Identification, cloning, sequencing, and overexpression of the gene encoding proclavaminate amidino hydrolase and characterization of protein function in clavulanic acid biosynthesis

Clavulanic Acid Production by Streptomyces clavuligerus: Insights from Systems Biology, Strain Engineering, and Downstream Processing

Clavulanic acid (CA) is an irreversible β-lactamase enzyme inhibitor with a weak antibacterial activity produced by Streptomyces clavuligerus (S. clavuligerus). CA is typically co-formulated with broad-spectrum β‑lactam antibiotics such as amoxicillin, conferring them high potential to treat diseases caused by bacteria that possess β‑lactam resistance. The clinical importance of CA and the complexity of the production process motivate improvements from an interdisciplinary standpoint by integrating metabolic engineering strategies and knowledge on metabolic and regulatory events through systems biology and multi-omics approaches. In the large-scale bioprocessing, optimization of culture conditions, bioreactor design, agitation regime, as well as advances in CA separation and purification are required to improve the cost structure associated to CA production. This review presents the recent insights in CA production by S. clavuligerus, emphasizing on systems biology approaches, strain engineering, and downstream processing.

A Genome-Scale Insight into the Effect of Shear Stress During the Fed-Batch Production of Clavulanic Acid by Streptomyces Clavuligerus

Streptomyces clavuligerus is a filamentous Gram-positive bacterial producer of the β-lactamase inhibitor clavulanic acid. Antibiotics biosynthesis in the Streptomyces genus is usually triggered by nutritional and environmental perturbations. In this work, a new genome scale metabolic network of Streptomyces clavuligerus was reconstructed and used to study the experimentally observed effect of oxygen and phosphate concentrations on clavulanic acid biosynthesis under high and low shear stress. A flux balance analysis based on experimental evidence revealed that clavulanic acid biosynthetic reaction fluxes are favored in conditions of phosphate limitation, and this is correlated with enhanced activity of central and amino acid metabolism, as well as with enhanced oxygen uptake. In silico and experimental results show a possible slowing down of tricarboxylic acid (TCA) due to reduced oxygen availability in low shear stress conditions. In contrast, high shear stress conditions are connected with high intracellular oxygen availability favoring TCA activity, precursors availability and clavulanic acid (CA) production.

Streptomyces clavuligerus shows a strong association between TCA cycle intermediate accumulation and clavulanic acid biosynthesis

Clavulanic acid (CA) is produced by Streptomyces clavuligerus (S. clavuligerus) as a secondary metabolite. Knowledge about the carbon flux distribution along the various routes that supply CA precursors would certainly provide insights about metabolic performance. In order to evaluate metabolic patterns and the possible accumulation of tricarboxylic acid (TCA) cycle intermediates during CA biosynthesis, batch and subsequent continuous cultures with steadily declining feed rates were performed with glycerol as the main substrate. The data were used to in silico explore the metabolic capabilities and the accumulation of metabolic intermediates in S. clavuligerus. While clavulanic acid accumulated at glycerol excess, it steadily decreased at declining dilution rates; CA synthesis stopped when glycerol became the limiting substrate. A strong association of succinate, oxaloacetate, malate, and acetate accumulation with CA production in S. clavuligerus was observed, and flux balance analysis (FBA) was used to describe the carbon flux distribution in the network. This combined experimental and numerical approach also identified bottlenecks during the synthesis of CA in a batch and subsequent continuous cultivation and demonstrated the importance of this type of methodologies for a more advanced understanding of metabolism; this potentially derives valuable insights for future successful metabolic engineering studies in S. clavuligerus.

