A paper copy of the Sequence Listing and a computer readable form of the Sequence Listing containing the file named “15060-950_sequence listing_ST25.txt”, which is 74,04, bytes in size (as measured in MICROSOFT WINDOWS® EXPLORER), are herein incorporated by reference. This Sequence Listing consists of SEQ ID NOs: 1-28.
Non-ribosomal peptide synthetases (NRPSs) are multi-domain modular biosynthetic assembly lines that polymerize amino acids into a myriad of biologically active and often structurally complex molecules, including the life-saving non-ribosomal peptide (NRP) antibiotics vancomycin, daptomycin, and penicillin. To increase structural diversity, NRPSs draw from a pool of 23 proteinogenic and about 500 non-proteinogenic amino acids. Terminal thioesterase (TE) domains of modular NRPSs employ diverse release strategies for off-loading thioester-tethered polymeric peptides from termination modules via hydrolysis, aminolysis, reduction, or cyclization to provide mature antibiotics as carboxylic acids, esters, amides, aldehydes, macrolactams, and macrolactones, respectively.
Among the different types of macrolactones, strained β-lactone rings are found in diverse classes of natural products including polyketides (PKs), nonribosomal peptides (NRPs), amino acids, terpenoids, and hybrid molecules. Little is known about the biosynthetic origins of β-lactones despite wide therapeutic value of naturally occurring peptide β-lactones as inhibitors of enzymes in the serine hydrolase superfamily. One naturally occurring peptide β-lactone is tetrahydrolipstatin, a hybrid PK-NRP lipase inhibitor used as a treatment of obesity. Another naturally occurring peptide β-lactone, salinosporamide A (also known as marizomib and NPI-0052) is a hybrid PK-NRP proteasome inhibitor under clinical investigation as a treatment of multiple myeloma and other advanced malignancies. Other naturally-occurring β-lactones are reported to show promise as antimicrobial, anticancer, antiviral, and anti-obesity agents. The genetic and biochemical basis for β-lactone ring formation is an ongoing challenge in natural product biosynthesis, and to date no enzymes are known to catalyze the formation of a strained β-lactone ring.
There is precedent for enzymatic formation of strained 4-membered rings in the closely related β-lactam family of antibiotics. Three chemically distinct biosynthetic pathways leading to β-lactams have been reported. For example, penicillin and cephalosporin bicyclic β-lactam scaffolds may be formed via oxidative cyclization of a NRP tripeptide precursor by isopenicillin N synthase. In another example, the β-lactam rings in clavulanic acid and carbapenems may arise via ATP-dependent cyclization of β-amino acid precursors catalyzed by the β-lactam synthetase enzyme family. In an additional example, the nocardicin family of monocyclic β-lactam antibiotics is derived from NRPS assembly lines with five catalytic modules that each covalently tethers the evolving substrate as a thioester on a peptidyl carrier protein, also known as thiolation (T) domain. In another additional example, a condensation domain of module 5 was identified with a rare HHHXXDG motif that is important for dehydration of a T4-thioester tethered serine to the corresponding dehydroalanine. The newly formed T4-dehydroalanine thioester serves as electrophile for a Michael addition/nucleophilic acyl substitution reaction cascade with the nucleophilic α-amino group of a downstream T5-tyrosine thioester to produce the nocardicin β-lactam warhead. Potentially, modifications of these biosynthetic strategies may be employed to assemble β-lactone rings.
The biosynthetic gene clusters for the β-lactones lipstatin (
Lactacystin is a secondary metabolite produced by Streptomyces sp. OM-6519 and is structurally related to salinosporamides. Lactacystin is thought to be cleaved from the biosynthetic assembly line via transthioesterification with N-acetylcystein. The resulting β-hydroxy-N-acteylcysteinylthioester has been shown to be in equilibrium with the cis-fused bicyclic β-lactone believed to be an active proteasome inhibitor. It was previously demonstrated that the trans-monocyclic β-lactone ring found in ebelactone and lactacystin may form non-enzymatically from cyclization of the β-hydroxy-N-acetylcysteamine thioester in aqueous buffer at pH 7. The facile non-enzymatic formation of ebelactone and lactacystin β-lactones from precursor β-hydroxy-thioesters under these conditions may reduce the likelihood of identifying a biosynthetic enzyme catalysis of β-lactone ring formation. However, under certain conditions, enzyme catalysis of β-lactone ring formation may still prove advantageous, despite the relative stability of the β-lactones in aqueous solutions.
Obafluorin in its closed-ring form (RC-Obi) is a cis-monocyclic β-lactone antibiotic (see
RC-Obi was reported to have broad-spectrum antibacterial activity and demonstrated efficacy in a Streptococcus pneumonia murine septicemia model. Although the biological target of RC-Obi is unknown, bacterial transpeptidases are thought to be potential targets due to the structural similarity of RC-Obi to monocyclic β-lactam antibiotics and the documented susceptibility of RC-Obi to hydrolysis by β-lactamases.
In one aspect, a method of producing a peptide beta-lactone is disclosed. The method includes contacting a beta-hydroxy-alpha-amino acid, an aryl carrier protein (ObiD), and ATP with a non-ribosomal protein synthetase. The beta-hydroxy-alpha-amino acid is selected from the group consisting of beta-OH-p-NO2-homoPhe and beta-OH-homoPhe. The aryl carrier protein is selected from the group consisting of ObiD, a homolog of ObiD, recombinant ObiD, and any variation thereof comprising the amino acid sequence of SEQ ID NO:1 or fragment thereof. The non-ribosomal protein synthetase is selected from the group consisting of ObiF, a homolog of ObiF, recombinant ObiF, and any variation thereof comprising the amino acid sequence of SEQ ID NO:2 or fragment thereof. The benzoic acid derivative is 2,3-dihydroxoybenzoic acid.
In another aspect, a method of producing a peptide beta-lactone is disclosed. The method includes forming a reaction mixture that includes a beta-hydroxy-alpha-amino acid, a benzoic acid derivative, ATP, an aryl carrier protein, and a non-ribosomal protein synthetase. The beta-hydroxy-alpha-amino acid is selected from the group consisting of beta-OH-p-NO2-homoPhe and beta-OH-homoPhe. The benzoic acid derivative consists of 2,3-dihydroxoybenzoic acid. The aryl carrier protein is selected from the group consisting of ObiD, a homolog of ObiD, recombinant ObiD, and any variation thereof comprising the amino acid sequence of SEQ ID NO:1 or fragment thereof. The non-ribosomal protein synthetase is selected from the group consisting of ObiF, a homolog of ObiF, recombinant ObiF, and any variation thereof comprising the amino acid sequence of SEQ ID NO:2 or fragment thereof. The non-ribosomal protein synthetase further include a condensation domain (C), a first adenylation domain (A1), a peptidyl carrier domain (PCP), a thioesterase domain (TE), and a second adenylation domain (A2). The method may further include contacting the beta-hydroxy-alpha-amino acid with the non-ribosomal protein synthetase at the peptidyl carrier domain (PCP) with ATP activation by the first adenylation domain (A1) to form a PCP-beta-hydroxy-alpha-amino acid thioester that includes an alpha-amino moiety. The method may further include ATP activating the benzoic acid derivative at the second adenylation domain (A2) and contacting the ATP-activated benzoic acid derivative with the aryl carrier protein to form a benzoic acid derivative-aryl carrier protein thioester that includes a carbonyl moiety. The method also includes contacting the benzoic acid derivative-aryl carrier protein thioester with the condensation domain (C) to catalyze an amide bond between the alpha-amino moiety and the carbonyl moiety to form a PCP-peptide beta-lactone precursor thioester. The method additionally includes contacting the PCP-peptide beta-lactone precursor thioester with the thioesterase domain (TE) to form a transthioesterified peptide beta-lactone precursor. The method also additionally includes releasing the transthioesterified peptide beta-lactone precursor as a peptide beta-lactone from the non-ribosomal protein synthetase.
