Carboxyethylarginine synthase genes show complex cross-regulation in Streptomyces clavuligerus.

Carboxyethylarginine synthase is the first dedicated enzyme of clavam biosynthesis in Streptomyces clavuligerus and is present in two isoforms encoded by two separate genes. When grown on a liquid soy medium, strains with ceaS1 deleted showed only a mild reduction of clavam biosynthesis, while disruption of ceaS2 abolished all clavam biosynthesis. Creation of an in-frame ceaS2 deletion mutant to avoid polarity did not restore clavam production, nor did creation of a site-directed mutant altered only in a single amino acid residue important for activity. Reverse transcriptase PCR analyses of these mutants indicated that the failure to produce clavam metabolites could be traced to reduced or abolished transcription of ceaS1 in the ceaS2 mutants, despite the location of ceaS1 on a replicon completely separate from that of ceaS2. Western analyses further showed that the CeaS1 protein (as well as the CeaS2 protein) was absent from the ceaS2 mutants. Complementation experiments were able to restore clavam production partially, but only by virtue of restoring CeaS2 production. CeaS1 was still absent from the complemented strains. While this dependence of CeaS1 production on the expression of ceaS2 from its native chromosomal location was seen in all of the ceaS2 mutants, the effect was limited to growth in liquid medium. When the same mutants were grown on solid soy medium, clavam production was restored and CeaS1 was produced, albeit at low levels compared to the wild type.

5S clavam biosynthesis is controlled by an atypical two-component regulatory system in Streptomyces clavuligerus.

Streptomyces clavuligerus produces a collection of five clavam metabolites, including the clinically important ß-lactamase inhibitor clavulanic acid, as well as four structurally related metabolites called 5S clavams. The paralogue gene cluster of S. clavuligerus is one of three clusters of genes for the production of these clavam metabolites. A region downstream of the cluster was analyzed, and snk, res1, and res2, encoding elements of an atypical two-component regulatory system, were located. Mutation of any one of the three genes had no effect on clavulanic acid production, but snk and res2 mutants produced no 5S clavams, whereas res1 mutants overproduced 5S clavams. Reverse transcriptase PCR analyses showed that transcription of cvm7p (which encodes a transcriptional activator of 5S clavam biosynthesis) and 5S clavam biosynthetic genes was eliminated in snk and in res2 mutants but that snk and res2 transcription was unaffected in a cvm7p mutant. Both snk and res2 mutants could be complemented by introduction of cvm7p under the control of an independently regulated promoter. In vitro assays showed that Snk can autophosphorylate and transfer its phosphate group to both Res1 and Res2, and Snk-H365, Res1-D52, and Res2-D52 were identified as the phosphorylation sites for the system. Dephosphorylation assays indicated that Res1 stimulates dephosphorylation of Res2∼P. These results suggest a regulatory cascade in which Snk and Res2 form a two-component system controlling cvm7p transcription, with Res1 serving as a checkpoint to modulate phosphorylation levels. Cvm7P then activates transcription of 5S clavam biosynthetic genes.

A comparison of the clavam biosynthetic gene clusters in Streptomyces antibioticus Tü1718 and Streptomyces clavuligerus.

The production of clavam metabolites has been studied previously in Streptomyces clavuligerus , a species that produces clavulanic acid as well as 4 other clavam compounds, but the late steps of the pathway leading to the specific end products are unclear. The present study compared the clavam biosynthetic gene cluster in Streptomyces antibioticus , chosen because it produces only 2 clavam metabolites and no clavulanic acid, with that of S. clavuligerus. A cosmid library of S. antibioticus genomic DNA was screened with a clavaminate synthase-specific probe based on the corresponding genes from S. clavuligerus, and 1 of the hybridizing cosmids was sequenced in full. A clavam gene cluster was identified that shows similarities to that of S. clavuligerus but also contains a number of novel genes. Knock-out mutation of the clavaminate synthase gene abolished clavam production in S. antibioticus, confirming the identity of the gene cluster. Knock-out mutation of a novel gene encoding an apparent oxidoreductase also abolished clavam production. A potential clavam biosynthetic pathway consistent with the genes in the cluster and the metabolites produced by S. antibioticus, and correspondingly different from that of S. clavuligerus, is proposed.

Biosynthesis of clavam metabolites.