Inversion of the stereochemical configuration (3S, 5S)-clavaminic acid into (3R, 5R)-clavulanic acid: A computationally-assisted approach based on experimental evidence

Clavulanic acid (CA), a potent inhibitor of β-lactamase enzymes, is produced by Streptomyces clavuligerus (Sc) cultivation processes, for which low yields are commonly obtained. Improved knowledge of the clavam biosynthetic pathway, especially the steps involved in the inversion of 3S-5S into 3R-5R stereochemical configuration, would help to eventually identify bottlenecks in the pathway. In this work, we studied the role of acetate in CA biosynthesis by a combined continuous culture and computational simulation approach. From this we derived a new model for the synthesis of N-acetyl-glycyl-clavaminic acid (NAG-clavam) by Sc. Acetylated compounds, such as NAG-clavam and N-acetyl-clavaminic acid, have been reported in the clavam pathway. Although the acetyl group is present in the β-lactam intermediate NAG-clavam, it is unknown how this group is incorporated. Hence, under the consideration of the experimentally proven accumulation of acetate during CA biosynthesis, and the fact that an acetyl group is present in the NAG-clavam structure, a computational evaluation of the tentative formation of NAG-clavam was performed for the purpose of providing further understanding. The proposed reaction mechanism consists of two steps: first, acetate reacts with ATP to produce a reactive acylphosphate intermediate; second, a direct nucleophilic attack of the terminal amino group of N-glycyl-clavaminic on the carbonyl carbon of the acylphosphate intermediate leads to a tetrahydral intermediate, which collapses and produces ADP and N-acetyl-glycyl-clavaminic acid. The calculations suggest that for the proposed reaction mechanism, the reaction proceeds until completion of the first step, without the direct action of an enzyme, where acetate and ATP are involved. For this step, the computed activation energy was ≅2.82kcal/mol while the reaction energy was ≅2.38kcal/mol. As this is an endothermic chemical process with a relatively small activation energy, the reaction rate should be considerably high. The calculations offered in this work should not be considered as a definite characterization of the potential energy surface for the reaction between acetate and ATP, but rather as a first approximation that provides valuable insight about the reaction mechanism. Finally, a complete route for the inversion of the stereochemical configuration from (3S, 5S)-clavaminic acid into (3R, 5R)-clavulanic acid is proposed, including a novel alternative for the double epimerization using proline racemase and NAG-clavam formation.

Identification and characterization of the carbapenem MM 4550 and its gene cluster in Streptomyces argenteolus ATCC 11009

Nearly 50 naturally occurring carbapenem β-lactam antibiotics, most produced by Streptomyces, have been identified. The structural diversity of these compounds is limited to variance of the C-2 and C-6 side chains as well as the stereochemistry at C-5/C-6. These structural motifs are of interest both for their antibiotic effects and their biosynthesis. Although the thienamycin gene cluster is the only active gene cluster publically available in this group, more comparative information is needed to understand the genetic basis of these structural differences. We report here the identification of MM 4550, a member of the olivanic acids, as the major carbapenem produced by Streptomyces argenteolus ATCC 11009. Its gene cluster was also identified by degenerate PCR and targeted gene inactivation. Sequence analysis revealed that the genes encoding the biosynthesis of the bicyclic core and the C-6 and C-2 side chains are well conserved in the MM 4550 and thienamycin gene clusters. Three new genes, cmmSu, cmm17 and cmmPah were found in the new cluster, and their putative functions in the sulfonation and epimerization of MM 4550 are proposed. Gene inactivation showed that, in addition to cmmI, two new genes, cmm22 and -23, encode a two-component response system thought to regulate the production of MM 4550. Overexpression of cmmI, cmm22 and cmm23 promoted MM 4550 production in an engineered strain. Finally, the involvement and putative roles of all genes in the MM 4550 cluster are proposed based on the results of bioinformatics analysis, gene inactivation, and analysis of disruption mutants. Overall, the differences between the thienamycin and MM 4550 gene clusters are reflected in characteristic structural elements and provide new insights into the biosynthesis of the complex carbapenems.

Biosynthesis of clavam metabolites

Naturally occurring clavam metabolites include the valuable β-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.

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.