In an additional aspect, a continuous flow reactor is disclosed that includes an elongate conduit with at least one region. The at least one region includes a first region that includes a non-ribosomal protein synthetase immobilized to a substrate. The non-ribosomal protein synthetase is configured to contact a flow of a reaction mixture that includes a beta-hydroxy-alpha-amino acid and an aryl carrier protein. The non-ribosomal protein synthetase is further configured to release a peptide beta-lactone into the flow of the reaction mixture. The non-ribosomal protein synthetase is selected from the group consisting of ObiF, a homolog of ObiF, recombinant ObiF, and any variation thereof comprising the amino acid sequence of SEQ ID NO:2 or fragment thereof. The beta-hydroxy-alpha-amino acid is selected from the group consisting of beta-OH-p-NO2-homoPhe and beta-OH-homoPhe. The aryl carrier protein is selected from the group consisting of ObiD, a homolog of ObiD, recombinant ObiD, and any variation thereof comprising the amino acid sequence of SEQ ID NO: 1 or fragment thereof.
The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.
The figures described herein below illustrate various aspects of the disclosure.
The present disclosure is directed to methods of producing peptide beta-lactones and peptide beta-hydroxy acids that include contacting a beta-hydroxy-alpha-amino acid, an aryl carrier protein (ObiD), and ATP with a non-ribosomal protein synthetase. A continuous flow reactor is also disclosed that includes an elongate conduit with at least one region that includes a first region with a non-ribosomal protein synthetase immobilized to a substrate. The non-ribosomal protein synthetase of the continuous flow reactor is configured to contact a flow of a reaction mixture that includes a beta-hydroxy-alpha-amino acid and an aryl carrier protein. The non-ribosomal protein synthetase is further configured to release a peptide beta-lactone into the flow of the reaction mixture.
Definitions of various abbreviations used herein are provided as follows: A, adenylation; ACP, acyl carrier protein; 4-ADC, 4-aminodeoxychorismate synthase; AHL, acylhomoserine lactone; C, condensation; CDS, coding sequence; cpm, counts per minute; DAHP, 3-Deoxy-D-arabinoheptulosonate 7-phosphate; 2,3-DHB, 2,3-dihydroxybenzoate; DTT, dithiothreitol; E. coli, Escherichia coli; gDNA, genomic DNA; β-OH-p-NO2-homoPhe, β-hydroxy-para-nitro-homoPhenylalanine; LB, Luria broth; NRPS, non-ribosomal peptide synthetase; NRP, non-ribosomal peptide; RC-Obi, ring-closed obafluorin; ACP, acyl carrier protein; PAA, phenylacetaldehyde; PAPPA, para-aminophenylpyruvic acid; PCP, peptidyl carrier protein; PHPPA, para-hydroxyphenylpyruvic acid; PNPPA, para-nitrophenylpyruvic acid; PPA, phenylpyruvic acid; PPant, phosphopantetheinyl; PPTase, phosphopantetheinyl transferase; P. fluorescens, Pseudomonas fluorescens; PK, polyketide; PKS, polyketide synthase; PLP, pyridoxal 5′-phosphate; RO-Obi, ring-opened obafluorin; T, thiolation; TE, thioesterase; TFA, trifluoroacetic acid; and TPP, thiamine pyrophosphate.
As illustrated in
Aryl amine oxidase (ObiL) converts PAPPA to PNPPA and ThDP-dependent decarboxylase ObiG converts PNPPA to PNPAA. Threonine aldolase (ObiH) establishes equilibrium between PNPAA, L-Thr, acetaldehyde, and β-OH-p-NO2-homoPhe that is driven towards products by the ATP-consuming NRPS ObiF (see reaction II of
As illustrated in
Three enzymes, Fe(II) oxidase ObiL, decarboxylase ObiG, and aldolase ObiH, convert PAPPA to 1-OH-p-NO2-homoPhe (
ObiL is a non-heme diiron oxygenase that catalyzes the six-electron oxidation of the aryl amine PAPPA to the aryl nitro p-NO2-phenylpyruvic acid (PNPPA), as illustrated in
aGenBank KX134693.
bGenBank EJZ60582.1.
cPBD 5HYH_A.
ObiG is a ThDP-dependent phenylpyruvate decarboxylase that catalyzes the conversion of PNPPA to PNPAA (
The stereochemistry of the ObiH aldol product matches that of the preferred precursor L-Thr and the final biosynthetic product RC-Obi. Double enzyme reactions with decarboxylase ObiG and aldolase ObiH monitored by LCMS established that L-Thr is the preferred amino acid substrate and PNPPA is the preferred phenyl pyruvate substrate. p-Amino-phenylpyruvic acid (PAPPA) was not accepted as a substrate by ObiG/ObiH suggesting that ObiL must oxidize PAPPA prior to ObiGH catalysis. The timing and action of ObiL as an aryl amine oxidase was confirmed using a triple enzyme reaction of ObiGHL with L-Thr and PAPPA substrates which produced β-OH-p-NO2-homoPhe.
The reactive aldehyde resulting from the enzymatic conversion of PNPPA by ObiG is immediately captured by threonine aldolase ObiH.
Double enzyme reactions with decarboxylase ObiG and aldolase ObiH monitored by LCMS established that L-Thr is the preferred amino acid substrate (
Referring to
Amide coupling and β-lactone cyclization occur on the NRPS ObiF/ObiD to complete RC-Obi biosynthesis, as illustrated in
ObiD is a separate aryl acyl carrier protein (TAr), as illustrated in
Recombinant NRPS ObiF and acyl carrier protein ObiD convert β-OH-p-NO2-homoPhe and 2,3-DHB into the β-lactone Obi (
It was discovered that the ObiF NRPS was the first β-lactone producing assembly line, PKS or NRPS, to include a TE domain in the termination module. Primary sequence analysis of the ObiF TE domain revealed that the expected catalytic serine of the conserved GXSXG motif is replaced by a cysteine at residue 1141 (see
A GXCXG motif in a type I TE-domain was also reported previously in an NRPS from Acinetobacter baumannii (see
A homology model of the ObiF TE domain is illustrated in
The ObiF, AB3403, and EntF TE-domains have low sequence similarity (
A C1141S mutation converted ObiF from a “β-lactone synthetase” to a hydrolase producing RO-Obi exclusively in the β-hydroxy acid form (see
Recombinant ObiF containing a GHCAG motif (
The four different NRPSs illustrated in
The ObiF A domains are highly selective for β-OH-p-NO2-homoPhe and 2,3-DHB. Analysis of ObiF with NRPSPredictor2 software predicted that the embedded A-domain would adenylate L-Thr and that the terminal AAr domain would adenylate 2,3-DHB, as summarized in Table 2 below. Table 2 provides ObiF A domain selectivity predictions using NRPSPredictor2, Stachelhaus code, Minowa, and SeqL algorithms. The specificity-conferring sequence of the embedded ObiF A domain (D/A/W/G/C/G/L/I/N/K) shows similarity to the signature sequences for A domains that activate L-Thr (D/F/W/N/I/G/M/V/H/K) and L-Phe (D/A/W/T/I/A/A/V/C/K), with some key differences that help rationalize selectivity for the sterically larger β-OH-p-NO2-homoPhe substrate. In comparison to L-Phe A domains, Thr at position 4 is changed to a Gly, thereby extending the active site pocket to accommodate the chain extended homoPhe. In comparison to L-Thr A domains, Phe at position 2 is changed to Ala and Asn at position 4 is changed to Gly, which leaves room to accommodate the benzyl group. Both L-Phe and L-Thr A domains have Ile at position 5, which is changed to Cys in ObiF.
Burkholderia
Chitiniphilus
Pseudomonas
aThe full sequences for the P. fluorescens, B. diffusa, and C. shinanonensis obafluorin biosynthetic gene clusters were entered into antiSMASH (antismash.secondarymetabolites.org) for analysis. Adenylation domain selectivity was predicted using NRPSPredictor21,2, Stachelhaus code3, Minowa4, and SEQL-NRPS5. All methods predicted 2,3-DHB as substrate for AAr.
Without being limited to any particular theory, the Cys in ObiF may interact favorably with the electron deficient nitro-phenyl group (
It was discovered that the ObiF TE-domain has a direct role in the formation of the Obi β-lactone ring as the final biosynthetic step releasing the mature cyclized product from the NRPS assembly line (
Without being limited to any particular theory, in the case of β-lactone formation, the weaker C—S bond of the thioester compared to the C—O bond of an oxoester is likely required to make strained ring formation thermodynamically favorable. Further, slowing the rate of deacylation increases the dwell time of the C1141-thioester, which may play a role in making cyclization competitive with hydrolysis. Substrate preorganization has been reported previously to be an important factor in NRPS and PKS TE-mediated macrocylizations, and influence the ring size tolerance of the cyclization.