Naturally occurring clavam metabolites include the valuable ß-lactamase inhibitor, clavulanic acid, as well as stereochemical variants with side-chain modifications, called the 5S clavams. Because of the clinical importance of clavulanic acid, most studies of clavam biosynthesis are based on the industrial producer species Streptomyces clavuligerus. Well-characterized early steps in clavam biosynthesis are outlined, and less well understood late steps in 5S clavam biosynthesis are proposed. The complex genetic organization of the clavam biosynthetic genes in S. clavuligerus is described and, where possible, comparisons with other producer species are presented.

Clavulanic acid biosynthesis and genetic manipulation for its overproduction.

Clavulanic acid, a ß-lactamase inhibitor, is used together with ß-lactam antibiotics to create drug mixtures possessing potent antimicrobial activity. In view of the clinical and industrial importance of clavulanic acid, identification of the clavulanic acid biosynthetic pathway and the associated gene cluster(s) in the main producer species, Streptomyces clavuligerus, has been an intriguing research question. Clavulanic acid biosynthesis was revealed to involve an interesting mechanism common to all of the clavam metabolites produced by the organism, but different from that of other ß-lactam compounds. Gene clusters involved in clavulanic acid biosynthesis in S. clavuligerus occupy large regions of nucleotide sequence in three loci of its genome. In this review, clavulanic acid biosynthesis and the associated gene clusters are discussed, and clavulanic acid improvement through genetic manipulation is explained.

A conserved lysine in beta-lactam synthetase assists ring cyclization: Implications for clavam and carbapenem biosynthesis.

beta-Lactam synthetase (beta-LS) is the paradigm of a growing class of enzymes that form the critical beta-lactam ring in the clavam and carbapenem antibiotics. beta-LS catalyzes a two-stage reaction in which N(2)-(2-carboxyethyl)-L-arginine is first adenylated, and then undergoes intramolecular ring closure. It was previously shown that the forward kinetic commitment to beta-lactam formation is high, and that the overall rate of reaction is partially limited to a protein conformational change rather than to the chemical step alone of closing the strained ring. beta-Lactam formation was evaluated on the basis of X-ray crystal structures, site-specific mutation, and kinetic and computational studies. The combined evidence clearly points to a reaction coordinate involving the formation of a tetrahedral transition state/intermediate stabilized by a conserved Lys. The combination of substrate preorganization, a well-stabilized transition state and an excellent leaving group facilitates this acyl substitution to account for the strong forward commitment to catalysis and to lower the barrier of four-membered ring formation to the magnitude of a protein conformational change.

Alanylclavam biosynthetic genes are clustered together with one group of clavulanic acid biosynthetic genes in Streptomyces clavuligerus.

Streptomyces clavuligerus produces at least five different clavam metabolites, including clavulanic acid and the methionine antimetabolite, alanylclavam. In vitro transposon mutagenesis was used to analyze a 13-kb region upstream of the known paralogue gene cluster. The paralogue cluster includes one group of clavulanic acid biosynthetic genes in S. clavuligerus. Twelve open reading frames (ORFs) were found in this area, and mutants were generated in each using either in vitro transposon or PCR-targeted mutagenesis. Mutants with defects in any of the genes orfA, orfB, orfC, or orfD were unable to produce alanylclavam but could produce all of the other clavams, including clavulanic acid. orfA encodes a predicted hydroxymethyltransferase, orfB encodes a YjgF/YER057c/UK114-family regulatory protein, orfC encodes an aminotransferase, and orfD encodes a dehydratase. All of these types of proteins are normally involved in amino acid metabolism. Mutants in orfC or orfD also accumulated a novel clavam metabolite instead of alanylclavam, and a complemented orfC mutant was able to produce trace amounts of alanylclavam while still producing the novel clavam. Mass spectrometric analyses, together with consideration of the enzymes involved in its production, led to tentative identification of the novel clavam as 8-OH-alanylclavam, an intermediate in the proposed alanylclavam biosynthetic pathway.

5S clavam biosynthetic genes are located in both the clavam and paralog gene clusters in Streptomyces clavuligerus.