ORF17 from the clavulanic acid biosynthesis gene cluster catalyzes the ATP-dependent formation of N-glycyl-clavaminic acid

(3R,5R)-Clavulanic acid, a clinically used inhibitor of serine beta-lactamases, is produced by fermentation of Streptomyces clavuligerus. The early steps in clavulanic acid biosynthesis leading to the bicyclic beta-lactam intermediate (3S,5S)-clavaminic acid have been defined. However, the mechanism by which (3S,5S)-clavaminic acid is converted to the penultimate intermediate (3R,5R)-clavaldehyde is unclear. Disruption of orf15 or orf16, of the clavulanic acid biosynthesis gene cluster, blocks clavulanic acid production and leads to the accumulation of N-acetyl-glycyl-clavaminic acid and N-glycyl-clavaminic acid, suggesting that these compounds are intermediates in the pathway. Two alternative start codons have been proposed for orf17 to encode for two possible polypeptides, one of which has 92 N-terminal residues less then the other. The shorter version of orf17 was successfully expressed in Escherichia coli and purified as a monomeric protein. Sequence analyses predicting the ORF17 protein to be a member of the ATP-grasp fold superfamily were supported by soft ionization mass spectrometric analyses that demonstrated binding of ATP to the ORF17 protein. Semisynthetic clavaminic acid, prepared by in vitro reconstitution of the biosynthetic pathway from the synthetically accessible intermediate proclavaminic acid, was shown by mass spectrometric analyses to be converted to N-glycyl-clavaminic acid in the presence of ORF17, ATP, and glycine. Under the same conditions N-acetyl-glycine and clavaminic acid were not converted to N-acetyl-glycyl-clavaminic acid. The specificity of ORF17 as an N-glycyl-clavaminic acid synthetase, together with the reported accumulation of N-glycyl-clavaminic acid in orf15 and orf16 disruption mutants, suggested that N-glycyl-clavaminic acid is an intermediate in clavulanic acid biosynthesis.

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.

Structure–function correlations in oxygen activating non-heme iron enzymes

A large group of mononuclear non-heme iron enzymes exist which activate dioxygen to catalyze key biochemical transformations, including many of medical, pharmaceutical and environmental significance. These enzymes utilize high-spin Fe(II) active sites and additional reducing equivalents from cofactors or substrates to react with O2 to yield iron-oxygen intermediates competent to transform substrate to product. While Fe(II) sites have been difficult to study due to the lack of dominant spectroscopic features, a spectroscopic methodology has been developed which allows the elucidation of the geometric and electronic structures of these active sites and provides molecular level insight into the mechanisms of catalysis. This review provides a summary of this methodology with emphasis on its application to the determination of important active site structure-function correlations in mononuclear non-heme iron enzymes. These studies provide key insight into the mechanisms of oxygen activation, active site features that contribute to differences in reactivity and, combined with theoretical calculations and model studies, the nature of oxygen intermediates active in catalysis.

The paralogous pairs of genes involved in clavulanic acid and clavam metabolite biosynthesis are differently regulated in Streptomyces clavuligerus

Carboxyethylarginine synthase, encoded by the paralogous ceaS1 and ceaS2 genes, catalyzes the first reaction in the shared biosynthetic pathway leading to clavulanic acid and the other clavam metabolites in Streptomyces clavuligerus. The nutritional regulation of ceaS1 and ceaS2 expression was analyzed by reverse transcriptase PCR and by the use of the enhanced green fluorescent protein-encoding gene (egfp) as a reporter. ceaS1 was transcribed in complex soy medium only, whereas ceaS2 was transcribed in both soy and defined starch-asparagine (SA) media. The transcriptional start points of the two genes were also mapped to a C residue 98 bp upstream of ceaS1 and a G residue 51 bp upstream of the ceaS2 start codon by S1 nuclease protection and primer extension analyses. Furthermore, transcriptional mapping of the genes encoding the beta-lactam synthetase (bls1) and proclavaminate amidinohydrolase (pah1) isoenzymes from the paralogue gene cluster indicated that a single polycistronic transcript of approximately 4.9 kb includes ceaS1, bls1, and pah1. The expression of ceaS1 and ceaS2 in a mutant strain defective in the regulatory protein CcaR was also examined. ceaS1 transcription was not affected in the ccaR mutant, whereas that of ceaS2 was greatly reduced compared to the wild-type strain. Overall, our results suggest that different mechanisms are involved in regulating the expression of ceaS1 and ceaS2, and presumably also of other paralogous genes that encode proteins involved in the early stages of clavulanic acid and clavam metabolite biosynthesis.