Because the thermodynamic requirements for β-lactone formation are not met by the oxoester intermediate created by the ObiF-C1141S mutant, only the hydrolysis product RO-Obi accumulates (
The “beta-lactone synthetase” identified in the Obi gene cluster is a type I α/β hydrolase TE domain that is part of an NRPS module (ObiF). TE Domains are a highly diverse family of α/β hydrolases that employ a variety of antibiotic release strategies including hydrolysis and macrocyclization. Without being limited to any particular theory, general features identified by the characterization of the Obi NRPS TE domain may be genetic and biochemical signatures associated with β-lactone biosynthesis. The presence of an active site Cys residue in the GXCXG motif of a type I TE is a feature associated with β-lactone ring formation that ensures a thermodynamically favorable scenario for strained ring formation proceeding through a more reactive thioester as compared to the traditional oxoester intermediate encountered during TE-mediated off-loading of NRPS products in other biosynthetic processes.
Amongst the type I TE domains, GXCXG motifs with an active site Cys instead of Ser are rare. Analysis of the thioesterase protein family (PF00975, European Bioinformatics Institute) revealed that 264 out of 3863 members (6.8%) contained a GXCXG, while the remaining 93.2% contained a GXSXG motif. Analysis of the top 20,000 hits from standard protein BLAST search of the full ObiF sequence against non-redundant protein sequences in the NCBI database revealed that 13,944 sequences possessed a GXSXG motif, 1,240 sequences contained a GXCXG motif, and 194 sequences contained a GHCXG motif. The ObiF TE domains from P. fluorescens, C. shinanonesis, and B. diffusa as reported all contain a GHCAG motif and show >50% total sequence homology (
Homology modeling of the ObiF TE domain with the EntF (19% sequence similarity) and AB3403 (20% sequence similarity) TE-domains (see
Inclusion of the 2,3-DHB-activating AA, domain as part of the ObiF NRPS module (see
Recent published structural and biophysical studies of NRPS modules with C-A-T-TE domains have provided insight into the motions and dynamics of individual domains during coordinated catalysis by the enzyme assembly lines. The TE domain is predicted to be highly dynamic and distal from the T domain until invoked for final release of the antibiotic. In the case of ObiF, this would leave AAr free to catalyze the formation of the 2,3-DHB acyl adenylate and keep the TAr carrier protein loaded as a 2,3-DHB phosphopantetheinyl thioester. In the case of enterobactin biosynthesis, the AAr and TAr domains, EntE and EntB, respectively, are separate from the main NRPS module, EntF, which activates and loads Ser as a T domain phosphopantetheinyl thioester. The full length EntF is required for trimerization of Ser, amide bond formation with 2,3-DHB, and cyclization to the macrolactone. Thus, only AAr and TAr domains have been shown to be active in trans supporting the existence of ObiF NRPS modules with and without the AAr domain as part of the main NRPS module (see
Without being limited to any particular theory, other catalytic domains with active site Cys residues might be capable of catalyzing the cyclization of β-hydroxy thioesters to β-lactones. For example, it was previously reported that an uncharacterized ketosynthase (KS) domain resides at the C-terminus of the ebelactone PKS termination module. KS-Domains are reported to undergo transthioesterification reactions with T-domain thioesters to form an intermediate KS Cys thioester that is part of a conserved Cys-His-His triad. The KS Cys-His-His triad typically catalyzes thio-Claisen condensation with a malonyl T domain thioester, but might also be capable of β-lactone ring formation. The termination module of the hybrid PKS-NRPS assembly line for oxazolomycin features a C-terminal C domain of unknown function. Condensation domains typically catalyze amide bond formation between two T domain thioesters, but there are previously documented cases of C domains catalyzing cyclization during product release such as in cyclosporin A and enniatin biosynthesis. The terminal C-domain of the oxazolomycin assembly line might catalyze the intramolecular condensation of a T domain thioester to the spirocyclic β-lactone. The salinosporamide biosynthetic gene cluster encodes for several uncharacterized enzymes including a stand-alone KS domain, SalC, and a type II thioesterase, SalF4. SalF contains a GXSXG catalytic motif and has been proposed to be involved in proofreading, which might indicate a role as a classic hydrolase. The KS domain SalC could be involved in formation of the cis-fused bicyclic β-lactone or the salinosporamides might experience the same fate as the closely related lactacystin, which is cleaved from the assembly line as an N-acetylcystein thioester and non-enzymatically equilibrates with the β-lactone in solution.
The presence of genes encoding for a pyruvate decarboxylase and threonine aldolase simultaneously in a biosynthetic gene cluster may also serve as a genetic signature for β-hydroxy-α-amino acid production. Fe(II)/α-KG-dependent oxygenases and non-heme di-iron oxygenases are known to produce β-hydroxy-α-amino acids via direct C—H bond activation chemistry. The direct hydroxylation of amino acid side chains take place while loaded as phosphopantetheinyl thioesters on NRPS T domains. This makes A domain substrate prediction insufficient for the potential incorporation of β-hydroxy-α-amino acids into NRP scaffolds.
The Obi β-lactone scaffold represents a novel structural class of β-lactone antibiotics from nature's chemical inventory. The Obi biosynthetic machinery characterized in this study offers a versatile platform for the chemoenzymatic synthesis of β-lactones from β-hydroxy α-amino acid precursors. Here, the novel amino acid β-OH-p-NO2-homoPhe was produced by the tandem action of arylamine oxidase ObiL, phenylpyruvate decarboxylase ObiG, and threonine aldolase ObiH, which might represent a general strategy for producing β-hydroxy-α-amino acid precursors to peptide β-lactones. The Obi NRPS biosynthetic machinery, ObiF and ObiD, contains a sequence novel TE domain with a rare catalytic Cys residue that plays a direct role in β-lactone ring formation.
In an aspect, β-hydroxy-α-amino acids may be directly incorporated into peptide scaffolds on an NRPS assembly line leading to peptides capped at the C-terminus with a β-lactone warhead. The genetic and biochemical characterization of the Obi biosynthetic pathway in P. fluorescens described herein serves as a basis for expanding the known chemistry of NRPS and PKS product release mechanisms to include strained ring formation. In various aspects, the chemoenzymatic approach to the biosynthesis of C-terminal β-lactone peptides may be modified as described above to enable precursor-directed process modifications and NRPS engineering to develop biosynthetic methods for producing a variety of targeted peptide β-lactone inhibitors of proteases for the treatment of diseases associated with microbial and viral infections, cancer, and/or obesity.
In various aspects, at least one of the isolated and purified enzymes encoded by the Obi gene cluster may be incorporated into a method for producing a peptide beta-lactone from one or more precursor compounds. The method makes use of the biosynthetic pathways and enzymes disclosed herein associated with the production of RC-Obi (see
In various aspects, the isolated and purified enzymes incorporated into the method of producing peptide beta-lactones may be any one or more enzymes encoded by the Obi gene cluster of Pseudomonas fluorescens as well as variants of the one or more enzymes including, but not limited to, homologous enzymes from other Pseudomonad species including the environmental chitin-degrading bacterium Chitiniphilus shinanonensis and the plant growth-promoting rhizobacterium Burkholderia diffusa. In another aspect, the enzymes used in various aspects of the method may be modified to enhance enzyme activity for a particular substrate and/or to maintain activity for a wider variety of substrates.
The number of enzymes incorporated into the method in various aspects may vary depending on one or more of at least several factors including, but not limited to, the precursor compounds used to produce the peptide beta-lactones using the method and/or any modifications to the enzymes used in the method. In one aspect, the method of producing a peptide beta-lactone may include a number of enzymes encoded by the Obi gene cluster ranging from one enzyme to about 11 enzymes or more.