The Streptomyces clavuligerus clavam gene cluster was examined to identify genes specifically involved in 5S clavam biosynthesis. A reduction/loss of 5S clavam production was seen in cvm2 and cvm5 gene mutants, and a clavam metabolite not previously observed, 2-carboxymethylideneclavam, accumulated in the cvm5 mutant. Disruption of additional genes from the region of the clavam cluster did not have any effect on 5S clavam production. Examination of the paralog gene cluster region for 5S clavam biosynthetic genes led to the identification of cvm6P and cvm7P, which encode a putative aminotransferase and a transcriptional regulator, respectively. Mutants defective in cvm6P and cvm7P were completely blocked in 5S clavam but not clavulanic acid production. The loss of 5S clavam production in cvm7P mutants suggests that this gene encodes a transcriptional regulator specific for 5S clavam metabolite biosynthesis.

Enhancement of clavulanic acid by replicative and integrative expression of ccaR and cas2 in Streptomyces clavuligerus NRRL3585.

Clavulanic acid (CA) is an inhibitor of beta-lactamase that is produced from Streptomyces clavuligerus NRRL3585 and is used in combination with other antibiotics in clinical treatments. In order to increase the production of CA, the replicative and integrative expressions of ccaR (encoding for a specific regulator of the CA biosynthetic operon) and cas2 (encoding for the rate-limiting enzyme in the CA biosynthetic pathway) were applied. Six recombinant plasmids were designed for this study. The pIBRHL1, pIBRHL3, and pIBRHL13 were constructed for overexpression, whereas pNQ3, pNQ2, and pNQ1 were constructed for chromosomal integration with ccaR, cas2, and ccaR-cas2, respectively. All of these plasmids were transformed into S. clavuligerus NRRL3585. CA production in transformants resulted in a significantly enhanced amount greater than that of the wild type, a 2.25-fold increase with pIBRHL1, a 9.28-fold increase with pNQ3, a 5.06-fold increase with pIBRHL3, a 2.93-fold increase with pNQ2 integration, a 5.79-fold increase with pIBRHL13, and a 23.8-fold increase with pNQ1. The integrative pNQ1 strain has been successfully applied to enhance production.

The enzymology of clavam and carbapenem biosynthesis.

The enzyme-catalysed reactions involved in formation of the bicyclic clavam and carbapenem nuclei, including beta-amino acid and beta-lactam formation, are discussed and compared with those involved in penicillin and cephalosporin biosynthesis. The common role of unusual oxidation reactions in the biosynthetic pathways and the lack of synthetic reagents available to effect them are highlighted.

Clavulanic acid biosynthesis in Streptomyces clavuligerus: gene cloning and characterization.

Seven classes of Streptomyces clavuligerus mutants defective in clavulanic acid (CLA) biosynthesis have been identified and used to clone the chromosomal DNA encoding eight CLA biosynthetic genes. The complete sequences of three and the partial sequences of two of these biosynthetic genes are reported, together with their known or predicted functions.

Cloning, sequencing and disruption of a gene from Streptomyces clavuligerus involved in clavulanic acid biosynthesis.

During the purification of delta-(L-alpha-aminoadipyl)-L-cysteinyl-D-valine synthetase (ACVS) from Streptomyces clavuligerus, a small protein (CLA) involved in clavulanic acid production co-purified with ACVS. A 24-mer mixed-DNA probe based on the N-terminal amino-acid sequence of CLA was used to isolate the corresponding gene (cla), located near one end of the known cluster of penicillin and cephamycin biosynthetic genes, 5.7 kb downstream from the pcbC gene which encodes isopenicillin-N synthase. The sequence of cla would encode a protein of 313 aa with a high degree of similarity to amidinohydrolase enzymes. The cla gene is located immediately upstream from the previously described clavaminate synthase 2-encoding gene (cs2), and cla homologs were only present in streptomycetes which produced clavam compounds. Replacement of cla with a disrupted copy of the gene blocked the production of clavulanic acid in starch asparagine medium (SA).

The argG gene of Streptomyces clavuligerus has low homology to unstable argG from other actinomycetes: effect of amplification on clavulanic acid biosynthesis.