Two oligopeptide-permease-encoding genes in the clavulanic acid cluster of Streptomyces clavuligerus are essential for production of the beta-lactamase inhibitor

orf7 (oppA1) and orf15 (oppA2) are located 8 kb apart in the clavulanic acid gene cluster of Streptomyces clavuligerus and encode proteins which are 48.0% identical. These proteins show sequence similarity to periplasmic oligopeptide-binding proteins. Mutant S. clavuligerus oppA1::acc, disrupted in oppA1, lacks clavulanic acid production. Clavulanic acid production is restored by transformation with plasmid pIJ699-oppA1, which carries oppA1, but not with the multicopy plasmid pIJ699-oppA2, which carries oppA2. The mutant S. clavuligerus oppA2::aph also lacks clavulanic acid production, shows a bald phenotype, and overproduces holomycin (5). Clavulanic acid production at low levels is restored in the oppA2-disrupted mutants by transformation with plasmid pIJ699-oppA2, but it is not complemented by the multicopy plasmid pIJ699-oppA1. Both genes encode oligopeptide permeases with different substrate specificities. The disrupted S. clavuligerus oppA2::aph is not able to grow on RPPGFSPFR (Arg-Pro-Pro-Gly-Phe-Ser-Pro-Phe-Arg; bradykinin), but both mutants grow on VAPG (Val-Ala-Pro-Gly) as the only nitrogen source, indicating differences in the peptide bound by the proteins encoded by both genes. The null S. clavuligerus oppA1::acc and S. clavuligerus oppA2::aph mutants are more resistant to the toxic tripeptide phosphinothricyl-alanyl-alanine (also named bialaphos) than the wild-type strain, suggesting that this peptide might be transported by these peptide-binding proteins.

Streptomyces clavuligerus has a second copy of the proclavaminate amidinohydrolase gene

Past genetic studies have indicated that the genes encoding early enzymes of clavulanic acid biosynthesis may be duplicated in Streptomyces clavuligerus. We observed cross-hybridizing bands upon Southern analyses of proclavaminate amidinohydrolase (pah)-defective mutant strains of S. clavuligerus screened with a pah-specific probe. The DNA fragment responsible for this cross hybridization was cloned and sequenced and shown to encode a second copy of the pah gene. The new pah gene (pah1) was 1,056 bp in length, and its sequence was 72% identical to that of the original pah gene (pah2). Disruption mutants with defects in pah1 showed no significant effects on production of clavulanic acid or any of the clavam metabolites with stereochemistries opposite that of clavulanic acid (5S clavams) produced by S. clavuligerus when they were grown on starch asparagine or soy medium. However, double mutants with defects in both pah1 and pah2 were defective in the production of both clavulanic acid and all of the 5S clavam metabolites.

Five additional genes are involved in clavulanic acid biosynthesis in Streptomyces clavuligerus

An approximately 12.5-kbp region of DNA sequence from beyond the end of the previously described clavulanic acid gene cluster was analyzed and found to encode nine possible open reading frames (ORFs). Involvement of these ORFs in clavulanic acid biosynthesis was assessed by creating mutants with defects in each of the ORFs. orf12 and orf14 had been previously reported to be involved in clavulanic acid biosynthesis. Now five additional ORFs are shown to play a role, since their mutation results in a significant decrease or total absence of clavulanic acid production. Most of these newly described ORFs encode proteins with little similarity to others in the databases, and so their roles in clavulanic acid biosynthesis are unclear. Mutation of two of the ORFs, orf15 and orf16, results in the accumulation of a new metabolite, N-acetylglycylclavaminic acid, in place of clavulanic acid. orf18 and orf19 encode apparent penicillin binding proteins, and while mutations in these genes have minimal effects on clavulanic acid production, their normal roles as cell wall biosynthetic enzymes and as targets for beta-lactam antibiotics, together with their clustered location, suggest that they are part of the clavulanic acid gene cluster.