In various aspects, the enzymes incorporated into the method of producing peptide beta-lactones may be isolated and purified enzymes obtained by isolation from one or more cell cultures that contain cells that express one or more of the enzymes used in the method. In one aspect, the cell cultures may contain cells that express the one or more enzymes as describe herein above including, but not limited to Pseudomonas fluorescens cells, Chitiniphilus shinanonensis cells, and Burkholderia diffusa cells. In another aspect, the cell cultures may include transgenic cells including, but not limited to, transgenic E. coli and yeast cells in which at least a portion of the Obi gene cluster expressing one or more of the enzymes associated with RC-Obi biosynthesis forms have been introduced. In an aspect, at least a portion of the Obi gene cluster introduced into the transgenic cell may be modified using known methods in order to enhance the efficiency of enzyme expression.
In one aspect, the isolated enzymes may be one or more enzymes encoded by at least a portion of the Obi gene cluster. Suitable enzymes may include the enzymes associated with biosynthesis as listed in Table 3 below:
In an aspect, the one or more enzymes may be isolated and purified from the one or more cell cultures using any known method including, but not limited to, chromatographic separation methods similar to the isolation and purification methods described in the Examples herein. In one aspect, for those enzymes produced by transgenic cells, the enzymes may be further treated after isolation and purification in order to activate the enzyme prior to use. By way of non-limiting example, recombinant ObiF and ObiD enzymes may be treated with phosphopantetheinyl transferase (Sfp) enzyme in order to add the required phosphopantetheinyl post-translational modification to the PCP domains that is required for activity prior to use.
In one aspect, the method illustrated in
In one aspect, the aryl carrier protein used in the method may be ObiD, a homolog of ObiD, recombinant ObiD, and any variation thereof comprising the amino acid sequence of SEQ ID NO:1 or fragment thereof. The ObiD positions the activated benzoic acid derivative at the C domain of ObiF for subsequent transthioesterification of the beta-hydroxy-alpha-amino acid and benzoic acid derivative, as well as the formation of the peptide beta-lactone, as illustrated in
In various aspects, the method may produce any peptide beta-lactone without limitation with suitable modification of the ObiF and/or ObiD enzymes. In one aspect, the peptide beta-lactone produced by the method may be obafluorin (RC-Obi), as illustrated in FIG. 3C. In another aspect, the method peptide beta-lactone produced by the method may be an obafluorin analog including, but not limited to any compound with one of the chemical structures as described below:
In another aspect, the method may further include hydrolyzing the peptide beta-lactone produced by the method to produce a peptide beta-hydroxy acid, including, but not limited to, any compound with any one of the chemical structure as described herein below:
R=
In various aspects, any benzoic acid derivative may be contacted with the ObiF and ObiD enzymes or variations thereof without limitation. Non-limiting examples of suitable benzoic acid derivatives include 2,3-dihydroxoybenzoic acid, as described herein previously (see
In various aspects, any beta-hydroxy-alpha-amino acid may be contacted with the ObiF enzyme or variations thereof without limitation. Non-limiting examples of suitable beta-hydroxy-alpha-amino acid include beta-OH-p-NO2-homoPhe and beta-OH-homoPhe, as described herein previously (see
In another aspect, the method may also include forming the beta-hydroxy-alpha-amino acid by contacting an aliphatic or aryl aldehyde or derivative thereof, an amino acid, and a pyridoxyl phosphate (PLP) cofactor with a serine hydroxymethyltransferase/threonine aldoloase.
In an aspect, the serine hydroxymethyltransferase/threonine aldoloase used in the method may be ObiH, a homolog of ObiH, and any variation thereof comprising the amino acid sequence of SEQ ID NO:3 or fragment thereof. The ObiH catalyzes the synthesis of the beta-hydroxy-alpha-amino acid from the aliphatic or aryl aldehyde or derivative thereof and the amino acid in conjunction with the PLP cofactor as illustrated in
In various aspects, any amino acid may be contacted with the ObiH or variations thereof without limitation. Non-limiting examples of suitable amino acids include: threonine and any isomer thereof, serine and any isomer thereof, and glycine and any isomer thereof. In one aspect, the amino acid may be L-threonine (L-Thr) as described herein previously (see
In various aspects, any aliphatic or aryl aldehyde or derivative may be contacted with the ObiH or variations thereof without limitation. Non-limiting examples of suitable aliphatic or aryl aldehydes or derivatives include: aliphatic aldehydes, aromatic benzaldehydes, aromatic phenylacetaldehydes, and aromatic cinnamaldehydes. In one aspect, the aliphatic or aryl aldehydes may be p-NO2-phenylacetaldehyde (PNPAA) as described herein previously (see
In another aspect, the method may also include forming the aliphatic or aryl aldehyde or derivative thereof by contacting an aliphatic or aryl pyruvate or derivative thereof and thiamine pyrophosphate (TPP) with a thiamine dependent pyruvate decarboxylase.
In an aspect, the thiamine dependent pyruvate decarboxylase used in the method may be ObiG, a homolog of ObiG, and any variation thereof comprising the amino acid sequence of SEQ ID NO:4 or a fragment thereof. The ObiG catalyzes the conversion of the phenyl pyruvate or derivative thereof to the aliphatic or aryl aldehyde or derivative in conjunction with the TPP cofactor as illustrated in
In various aspects, any phenyl pyruvate or derivative may be contacted with the ObiG or variations thereof without limitation. Non-limiting examples of suitable phenyl pyruvates or derivatives include: p-nitrophenylpyruvate, p-hydroxyphenylpyruvate, and phenylpyruvate. In one aspect, the phenyl pyruvate or derivative may be p-nitrophenylpyruvate (PNPPA) as described herein previously (see
In another aspect, the method may also include forming the aliphatic or aryl pyruvate derivative consisting of p-nitrophenylpyruvate (PNPPA) by contacting p-aminophenylpyruvate (PAPPA), oxygen, and Fe(II) with a p-aminobenzoate N-oxygenase.
In an aspect, the p-aminobenzoate N-oxygenase used in the method may be ObiL, a homolog of ObiL, and any variation thereof comprising the amino acid sequence of SEQ ID NO:5 or fragment thereof. The ObiL catalyzes the conversion of PAPPA to PNPPA in conjunction with the Fe(II) cofactor as illustrated in
In another aspect, the method may be further modified to produce an N-acyl-beta-hydroxy-alpha-amino acid by hydrolyzing the peptide beta-lactone produced using any of the previous methods described herein above. Any suitable known method of hydrolysis may be used to hydrolyze the peptide beta-lactone without limitation. By way of non-limiting example, the peptide beta-lactone may be contacted with a hydrolyzing agent including, but not limited to, MES buffer.
The genome of the known RC-Obi producer Pseudomonas fluorescens ATCC 39502 was sequenced to search for a putative Obi biosynthetic gene cluster. P. fluorescens ATCC 39502 was purchased from ATCC and glycerol stocks were made from cells grown in Bennet's media and stored at −80° C.
The P. fluorescens ATCC 39502 gDNA was isolated using a Qiagen DNeasy Blood & Tissue kit following the provided instructions. The gDNA was sequenced by Ambry Genetics (Aliso Viejo, Calif.) using Illumnia MiSeq. Contigs containing ORFs were assembled, annotated, and deposited in GenBank (Accession #s KX134682-KX134695) with assistance from Cofactor Genomics (St. Louis, Mo.).
A gene cluster of approximately 20 kb with 14 candidate coding sequences (CDSs) was identified, including one encoding an AurF di-iron non-heme arylamine oxygenase homolog (ObiL) predicted to install the aryl nitro functional group via oxidation of the precursor aniline, as illustrated in
1Functions were predicted from NCBI protein BLAST searches against the non-redundant protein database. Homologous protein names are shown in parentheses.
P. fluorescens
C. shinanonensis
B. diffusa
Pseudomonas
Pseudomonas
aPredicted gene functions are provided in Supplementary Table 1.
bDomains = C-A-T-TE.
cDomain = AAr.
dThere is a frame with an internal stop codon. The gene shows homology to WP_015032126.1, a predicted amino-deoxychorismate synthase, component I.