The argG gene of Streptomyces clavuligerus (Scl) has been cloned by complementation of argG mutants of Escherichia coli and S. lividans (Sl). The argG nucleotide (nt) sequence showed that it corresponds to a new type of argG different from the corresponding genes of S. coelicolor (Sco) and Sl. It encodes a 43,250-Da protein that showed higher similarity to argininosuccinate synthetases (ASS) from Methanococcus vannielii and Methanosarcina barkeri than to ASS deduced from other Streptomyces argG. No hybridization of the Scl argG was found with the homologous genes of Sl or Sco. The argH gene was located downstream from argG in Scl. The genomic region around argG and argH in Scl was different from the homologous regions in other Streptomyces and is not genetically unstable, unlike in Sco and Sl. Amplification of argG in transformant Scl[pULAR113] results in a 2.3-fold increase in the production of clavulanic acid (CA) in relation to the control strain Scl[pIJ699].

The biosynthetic genes for clavulanic acid and cephamycin production occur as a 'super-cluster' in three Streptomyces.

The cosmid cloning vector pHC79 has been used to clone fragments of chromosomal DNA from the Streptomyces: S. clavuligerus, S. jumonjinensis and S. katsurahamanus. These strains all produce both the beta-lactam antibiotic, cephamycin and the beta-lactamase inhibitor, clavulanic acid. Although structurally related these two beta-lactams are known to be derived from different biosynthetic precursors. Hybridisation studies and restriction mapping have shown that the gene clusters encoding the two biosynthetic pathways are chromosomally adjacent in these strains, thus creating a 'super-cluster' of genes involved in both the production and enhancement of activity of a beta-lactam antibiotic.

[Comparative characteristics of penicillin-binding proteins of representatives of the genus Streptomyces]. / Sravnitel'naia kharakteristika penitsillinsviazyvaiushchikh belkov predstavitelei roda Streptomyces.

Penicillin-binding proteins (PBPs) in Strepomyces strains producing clavulanic acid and beta-lactamase and in Streptomyces strains not producing these compounds were studied comparatively. In S. clavuligerus, the organism producing clavulanic acid, there were detected 3 PBPs in the membrane fraction. S. griseus, the organism producing beta-lactamase, contained 6 PBP. In S. cacaoi and S. olivaceus, organisms producing neither beta-lactams nor beta-lactamase, there were detected 5 and 4 PBP, respectively. The set of the PBP in the organism producing clavulanic acid varied during fermentation. In a variant of S. clavuligerus isolated after protoplasting of the mycelial cells and their regeneration the content of the electrophoretically most mobile PBP lowered. The PBP of S. clavuligerus did no show any high affinity to other beta-lactams such as methicillin and ampicillin tested as competing agents of 14C-benzylpenicillin.

[Various principles of detecting the producers of beta-lactamase inhibitors among soil Actinomycetes]. / O nekotorykh printsipakh vyiavleniia produtsentov ingibitorov beta-laktamaz sredi pochvennykh aktinomitsetov.

Principles of detecting organisms producing beta-lactamase inhibitors among soil actinomycetes were developed. For detecting such cultures it was recommended to use the Gauze agarized medium No. 1 supplemented with beta-lactam antibiotics. Benzylpenicillin proved to be the most efficient. Various liquid fermentation media for detecting the inhibitory activity of soil actinomycetes were compared. Two media were the most favourable i.e. the glucose-yeast medium No. 18/3 and the soybean-glucose medium with Na2SO4 and CoCl2 No. 20/3. The use of test cultures with relatively low resistance to benzylpenicillin was shown expedient in screening cultures producing beta-lactamase inhibitors. Test cultures with high resistance should be used in more detailed characterization of the selected cultures.

Recent advances in the biosynthesis of penicillins, cephalosporins and clavams and its regulation.

The beta-lactam antibiotics have been serving mankind for over 70 years. Despite this old age, they continue to provide health to the world population by virtue of industrial production and discoveries of new secondary metabolite molecules with useful activities. Sales of these remarkable compounds have reached over $20 billion dollars per year. They include penicillins, cephalosporins, cefoxitin, monobactams, clavulanic acid and carbapenems. Strain improvement of the penicillin-producing species of Penicillium has been truly remarkable, with present strains producing about 100,000 times more penicillin that the original Penicillium notatum of Alexander Fleming. A tremendous amount of information has been gathered on the biosynthetic enzymes involved, the pathways of biosynthesis of beta-lactams as well as their regulation, and the genomics and proteomics of the producing organisms. Modern aspects of the processes are discussed in the present review including genetics, molecular biology, metabolic engineering, genomics and proteomics.