Crystal Structure and Mechanistic Implications of N2-(2-Carboxyethyl)arginine Synthase, the First Enzyme in the Clavulanic Acid Biosynthesis Pathway

The initial step in the biosynthesis of the clinically important beta-lactamase inhibitor clavulanic acid involves condensation of two primary metabolites, D-glyceraldehyde 3-phosphate and L-arginine, to give N2-(2-carboxyethyl)arginine, a beta-amino acid. This unusual N-C bond forming reaction is catalyzed by the thiamin diphosphate (ThP2)-dependent enzyme N2-(2-carboxyethyl)arginine synthase. Here we report the crystal structure of N2-(2-carboxyethyl)arginine synthase, complexed with ThP2 and Mg2+, to 2.35-A resolution. The structure was solved in two space groups, P2(1)2(1)2(1) and P2(1)2(1)2. In both, the enzyme is observed in a tetrameric form, composed of a dimer of two more tightly associated dimers, consistent with both mass spectrometric and gel filtration chromatography studies. Both ThP2 and Mg2+ cofactors are present at the active site, with ThP2 in a "V" conformation as in related enzymes. A sulfate anion is observed in the active site of the enzyme in a location proposed as a binding site for the phosphate group of the d-glyceraldehyde 3-phosphate substrate. The mechanistic implications of the active site arrangement are discussed, including the potential role of the aminopyrimidine ring of the ThP2. The structure will form a basis for future mechanistic and structural studies, as well as engineering aimed at production of alternative beta-amino acids.

New reactions in clavulanic acid biosynthesis

Clavulanic acid is only a modestly effective antibiotic against bacterial infections in humans, but a potent inhibitor/inactivator of beta-lactamase enzymes that confer bacterial resistance. The biosynthetic pathway to clavulanic acid is considerably more complex than that to the structurally related penicillins and cephalosporins and has revealed several interesting reactions.

Oligomeric structure of proclavaminic acid amidino hydrolase: evolution of a hydrolytic enzyme in clavulanic acid biosynthesis

During biosynthesis of the clinically used beta-lactamase inhibitor clavulanic acid, one of the three steps catalysed by clavaminic acid synthase is separated from the other two by a step catalysed by proclavaminic acid amidino hydrolase (PAH), in which the guanidino group of an intermediate is hydrolysed to give proclavaminic acid and urea. PAH shows considerable sequence homology with the primary metabolic arginases, which hydrolyse arginine to ornithine and urea, but does not accept arginine as a substrate. Like other members of the bacterial sub-family of arginases, PAH is hexameric in solution and requires Mn2+ ions for activity. Other metal ions, including Co2+, can substitute for Mn2+. Two new substrates for PAH were identified, N-acetyl-(L)-arginine and (3R)-hydroxy-N-acetyl-(L)-arginine. Crystal structures of PAH from Streptomyces clavuligerus (at 1.75 A and 2.45 A resolution, where 1 A=0.1 nm) imply how it binds beta-lactams rather than the amino acid substrate of the arginases from which it evolved. The structures also suggest how PAH selects for a particular alcohol intermediate in the clavam biosynthesis pathway. As observed for the arginases, each PAH monomer consists of a core of beta-strands surrounded by alpha-helices, and its active site contains a di-Mn2+ centre with a bridging water molecule responsible for hydrolytic attack on to the guanidino group of the substrate. Comparison of structures obtained under different conditions reveals different conformations of a flexible loop, which must move to allow substrate binding.

The clavulanic acid biosynthetic cluster of Streptomyces clavuligerus: genetic organization of the region upstream of the car gene

The genetic organization of the region upstream of the car gene of the clavulanic acid biosynthetic gene cluster of Streptomyces clavuligerus has been determined. Sequence analysis of a 12.1 kb region revealed the presence of 10 ORFs whose putative functions, according to database searches, are discussed. Three co-transcriptional units are proposed: ORF10-11, ORF12-13 and ORF15-16-17-18. Potential transcriptional terminators were identified downstream of ORF11 (fd) and ORF15. Targeted disruption of ORF10 (cyp) gave rise to transformants unable to produce clavulanic acid, but with a considerably higher production of cephamycin C. Transformants inactivated at ORF14 had a remarkably lower production of clavulanic acid and similar production of cephamycin C. Significant improvements of clavulanic acid production, associated with a drop in cephamycin C biosynthesis, were obtained with transformants of S. clavuligerus harbouring multiple copies of plasmids carrying different constructions from the ORF10-14 region. This information can be used to guide strain improvement programs, blending random mutagenesis and molecular cloning, to optimize the yield of clavulanic acid.

