of crPNA to cleave wild-type variants before PCR amplification to provide an accurate and efficient way to enrich mutant variants of gDNA obtained from heterogeneous tumor tissues (solid and cell-free). gDNA is put in contact with preformed Cas9 plus crPNA and tracrRNA complex. The sequences are shown in Table 2:
GTTGGAGCTG
G
TGGCG
GG
CGT
AGG
CAAGA . . .
TAGG
SARS-Cov2 RNA is treated with reverse-transcriptase-recombinase polymerase amplification (RT-RPA) to amplify the S gene fragment. Then, an in vitro T7 transcription step take place before putting in contact with Cas13 complex formed by crPNA and tracrRNA (Table 3). In one example, a FRET reporter (reporter 1) is used. A fluorescent plate-reader is used to detect the SARS-Cov-2. In another example, a lateral flow system is used so that when a reporter is cleaved (reporter 2) the presence of SARS-Cov2 could be identified.
Number | Date | Country | Kind |
---|---|---|---|
P202031322 | Dec 2020 | ES | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2021/087887 | 12/30/2021 | WO |