Three unlinked gene clusters are involved in clavam metabolite biosynthesis in Streptomyces clavuligerus.

In Streptomyces clavuligerus, three groups of genes are known to be involved in the biosynthesis of the clavam metabolites. Since antibiotic biosynthetic genes are invariably clustered on the chromosome in prokaryotes, chromosome walking was undertaken in an attempt to show that the three groups of clavam genes would resolve into a single super-cluster when analyzed at larger scale. However, no evidence of linkage between the three groups was obtained. Furthermore, Southern analysis of macro-restriction fragments of genomic DNA separated by pulsed-field gel electrophoresis also indicated that the three groups of genes are not linked. Despite the structural and biosynthetic relatedness of the clavam metabolites, our results suggest that the genes involved in their production lie in three unlinked gene clusters. We believe that this represents the first instance in bacteria of genes involved in the biosynthesis of a single family of antibiotics sharing a common biosynthetic pathway and yet residing in three separate locations on the chromosome.

Elucidation of the order of oxidations and identification of an intermediate in the multistep clavaminate synthase reaction.

The enzyme clavaminate synthase (CS) catalyzes the formation of the first bicyclic intermediate in the biosynthetic pathway to the potent beta-lactamase inhibitor clavulanic acid. Our previous work has led to the proposal that the cyclization/desaturation of the substrate proclavaminate proceeds in two oxidative steps, each coupled to a decarboxylation of alpha-ketoglutarate and a reduction of dioxygen to water [Salowe, S. P., Marsh, E. N., & Townsend, C. A. (1990) Biochemistry 29, 6499-6508]. We have now employed kinetic isotope effect studies to determine the order of oxidations for CS purified from Streptomyces clavuligerus. By using (4'RS)-[4'-3H,1-14C]-rac-proclavaminate, a primary T(V/K) = 8.3 +/- 0.2 was measured from [3H]water release data, while an alpha-secondary T(V/K) = 1.06 +/- 0.01 was determined from the changing 3H/14C ratio of the product clavaminate. Values for the primary and alpha-secondary effects of 11.9 +/- 1.7 and 1.12 +/- 0.07, respectively, were obtained from the changing 3H/14C ratio of the residual proclavaminate by using new equations derived for a racemic substrate bearing isotopic label at both primary and alpha-secondary positions. Since only the first step of consecutive irreversible reactions will exhibit a V/K isotope effect, we conclude that C-4' is the initial site of oxidation in proclavaminate. As expected, no significant changes in the 3H/14C ratio of residual substrate were observed with [3-3H,1-14C]-rac-proclavaminate. However, two new tritiated compounds were produced in this incubation, apparently the result of isotope-induced branching brought about by the presence of tritium at the site of the second oxidation. One of these compounds was identified by comparison to authentic material as dihydroclavaminate, a stable intermediate that normally remains enzyme-bound. On the basis of the body of information available and the similarities to alpha-ketoglutarate-dependent dioxygenases, a comprehensive mechanistic scheme for CS is proposed to account for this unusual enzymatic transformation.

A regulatory gene (ccaR) required for cephamycin and clavulanic acid production in Streptomyces clavuligerus: amplification results in overproduction of both beta-lactam compounds.

A regulatory gene (ccaR), located within the cephamycin gene cluster of Streptomyces clavuligerus, is linked to a gene (blp) encoding a protein similar to a beta-lactamase-inhibitory protein. Expression of ccaR is required for cephamycin and clavulanic acid biosynthesis in S. clavuligerus. The ccaR-encoded protein resembles the ActII-ORF4, RedD, AfsR, and DnrI regulatory proteins of other Streptomyces species, all of which share several motifs. Disruption of ccaR by targeted double recombination resulted in the loss of the ability to synthesize cephamycin and clavulanic acid. Complementation of the disrupted mutant with ccaR restored production of both secondary metabolites. ccaR was expressed as a monocistronic transcript at 24 and 48 h in S. clavuligerus cultures (preceding the phase of antibiotic accumulation), but no transcript hybridization signals were observed at 72 or 96 h. This expression pattern is consistent with those of regulatory proteins required for antibiotic biosynthesis. Amplification of ccaR in S. clavuligerus resulted in a two- to threefold increase in the production of cephamycin and clavulanic acid.