Expansion of the clavulanic acid gene cluster: identification and in vivo functional analysis of three new genes required for biosynthesis of clavulanic acid by Streptomyces clavuligerus

Clavulanic acid is a potent inhibitor of beta-lactamase enzymes and is of demonstrated value in the treatment of infections by beta-lactam-resistant bacteria. Previously, it was thought that eight contiguous genes within the genome of the producing strain Streptomyces clavuligerus were sufficient for clavulanic acid biosynthesis, because they allowed production of the antibiotic in a heterologous host (K. A. Aidoo, A. S. Paradkar, D. C. Alexander, and S. E. Jensen, p. 219-236, In V. P. Gullo et al., ed., Development in industrial microbiology series, 1993). In contrast, we report the identification of three new genes, orf10 (cyp), orf11 (fd), and orf12, that are required for clavulanic acid biosynthesis as indicated by gene replacement and trans-complementation analysis in S. clavuligerus. These genes are contained within a 3.4-kb DNA fragment located directly downstream of orf9 (cad) in the clavulanic acid cluster. While the orf10 (cyp) and orf11 (fd) proteins show homologies to other known CYP-150 cytochrome P-450 and [3Fe-4S] ferredoxin enzymes and may be responsible for an oxidative reaction late in the pathway, the protein encoded by orf12 shows no significant similarity to any known protein. The results of this study extend the biosynthetic gene cluster for clavulanic acid and attest to the importance of analyzing biosynthetic genes in the context of their natural host. Potential functional roles for these proteins are proposed.

Enzymes catalyzing the early steps of clavulanic acid biosynthesis are encoded by two sets of paralogous genes in Streptomyces clavuligerus

Genes encoding the proteins required for clavulanic acid biosynthesis and for cephamycin biosynthesis are grouped into a "supercluster" in Streptomyces clavuligerus. Nine open reading frames (ORFs) associated with clavulanic acid biosynthesis were located in a 15-kb segment of the supercluster, including six ORFs encoding known biosynthetic enzymes or regulatory proteins, two ORFs that have been reported previously but whose involvement in clavulanic acid biosynthesis is unclear, and one ORF not previously reported. Evidence for the involvement of these ORFs in clavulanic acid production was obtained by generating mutants and showing that all were defective for clavulanic acid production when grown on starch asparagine medium. However, when five of the nine mutants, including mutants defective in known clavulanic acid biosynthetic enzymes, were grown in a soy-based medium, clavulanic acid-producing ability was restored. This ability to produce clavulanic acid when seemingly essential biosynthetic enzymes have been mutated suggests that paralogous genes encoding functionally equivalent proteins exist for each of the five genes but that these paralogues are expressed only in the soy-based medium. The five genes that have paralogues encode proteins involved in the early steps of the pathway common to the biosynthesis of both clavulanic acid and the other clavam metabolites produced by this organism. No evidence was seen for paralogues of the four remaining genes involved in late, clavulanic acid-specific steps in the pathway.

Genes specific for the biosynthesis of clavam metabolites antipodal to clavulanic acid are clustered with the gene for clavaminate synthase 1 in Streptomyces clavuligerus