The sequenced Obi gene cluster was found to encode for putative enzymes required for the biosynthesis of 2,3-DHB (ObiA, ObiB, ObiC, and ObiE) and the non-proteinogenic amino acid β-OH-p-NO2-homoPhe (ObiG, ObiI, ObiJ, ObiK, and ObiL), as summarized in
Referring again to Table 4, genes obiM and obiN were determined to encode for proteins with strong homology to acylhomoserine lactone (AHL) synthase LuxI and AHL-binding transcriptional regulator LuxR, respectively. The LuxILuxR pair is known to be a common quorum sensing system found in many Pseudomonads. A BLAST search of the NCBI database using the NCBI BLAST analysis of the Obi biosynthetic gene cluster from P. fluorescens ATCC 39502 revealed homologous gene clusters in the environmental chitin-degrading bacteria Chitiniphilus shinanonensis SAY3 and the rhizobacterium Burkholderia diffusa RF8-non_BP2. Two additional clusters were found in Pseudomonas sp. 37 R 15 and Pseudomonas sp. 34_E_7 that were virtually identical in sequence identity (>95% for all protein sequences) and direction of gene transcription compared to the gene cluster found in P. fluorescens ATCC 39502. GenBank accession numbers are shown in Table 4 above. Gene function predictions, also shown in Table 4, revealed homologous Obi clusters in other Pseudomonads including Pseudomonas sp. 37_R_15 and 34_E_7, the environmental chitin-degrading bacterium Chitiniphilus shinanonensis SAY3 (see
The results of these experiments identified a gene cluster of approximately 20 kb with 14 candidate coding sequences (CDSs) within the genome of the known RC-Obi producer Pseudomonas fluorescens ATCC 39502.
To demonstrate the cloning of various enzymes associated with the biosynthesis of RC-Obi, the following experiments were conducted.
Gene sequences were amplified from either P. fluorescens ATCC 39502 gDNA or C. shinanonensis DSM 23277 gDNA (isolated using Qiagen DNeasy Blood & tissue kit following provided instructions) using forward and reverse primers designed for each gene (see Tables 6 and 7 below) and a Herculase II Fusion DNA Polymerase kit.
P. fluorescens gDNA
P. fluorencens gDNA
P. fluorescens gDNA
P. fluorescens gDNA
P. fluorescens gDNA
C. shinanonensis gDNA
C. shinanonensis gDNA
The resulting PCR fragments were purified by gel electrophoresis. PCR products and pET28a vectors were separately digested with either FD-NdeI and FD-HindIII or NheI and FDHindIII. Cut DNA was purified using a QIAquick Gel Extraction Kit without running an agarose gel. Ligation reactions were carried out overnight at 16° C. using T4 DNA Ligase. Ligation mixtures were purified and transformed into electrocompetent E. coli TOP10 cells. Clones were selected for on LB agar containing 50 μg/mL kanamycin. Sequencing of selected colonies revealed clones containing the desired constructs. Plasmids were purified and used to transform electrocompetent E. coli BL21 (DE3) cells.
The organism strains and plasmids described above are summarized in Table 8 below:
Pseudomonas
Fluorescens
Chitiniphilus
shinanonensis
E. coli TOP10
E. coli BL21 (DE3)
E. coli BL21 (DE3)
E. coli BL21 (DE3)
E. coli BL21 (DE3)
E. coli BL21 (DE3)
E. coli BL21 (DE3)
E. coli BL21 (DE3)
E. coli BL21 (DE3)
E. coli BL21 (DE3)
E. coli BL21 (DE3)
E. coli BL21 (DE3)
The experiments described above resulted in the successful cloning of various enzymes associated with the biosynthesis of RC-Obi.
To demonstrate the expression and purification of various enzymes associated with the biosynthesis of RC-Obi, the following experiments were conducted.
For protein expression, a 5 mL culture of E. coli BL21 harboring the appropriate plasmid (see Table 8 above) was grown overnight in LB containing 50 μg/mL kanamycin with agitation at 37° C. A 200 μL aliquot of this culture was used to inoculate 500 mL of terrific broth (12 g/L tryptone, 24 g/L yeast extract, 5 g/L glycerol, 17 mM KH2PO4, 72 mM K2HPO4) containing 50 μg/mL kanamycin. The culture was grown at 37° C. with agitation until OD600 reached approximately 0.4. The culture was cooled in an ice bath for 20 min, then 500 μL of a sterile 0.5 M IPTG solution was added. The culture was then incubated with agitation for 18 hrs. (at 15° C. for ObiG/ObiF/CS-ObiF, and at 20° C. for ObiD/CS-ObiD/ObiH/ObiL).
All subsequent protein purification steps were performed at 4° C. Cells were harvested by centrifugation of the cultures at 5,000 rpm for 20 minutes. Supernatant was discarded, and cell pellets were each suspended in 40 mL cold lysis buffer (50 mM K2HPO4 pH 8.0, 500 mM NaCl, 5 mM β-mercaptoethanol, 20 mM imidazole, 10% glycerol). Cell suspensions were transferred to 50 mL falcon tubes and flash frozen in liquid nitrogen. Frozen cells were thawed and gently rocked for 30 minutes before being mechanically lysed using an Avestin EmulsiFlex-C5 cell disruptor. Cell lysate was centrifuged at 45,000 rpm for 35 min and supernatant was incubated with pre-washed Ni-NTA resin for 30 min. Resin was washed twice with 40 mL lysis buffer then eluted five times with 10 mL elution buffer (50 mM K2HPO4 pH 8.0, 500 mM NaCl, 5 mM β-mercaptoethanol, 300 mM imidazole, 10% glycerol). Fractions containing the majority of protein, as judged by SDS-PAGE with Coomassie blue visualization (see
The experiments described above resulted in the successful expression and purification of various proteins serving as enzymes in the biosynthesis of RC-Obi.
To produce mutated analogs of wild-type ObiF, the following experiments were conducted.
Mutagenesis primers (see Table 6 and Table 7 above) were phosphorylated using T4 Polynucleotide Kinase according to product instructions. Primers were taken directly from phosphorylation mixture for use in PCR amplification. PCR was carried out using a Herculase II Fusion DNA Polymerase kit. After amplification, 1 μL FastDigest DpnI was added to PCR reaction mixture to digest template plasmid with wild type gene. Reaction was incubated at 37° C. for 60 min, then plasmids were purified using gel electrophoresis methods similar to those described in Example 3 above. Purified plasmids were ligated overnight at 16° C. using T4 DNA ligase, then transformed into electrocompetent E. coli TOP10 cells. Plasmids were sequenced using methods similar to those described in Example 1 to confirm the desired mutations.
The experiments described above resulted in the production of plasmids used to produce two mutated analogs of wild-type ObiF, ObiF-C1141S and ObiF-C1141A.
To determine the sensitivity of ObiG activity with respect to different pyruvic acid substrates, the following experiments were conducted.
Purpald® indicator was used to estimate the activity of ObiG enzyme for four different pyruvic acid substrates according to the reaction scheme illustrated in
The results of this experiment demonstrated varying levels of ObiG activity depending on the substitution at the para-position of the phenylpyruvic acid.
To characterize the formation of a stable quinonoid by ObiH, the following experiments were conducted.
In a 1.5 mL Eppendorf tube, a master mix of 50 μM ObiH from a freshly thawed frozen stock, 50 μM PLP, and 25 mM MES buffer was prepared and analyzed by optical absorption spectroscopy scanning from 200-600 nm. Three solutions at a final volume of 500 μL were analyzed as single trials: 1) L-Thr was added to the master mix a 1 mM final concentration; 2) PAA was added to the master mix at 1 mM final concentration; and 3) L-Thr and PAA were added to the master mix at 1 mM final concentration each. All samples were then analyzed by optical absorption spectroscopy scanning from 200-600 nm in order to observe the quinonoid peak which absorbs at ˜495 nm.
The results of these experiments demonstrated that when ObiH was contacted with PLP and L-Thr, a quinonoid was formed.
To characterize the bioconversion of PNPPA to β-OH-p-NO2-homoPhe by the enzymes ObiG and ObiH, the following experiments were conducted.
Three solutions were prepared using individual Eppendorf tubes. First, an ObiG solution containing 10 μM ThDP, 10 μM MgCl2, and 10 μM ObiG was adjusted to 333 μL final volume using 25 mM MES buffer pH 7.5 and allowed to pre-incubate for 5 min. Second, a pyruvic acid solution containing 1 mM final concentration of PNPPA, PAPPA, PHPPA, and PPA, was adjusted to 333 μL with 25 mM MES buffer pH 7.5. Third, an ObiH solution containing 10 μM PLP, 1 mM amino acid (L-Thr), and 10 μM ObiH was adjusted to 333 μL final volume. After the pre-incubation time was complete, the three solutions were combined in a single Eppendorf tube and allowed rest for 3 hrs. at room temperature before quenching with MeCN to crash the enzyme. The mixtures were centrifuged and the supernatants were analyzed by LC-MS using a gradient of 0% B held for 5 minutes then 0% B to 95% B over 10 min using single ion monitoring for the expected ions in positive ion mode (retention times and observed product ions (see
For NMR analysis the same samples were prepared using fully deuterated MES buffer. After equilibration for 3 hrs., the reactions were quenched with TFA to a pH˜2. The samples were then flash frozen in liquid nitrogen, lyophilized to dryness, resuspended in 750 μL of D2O, and centrifuged to pellet any insoluble particulate. The soluble supernatants were then transferred to NMR tubes and analyzed. All reactions were performed in triplicate.
To characterize the bioconversion of PNPPA to β-OH-p-NO2-homoPhe by the enzymes ObiG and ObiH, the following experiments were conducted.
Three solutions were prepared using individual Eppendorf tubes. First, an ObiG solution containing 10 μM TPP, 10 μM MgCl2, and 10 μM ObiG was adjusted to 333 μL final volume using 25 mM MES buffer pH 7.5 and allowed to pre-incubate for 5 min. Second, a pyruvic acid solution containing 1 mM final concentration of PNPPA, was adjusted to 333 μL with 25 mM MES buffer pH 7.5. Third, an ObiH solution containing 10 μM PLP, 1 mM amino acid (L-Thr, D-Thr, L-Ser, D-Ser, Gly, L-alloThr, or D-alloThr), and 10 μM ObiH was adjusted to 333 μL final volume. After the pre-incubation time was complete, the three solutions were combined in a single Eppendorf tube and allowed rest for 3 hrs. at room temperature before quenching with MeCN to crash the enzyme. The mixtures were centrifuged and the supernatants were analyzed by LC-MS using a gradient of 0% B held for 5 minutes then 0% B to 95% B over 10 min using single ion monitoring for the expected ions in positive ion mode. Product masses were confirmed by high-resolution LC-MS analysis.
After 3 hrs. of reaction time, the EICs were obtained for the product [M+H]+ ion (m/z=241) of the β-OH-p-NO2-homoPhe as predicted by the reaction diagram illustrated in
A double enzyme reaction with ObiG and ObiH in the presence of TPP, PLP, and L-Thr revealed that PNPPA is directly converted to β-OH-p-NO2-homoPhe as detected by LC-MS (
To characterize the structure of the β-OH-p-NO2-homoPhe product resulting from the ObiG/ObiH double enzyme reaction described above (see
The ObiG/ObiH double enzyme reaction described above was scaled up with respect to the substrates to produce enough material for NMR analysis. The concentrations of reaction components were 10 μM ObiG, 10 μM ThDP, 10 μM MgCl2, 10 μM ObiH, 10 μM PLP, 5 mM L-Thr, 5 mM PNPPA, and 25 mM pH 7.5 MES buffer, with a final reaction volume of 1 mL. After 3 hrs., the reaction was quenched with TFA to a pH˜2, centrifuged at 13,000 rpm for 2 min, flash frozen in liquid nitrogen, and lyophilized to dryness. The resulting solid was dissolved in 1:10 MeCN:H2O, filtered, and purified by preparatory HPLC using a solvent gradient of 0% B held for 5 min then 0% B to 100% B over 10 min (β-OH-p-NO2-homoPhe retention time=14.3 min). The desired TFA salt of β-OH-p-NO2-homoPhe product was isolated as a white powder.
Table 9 is a summary of the NMR data obtained from a sample of the β-OH-p-NO2-homoPhe product described above. NMR spectra obtained from the β-OH-p-NO2-homoPhe product are provided as
1H-1H
13C (ppm)
1H (ppm),
1H-1H
1H-13C
The results of these experiments characterized the structure of the β-OH-p-NO2-homoPhe product resulting from the ObiG/ObiH double enzyme reaction described above.
A solution of 100 μM ObiL from a freshly thawed frozen stock, 3 mM phenazine methosulfate, 1 mM PAPPA, 100 μM iron(II) sulfate, and 25 mM NADH was prepared in 25 mM MES buffer at pH 5.5 at a final volume of 500 μL. NADH was added last to initiate the reaction and the mixture was incubated at room temperature for 1 hr. Upon addition of NADH, the color of the reaction changed from light yellow to sky blue to indicate the conversion of PAPPA to PNPPA by the reaction.
In a separate Eppendorf tube a 500 μL solution was prepared containing 10 μM ObiG, 10 μM ThDP, 10 μM MgCl2, 10 μM ObiH, 10 μM PLP, 1 mM L-Thr, and 25 mM MES buffer at pH 7. The ObiG/ObiH solution was added directly to the ObiL solution formed above and the mixture was allowed to react for 2 hrs. at room temperature. The reaction mixture was quenched with MeCN to crash the enzyme. The pH of the ObiL solution changed from 5.5 to 7.0 over the course of the reaction. The control assay (i.e. no ObiL) reached an end pH of 6.0 and was adjusted to a pH of 7 using 1 M NaOH prior to addition of the ObiG/ObiH solution.
The resulting mixtures were centrifuged and the supernatants were analyzed by LC-MS using a gradient of 0% B held for 5 min then 0% B to 95% B over 10 min. Ion counts for expected products were extracted from total ion chromatograms in positive ion mode.
To characterize the formation of β-lactone analogs of RC-Obi using the obafluorin NRPS ObiF/ObiD reaction scheme (see
Phosphopantetheinylation of apo-ObiD and apo-ObiF (wild type, C1141S/C1141A mutants, and C. shinanonensis homologues) was carried out in separate 500 μL solutions containing 180 μM CoASH, 5 mM DTT, 10 mM MgCl2, 400 nM Sfp, 25 μM apo-enzyme, and 75 mM tris-HCl at pH 7.552. The C1141S/C1141A mutant enzymes were produced using the methods described in Example 4 above. Reactions were left at room temperature for 2 hrs., and then used directly as the source of holo-ObiD and holo-ObiF. Reactions were performed in duplicate at 500 μL total volume. Full reactions contained 5 mM ATP, 5 mM DTT, 1 mM 2,3-DHB, 1 mM β-OH-p-NO2-homoPhe, 1 μM holo-ObiF (ObiF, CS-ObiF, ObiF-C1141A, or ObiF-C1141S), 1 μM holo-ObiD, and 75 mM tris-HCl at pH 7.5. Control reactions were also prepared by replacing various components with an equivalent volume of 75 mM tris-HCl buffer. Three control experiments were performed for the ObiF (see Table 10), ObiF-C1141S (see Table 11), ObiF-C1141A (see Table 12), CS-ObiF reactions: (−) ObiD; (−) 2,3-DHB/(−) β-OH-p-NO2-homoPhe; and (−) ATP (see Table 13). Two additional controls were prepared as either (−) ObiF or (−) ObiF/(−) ObiD. Reactions were performed at room temperature.
aReactions were conducted as described in the Online Methods.
bPresence (+) or absence (−) of products was judged by LC-MS analysis.
aReactions were conducted as described in the Online Methods.
bPresence (+) or absence ( ) of products was judged by LC-MS analysis.
aReactions were conducted as described in the Online Methods.
bPresence (+) or absence ( ) of products was judged by LC-MS analysis.
aReactions were conducted as described in the Online Methods.
bPresence (+) or absence ( ) of products was judged by LC-MS analysis.
At 10, 30, and 60 min time points a 50 μL aliquot from each reaction was quenched with 50 μL acidic MeCN (acidified with HCl) to give a final pH of approximately 3.5. Mixtures were centrifuged for 2 min at 13,000 rpm to remove precipitated enzyme and the supernatants were analyzed by LC-MS using a gradient of 5% solvent B to 95% solvent B over 20 min. Ion counts for the closed-ring obafluorin RC-Obi and open-ring obafluorin RO-Obi were extracted from total ion chromatograms in positive ion mode. Reaction mixtures were also analyzed by HPLC using a gradient of 5% B to 95% B over 20 min, 95% B to 100% B over 3 min, and 100% B to 5% B over 2 min at a flow rate of 1 mL/min with optical absorbance detection at 270 nm. Product ions and retention times were confirmed using purified standards of RC-Obi and RO-Obi isolated from P. fluorescens ATCC 39502 fermentations.