Portions of the Streptomyces clavuligerus chromosome flanking cas1, which encodes the clavaminate synthase 1 isoenzyme (CAS1), have been cloned and sequenced. Mutants of S. clavuligerus disrupted in cvm1, the open reading frame located immediately upstream of cas1, were constructed by a gene replacement procedure. Similar techniques were used to generate S. clavuligerus mutants carrying a deletion that encompassed portions of the two open reading frames, cvm4 and cvm5, located directly downstream of cas1. Both classes of mutants still produced clavulanic acid and cephamycin C but lost the ability to synthesize the antipodal clavam metabolites clavam-2-carboxylate, 2-hydroxymethyl-clavam, and 2-alanylclavam. These results suggested that cas1 is clustered with genes essential and specific for clavam metabolite biosynthesis. When a cas1 mutant of S. clavuligerus was constructed by gene replacement, it produced lower levels of both clavulanic acid and most of the antipodal clavams except for 2-alanylclavam. However, a double mutant of S. clavuligerus disrupted in both cas1 and cas2 produced neither clavulanic acid nor any of the antipodal clavams, including 2-alanylclavam. This outcome was consistent with the contribution of both CAS1 and CAS2 to a common pool of clavaminic acid that is shunted toward clavulanic acid and clavam metabolite biosynthesis.

beta-Lactam synthetase: a new biosynthetic enzyme

The principal cause of bacterial resistance to penicillin and other beta-lactam antibiotics is the acquisition of plasmid-encoded beta-lactamases, enzymes that catalyze hydrolysis of the beta-lactam bond and render these antibiotics inactive. Clavulanic acid is a potent inhibitor of beta-lactamases and has proven clinically effective in combating resistant infections. Although clavulanic acid and penicillin share marked structural similarities, the biosyntheses of their bicyclic nuclei are wholly dissimilar. In contrast to the efficient iron-mediated oxidative cyclization of a tripeptide to isopenicillin N, the critical beta-lactam ring of clavulanic acid is demonstrated to form by intramolecular closure catalyzed by a new type of ATP/Mg2+-dependent enzyme, a beta-lactam synthetase (beta-LS). Insertional inactivation of its encoding gene in wild-type Streptomyces clavuligerus resulted in complete loss of clavulanic acid production and the accumulation of N2-(carboxyethyl)-L-arginine (CEA). Chemical complementation of this blocked mutant with authentic deoxyguanidinoproclavaminic acid (DGPC), the expected product of the beta-LS, restored clavulanic acid synthesis. Finally, overexpression of this gene gave the beta-LS, which was shown to mediate the conversion of CEA to DGPC in the presence of ATP/Mg2+. Primary amino acid sequence comparisons suggest that this mode of beta-lactam formation could be more widely spread in nature and mechanistically related to asparagine synthesis.

Investigation of the Streptomyces clavuligerus cephamycin C gene cluster and its regulation by the CcaR protein

As part of a search for transcriptional regulatory genes, sequence analysis of several previously unsequenced gaps in the cephamycin biosynthetic cluster has revealed the presence in Streptomyces clavuligerus of seven genes not previously described. These include genes encoding an apparent penicillin binding protein and a transport or efflux protein, as well as the CmcI and CmcJ proteins, which catalyze late reactions in the cephamycin biosynthetic pathway. In addition, we discovered a gene, designated pcd, which displays significant homology to genes encoding semialdehyde dehydrogenases and may represent the gene encoding the long-sought-after dehydrogenase involved in the conversion of lysine to alpha-aminoadipate. Finally, two genes, sclU and rhsA, with no obvious function in cephamycin biosynthesis may define the end of the cluster. The previously described CcaR protein displays homology to a number of Streptomyces pathway-specific transcriptional activators. The ccaR gene was shown to be essential for the biosynthesis of cephamycin, clavulanic acid, and non-clavulanic acid clavams. Complementation of a deletion mutant lacking ccaR and the adjacent orf11 and blp genes showed that only ccaR was essential for the biosynthesis of cephamycin, clavulanic acid, and clavams and that mutations in orf11 or blp had no discernible effects. The lack of cephamycin production in ccaR mutants was directly attributable to the absence of biosynthetic enzymes responsible for the early and middle steps of the cephamycin biosynthetic pathway. Complementation of the ccaR deletion mutant resulted in the return of these biosynthetic enzymes and the restoration of cephamycin production.