The reaction mixture of the ObiF/ObiD-catalyzed conversion of 2,3-DHB and β-OH-p-NO2-homoPhe as monitored by HPLC with detection by optical absorbance is shown in
As illustrated in
As illustrated in
As illustrated in
To assess the effect of different substrates on the ObiF/ObiD-catalyzed formation of RC-Obi, the reaction and analysis described above was repeated for the ObiF/ObiD reactions with β-OH-p-NO2-homoPhe and 2,3-DHB, with β-OH-homoPhe substituted for β-OH-p-NO2-homoPhe, as illustrated schematically in
The results of these experiments demonstrated the production of Obi and Obi analogs using enzymatic synthesis with ObiD and ObiF.
To characterize the activity of the ObiF enzyme exposed to various amino acid and carboxylate substrates, the following experiments were conducted.
Reaction mixtures (650 μL) were formed that contained 2 μM ObiF, 5 mM of an amino acid, 1 mM ATP, 1 mM MgCl2, 40 mM KCl, 1 mM DTT, 5 mM Na[32P]PPi (3.3×105 cpm/mL), and 50 mM Tris-HCl (pH 8). The reaction mixtures were incubated at room temperature for 30 min, then three 200 μL aliquots of each reaction mixture were removed and quenched with 500 μL of a charcoal suspension (100 mM NaPPi, 350 mM HClO4, and 16 g/L powdered charcoal). The reaction mixture samples were shaken and then centrifuged at 13,000 rpm for three minutes. The resulting charcoal pellets were washed with 750 μL of wash solution (100 mM NaPPi, 350 mM HClO4) and centrifuged again for three min. This washing step was repeated once more, followed by suspension of the charcoal pellets in 1.5 mL EcoLite(+) scintillation fluid from MP Biomedicals. Charcoal-bound radioactivity was measured on a Beckman Coulter LS 6500 scintillation counter.
The results of these experiments demonstrated that the recombinant ObiF was most active upon contact with one of the carboxylate substrates β-OH-p-NO2-homoPhe and 2,3-DHB.
To isolate the closed-ring isoform of obafluorin (RC-Obi) and the ring-opened obafluorin hydrolysis product (RO-Obi), the following experiments were conducted.
RC-Obi and RO-Obi were isolated from Pseudomonas fluorescens ATCC 39502 fermentations. Bennet's Agar slants (1 g/L yeast extract, 1 g/L beef extract, 2 g/L NZ amine, 10 g/L glucose, 15 g/L agar) were inoculated with streaks of P. fluorescens ATCC 39502 from a frozen glycerol stock. The slants were incubated at 25° C. for 48 hrs. 5 mL of sterile saline was added to the top of the slant and shaken gently. Inoculated saline (1 mL) was transferred to 100 mL of sterile media (5 g/L yeast extract, 5 g/L glucose, 0.1 g/L MgSO47H2O, 0.1 g/L FeSO4.7H2O, 200 mL local soil filtrate extract, and 800 mL tap water, autoclaved) to form a starter culture.
The starter culture was incubated with shaking at 225 rpm at 25° C. for 24 hrs. 5 mL samples of the starter culture were transferred to 3 L baffled flasks containing 500 mL of the same media, and the resulting cultures were incubated with shaking at 225 rpm at 25° C. for 17 hrs. The cultures were pooled and centrifuged at 5000 rpm at 4° C. for 25 min to pellet the cultured cells. The supernatant of the pooled cultures was acidified to pH 3 with 1M aqueous HCl. The pooled supernatant was saturated with EtOAc then extracted with three 100 mL volumes of EtOAc. Extractions were pooled and dried using rotary evaporation to yield a grey-brown solid. The solid was dissolved in 10 mL acetonitrile, filtered, and concentrated by rotary evaporation under reduced pressure to yield 221 mg of clear, brown oil.
The oil was dissolved in 10 mL of acetonitrile, filtered, and purified with Prep HPLC with a gradient of 5% solvent B to 95% solvent B over 20 min. The two largest peaks were isolated which upon NMR analysis proved to be RC-Obi (retention time=23.0 min) and RO-Obi (retention time=20.5 min), both isolated as brown oils.
Table 14 is a summary of the NMR data obtained from the RC-Obi fraction of the oil. NMR spectra obtained from the RC-Obi fraction of the oil are provided as
13C
1H (ppm),
1H-1H
1H-13C
Table 15 is a summary of the NMR data obtained from the RO-Obi fraction of the oil. NMR spectra obtained from the RO-Obi fraction of the oil are provided as
1H-1H
13C
1H (ppm),
1H-1H
1H-13C
The results of these experiments resulted in the isolation and NMR characterization of purified RC-Obi and purified RO-Obi.
To characterize the role of the TE domain of the ObiF enzyme in β-lactone formation, an N-acetylcysteamine (SNAC) thioester (Obi-SNAC) was prepared, and the following experiments were conducted to compare the rates of hydrolysis of RC-Obi and Obi-SNAC.
A purified Obi-SNAC solution was produced by treatment of a purified RC-Obi solution with neat N-acetylcysteamine (SNAC), as illustrated in the schematic diagram in
The resulting purified Obi-SNAC solution was lyophilized overnight and dissolved in methanol-d4 for NMR analysis. Obi-SNAC forms a 2:1 mixture of rotamers in methanol-d4. The NMR data for the major rotamer are summarized in Table 16. The NMR spectra obtained from the Obi-SNAC solution are provided as
13C
1H (ppm), multiplets in Hz
aSinglet at 2.65 ppm in the 1H-NMR and 40.5 ppm in the 13C-NMR is residual DMSO.
bmultiplet consists of overlapping peaks from protons on C-12 and C-18, confirmed by HSQC and HMBC spectra.
cmultiplet consists of protons on C18 overlapping with peaks from methanol, as confirmed by HSQC, HMBC, and COSY.
Solutions of purified RC-Obi (1 mM) and Obi-SNAC (1 mM) were prepared in MES buffer at pH˜7 to form two reaction mixtures. Aliquots (100 μL) of each reaction mixture were taken at various time points to be analyzed by HPLC (gradient of 5% B to 95% B over 20 min, 95% B to 100% B over 3 min, and 100% B to 5% B over 2 min at a flow rate of 1 mL/min) with detection by optical absorbance spectroscopy at 270 nm. HPLC peak identities were confirmed by LC-MS and retention times were normalized using an Fmoc-Ala internal standard. Experiments were performed in duplicate.
The results of these experiments indicate that enzyme catalysis by the TE domain of the ObiF enzyme precedes the transformation of an Obi thioester to the corresponding cyclic β-lactone RC-Obi.
To assess the antibiotic efficacy of RC-Obi and RO-Obi, the following experiments were conducted.
Bacterial strains (E. coli 29522 and E. coli X580) were grown from frozen glycerol stocks in LB media overnight at 37° C. with shaking. These starter cultures were used to inoculate fresh LB broth or M9 minimal media broth at an OD600 of 0.3. Each well of a 96-well plate was filled with 100 μL of sterile media (LB or M9). A sterile solution of RC-Obi or RO-Obi in LB or M9 media was added to the first well of each row and was serially diluted two-fold down the entire row creating a compound concentration gradient of 0.3-0.0025 mM.
Each well of the plate was then filled with 100 μL of the OD600 0.3 bacterial cell suspensions to give a final volume of 200 μL per well. The plates were incubated at 37° C. and the OD600 of each well was measured every 30 minutes over 24 hours. The plate was shaken briefly prior to each measurement to ensure an even cell suspension. All growth curves were generated in triplicate.
E. coli ATCC 25922 was passaged in LB broth through 6 overnight cycles in the presence of 0.25 mM RC-Obi β-lactone with fresh doses of antibiotic added every 18 hours for 6 days straight. The 6× passaged E. coli was then treated with varying concentrations of RC-Obi β-lactone in LB broth and was still susceptible to the antibiotic (see
The E. coli cells were also subjected to fluorescence microscopy after treatment with RC-Obi or RO-Obi. E. coli ATCC 29522 cells were grown in LB media for 8 hours at 37° C. then plated on agar media and incubated overnight at 37° C. A single colony was transferred into test tube with fresh LB media and allowed to grow to 0.3 OD600 at 37° C. Cells were diluted by a factor of 10, allowed to grow to OD600 0.3 again. Aliquots of the cell suspension (2 mL each) were treated with RC-Obi (0.1 mM), RO-Obi (0.5 mM), ampicillin (50 μg/mL), or buffer control and incubated for 2 hours at 37° C. Culture aliquots of 250 μL were then used for staining and fluorescence microscopy. Cell membranes and DNA were labeled with the fixable dyes FM 4-64fx and DAPI, respectively, according to the manufacturer's instructions. Cells were fixed with 2.6% paraformaldehyde+0.008% glutaraldehyde as previously described. Fixed cells were imaged on 1% agarose pads with an Olympus BX51 microscope equipped with a CCD OrcaERG camera (Hamamatsu Photonics, Bridgewater, N.J.), an Olympus Plan N 100×/1.25 Oil Ph3 objective, and an X-Cite 120 LED light source (Lumen Dynamics). Nikon elements were used for image capture using the DAPI and rhodamine filter sets from Chroma. Images were processed using NIS—Elements Basic Research Microscope Imaging Software (Nikon Corp.).
The results of this experiment demonstrated the antibiotic efficacy of RC-Obi against E. coli.
To assess the compatibility of various substrates and optimization of experimental conditions for the enzymatic synthesis of β-lactone rings described herein, the following experiments were conducted.
Various substrate compositions (see
Substrate screen compositions used in the enzymatic synthesis of β-lactone ring products were first tested to determine an optimization of intermediate ObiH production of beta-hydroxy-alpha-amino acid according to the reaction scheme illustrated in
To a 1.5 mL Eppendorf tube 25 mM sodium phosphate buffer, 2.5 mM L-threonine, 1 mM aldehyde, 10 μM PLP, and 10 μM ObiH were added, with the enzyme being added last to initiate the reaction. Total reaction volume was 1 mL in water. The reaction was allowed to progress at room temperature. After 1 hour, the reaction was quenched with the addition of 1 M HCl to bring to pH 2. L-phenylalanine was added as an internal standard at a final concentration of 100 μM. The reactions were run in triplicate and analyzed by LC-MS. For all screens, the LC-MS method used a revers phase C18 column where solvent A was water buffered with 0.1% formic acid and solvent B was acetonitrile buffered with 0.1% formic acid. A gradient of 0% B to 5% B was formed over 5 min followed by a gradient of 5% B to 95% B over 10 minutes. The maximum ion counts for the ObiH products were used to calculate product concentration relative to an internal phenylalanine standard. Experiments were performed in triplicate as independent trails. The measured concentrations of products of the process illustrated in
As shown in
To a 1.5 mL Eppendorf tube 25 mM sodium phosphate buffer, variable L-threonine (1-50 mM), variable phenylacetaldehyde (PAA; 2-10 mM), 10 μM PLP, and 10 μM ObiH were added, with the enzyme being added last to initiate the reaction. Total reaction volume was 1 mL in water containing 0%-50% DMSO or water containing 0%-50% MeOH. The reaction was allowed to progress at room temperature or 4° C. After 1 hour, the reaction was quenched with the addition of 1 M HCl to bring to pH 2. L-phenylalanine was added as an internal standard at a final concentration of 100 μM and the reactions were analyzed by LC-MS. The LC-MS method used a reverse phase C18 column where solvent A was water buffered with 0.1% formic acid and solvent B was acetonitrile buffered with 0.1% formic acid. A gradient of 0% B to 5% B was formed over 5 min followed by a gradient of 5% B to 95% B over 10 minutes. The maximum ion counts for the ObiH products were used to calculate product concentration relative to an internal phenylalanine standard. Experiments with variable L-threonine and PAA were performed in triplicate as independent trails. Experiments with variable DMSO and MeOH solvents were performed as single trials. The results of the optimization processes are illustrated in
Substrate screens for the ObiH,F,D reaction (
ObiF and ObiD were pantetheinylated by a solution containing 180 μM CoASH, 5 mM DTT, 400 nM Sfp, 10 mM MgCl2, 25 μM apo enzyme, and 25 mM sodium phosphate buffer. The pantetheinylation reaction was allowed to proceed at room temperature for 2 hours. After this reaction time, the solution was added to a 1.5 mL Eppendorf tube and contained 25 mM sodium phosphate buffer, 15 mM L-threonine, 10 μM PLP, 1 mM aldehyde, 1 mM 2,3-DHB, 5 mM DTT, 5 mM ATP, 10 μM ObiH, 2.5 μM holo-ObiF, and 2.5 μM holo-ObiD (holo-ObiF and -ObiD were used directly from the pantetheinylation reaction. The total reaction volume was 1 mL. The aldehydes were dissolved in a stock solution of 5% DMSO in water, making the final reaction 1% DMSO and 99% water by volume. The reaction was allowed to proceed at room temperature for 24 hours, at the end of which the reaction was quenched with 1 M HCl to a pH of 2 and analyzed by LC-MS. The LC-MS method used a reverse phase C18 column where solvent A was water buffered with 0.1% formic acid and solvent B was acetonitrile buffered with 0.1% formic acid. A gradient of 0% B to 5% B was formed over 5 min followed by a gradient of 5% B to 95% B over 10 minutes. The presence of ObiHDF products was confirmed by extracting the molecular ions from the total ion count from LC-MS analysis. Experiments were performed in triplicate as independent trails.
The compounds marked in blue in
To assess the application of the methods disclosed herein to the synthesis of alkyne-tagged chemical probes, the following experiments were conducted.
To a 1.5 mL Eppendorf tube 25 mM sodium phosphate buffer, 15 mM L-threonine, 1 mM aldehyde (5), 10 μM PLP, and 5 μM ObiH were added, with the enzyme being added last to initiate the reaction. Total reaction volume was 1 mL in 93% water/7% DMSO and the final pH was 7.5. The reaction was allowed to progress at room temperature for 3 hours. The reaction was quenched with the addition of 1 M HCl and analyzed by LC-MS. The LC-MS method used a reverse phase C18 column where solvent A was water buffered with 0.1% formic acid and solvent B was acetonitrile buffered with 0.1% formic acid. A gradient of 0% B to 5% B was formed over 5 min followed by a gradient of 5% B to 95% B over 10 minutes. The ObiH product 6 was detected in the LC-MS, as illustrated in the optical absorbance spectrum of
The ObiH product (6) was purified by prep-HPLC giving 5.4 mg that was characterized by multi-dimensional NMR, the results of which are shown graphed in
13C
1H-1H
1H-13C
1H-13C
1H (ppm), multiplets in Hz
ObiF and ObiD were pantetheinylated by a solution containing 180 μM CoASH, 5 mM DTT, 400 nM Sfp, 10 mM MgCl2, 25 μM apo enzyme, and 25 mM sodium phosphate buffer. The pantetheinylation reaction was allowed to proceed at room temperature for 2 hours. After this reaction time, a second reaction mixture containing 5 μM holo-ObiF, 5 μM holo-ObiD, 5 mM ATP, 5 mM DTT, 500 μM 2,3-DHB, 500 μM β-OH-p-alkynyl-homoPhe (6), and 25 mM PBS at pH 7.5. The reaction was left at room temperature for 24 hours, then quenched with HCl to a pH of 2 and analyzed by LC-MS. The LC-MS method used a reverse phase C18 column where solvent A was water buffered with 0.1% formic acid and solvent B was acetonitrile buffered with 0.1% formic acid. A gradient of 0% B to 5% B was formed over 5 min followed by a gradient of 5% B to 95% B over 10 minutes.
The beta-lactone product 7 produced a relatively weak signal in the LC-MS, as illustrated in the optical absorbance spectrum of
This written description uses examples to disclose the disclosure, including the best mode, and also to enable any person skilled in the art to practice the disclosure, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the disclosure is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.
This application claims the benefit of U.S. Provisional Application No. 62/471,183 filed on Mar. 14, 2017, the contents of which are incorporated herein by reference in their entirety.
Number | Date | Country | |
---|---|---|---|
62471183 | Mar 2017 | US |