A pathway-specific transcriptional activator regulates late steps of clavulanic acid biosynthesis in Streptomyces clavuligerus

A Streptomyces clavuligerus gene (designated claR) located downstream from the gene encoding clavaminate synthase in the clavulanic acid biosynthetic gene cluster is involved in regulation of the late steps in clavulanic acid biosynthesis. Nucleotide sequence analysis and database searching of ClaR identified a significant similarity to the helix-turn-helix motif (HTH) region of LysR transcriptional regulators. A gene replacement mutant disrupted in claR was unable to produce clavulanic acid, suggesting that claR is essential for clavulanic acid biosynthesis. Furthermore, the accumulation of clavaminic acid in the claR mutant suggested that ClaR regulates the late steps in the clavulanic acid pathway, i.e. those involved in the conversion of clavaminic acid to clavulanic acid. Transcriptional analysis using RNA isolated from the wild type and the claR mutant showed that the expression of the putative late genes, but not the early genes, was regulated by ClaR. High-resolution S1 nuclease analysis of claR suggested that it is expressed as a monocistronic transcript and also as a bicistronic transcript along with the late gene orf-9. The transcription start site of the monocistronic claR transcript was identified as a C residue 155 nucleotides upstream from the claR start codon.

Roles of conserved residues in the arginase family

Arginases and related enzymes metabolize arginine or similar nitrogen-containing compounds to urea or formamide. In the present report a sequence alignment of 31 members of this family was generated. The alignment, together with the crystal structure of rat liver arginase, allowed the assignment of possible functional or structural roles to 32 conserved residues and conservative substitutions. Two of these residues were previously identified as functionally essential by analysis of inherited defects in the type I arginase gene. Nearly half of the conserved residues are either glycines or prolines located at critical bends in the protein structure. Most metal-coordinating residues, including one histidine and four aspartic acid residues, are strictly conserved. Two additional histidines involved in metal-binding and catalysis are conserved in all arginases and in almost all other family members. Two positions with invariant similarities may serve as indirect metal ligands. Evolutionary relationships within this family were also suggested. Vertebrate type I and II arginases appear to have developed independently from an early gene duplication event. A ureohydrolase sequence from Caenorhabditis elegans is more closely related to other arginases than previously appreciated, while unclassified enzymes from Methanococcus jannaschii and Methanothermus fervidus appear more similar to arginase-related enzymes. In addition, enzymes from Arabidopsis thaliana and Synechocystis, previously identified as arginases, more closely resemble arginase-related enzymes than currently known arginases.

The universal stress protein, UspA, of Escherichia coli is phosphorylated in response to stasis

Transcriptional induction of the uspA gene of Escherichia coli occurs whenever conditions cause growth arrest and cells deficient in UspA survive poorly in stationary phase. We demonstrate that the product of uspA is a serine and threonine phosphoprotein. In vivo, three isoforms of UspA were detected, two of which were phosphorylated as determined by alkaline phosphatase treatment; in vitro, phosphorylation with [gamma-32P]ATP yielded two radioactive UspA isoforms. The phosphorylated isoforms were barely visible in growing cells but one increased during starvation conditions causing growth arrest. This phosphorylation is dependent on the o591 gene, which encodes an autophosphorylating tyrosine phosphoprotein and which is involved in the synthesis or modification of six other proteins. In vitro, UspA undergoes a rapid and dynamic autophosphorylation, as shown by chase experiments with GTP or ATP as phosphate donors.

A single monomeric iron center in clavaminate synthase catalyzes three nonsuccessive oxidative transformations

The trifunctional oxygenase clavaminate synthase 2 (CS2) catalyses a hydroxylation reaction and two coupled oxidative reactions, a cyclization and a desaturation, in a nonsuccessive manner. A series of experiments was performed to elucidate the number of CS2 catalytic site(s) utilized in the three oxidative transformations. The stoichiometry of FeII required by CS2 was determined to be one ion per catalytically active enzyme molecule for the cyclization/desaturation reactions, and an affinity label, modeled after the substrate for the hydroxylation reaction, was synthesized and effectively inactivated CS2. The kinetics of this process showed concentration dependence and substrate protection consistent with active site direction. In addition, when this affinity label was incubated with CS2, the enzyme showed the same first-order rate of activity loss over time in both the hydroxylation activity assay and the cyclization/desaturation activity assay. These results support the view that all of the reactions catalysed by CS2 occur in a single catalytic site containing one FeII.