Gene cluster containing the genes for tyrocidine synthetases 1 and 2 from Bacillus brevis: evidence for an operon

Nonribosomal peptide synthetase biosynthetic clusters of ESKAPE pathogens

Covering: up to 2017.Natural products are important secondary metabolites produced by bacterial and fungal species that play important roles in cellular growth and signaling, nutrient acquisition, intra- and interspecies communication, and virulence. A subset of natural products is produced by nonribosomal peptide synthetases (NRPSs), a family of large, modular enzymes that function in an assembly line fashion. Because of the pharmaceutical activity of many NRPS products, much effort has gone into the exploration of their biosynthetic pathways and the diverse products they make. Many interesting NRPS pathways have been identified and characterized from both terrestrial and marine bacterial sources. Recently, several NRPS pathways in human commensal bacterial species have been identified that produce molecules with antibiotic activity, suggesting another source of interesting NRPS pathways may be the commensal and pathogenic bacteria that live on the human body. The ESKAPE pathogens (Enterococcus faecium, Staphylococcus aureus, Klebsiella pneumoniae, Acinetobacter baumannii, Pseudomonas aeruginosa, and Enterobacter spp.) have been identified as a significant cause of human bacterial infections that are frequently multidrug resistant. The emerging resistance profile of these organisms has prompted calls from multiple international agencies to identify novel antibacterial targets and develop new approaches to treat infections from ESKAPE pathogens. Each of these species contains several NRPS biosynthetic gene clusters. While some have been well characterized and produce known natural products with important biological roles in microbial physiology, others have yet to be investigated. This review catalogs the NRPS pathways of ESKAPE pathogens. The exploration of novel NRPS products may lead to a better understanding of the chemical communication used by human pathogens and potentially to the discovery of novel therapeutic approaches.

Crosslinking studies of protein-protein interactions in nonribosomal peptide biosynthesis

Selective protein-protein interactions between nonribosomal peptide synthetase (NRPS) proteins, governed by communication-mediating (COM) domains, are responsible for proper translocation of biosynthetic intermediates to produce the natural product. In this study, we developed a crosslinking assay, utilizing bioorthogonal probes compatible with carrier protein modification, for probing the protein interactions between COM domains of NRPS enzymes. Employing the Huisgen 1,3-dipolar cycloaddition of azides and alkynes, we examined crosslinking of cognate NRPS modules within the tyrocidine pathway and demonstrated the sensitivity of our panel of crosslinking probes toward the selective protein interactions of compatible COM domains. These studies indicate that copper-free crosslinking substrates uniquely offer a diagnostic probe for protein-protein interactions. Likewise, these crosslinking probes serve as ideal chemical tools for structural studies between NRPS modules where functional assays are lacking.

Nonribosomal peptide synthetases involved in the production of medically relevant natural products

Natural products biosynthesized wholly or in part by nonribosomal peptide synthetases (NRPSs) are some of the most important drugs currently used clinically for the treatment of a variety of diseases. Since the initial research into NRPSs in the early 1960s, we have gained considerable insights into the mechanism by which these enzymes assemble these natural products. This review will present a brief history of how the basic mechanistic steps of NRPSs were initially deciphered and how this information has led us to understand how nature modified these systems to generate the enormous structural diversity seen in nonribosomal peptides. This review will also briefly discuss how drug development and discovery are being influenced by what we have learned from nature about nonribosomal peptide biosynthesis.

Biosynthesis of the 2-Pyridone Tenellin in the Insect Pathogenic FungusBeauveria bassiana

Genomic DNA from the insect pathogenic fungus Beauveria bassiana was used as a template in a PCR with degenerate primers designed to amplify a fragment of a C-methyl transferase (CMeT) domain from a highly reduced fungal polyketide synthase (PKS). The resulting 270-bp PCR product was homologous to other fungal PKS CMeT domains and was used as a probe to isolate a 7.3-kb fragment of genomic DNA from a BamH1 library. Further library probing and TAIL-PCR then gave a 21.9-kb contig that encoded a 12.9-kb fused type I PKS-NRPS ORF together with ORFs encoding other oxidative and reductive enzymes. A directed knockout experiment with a BaR cassette, reported for the first time in B. bassiana, identified the PKS-NRPS as being involved in the biosynthesis of the 2-pyridone tenellin. Other fungal PKS-NRPS genes are known to be involved in the formation of tetramic acids in fungi, and it thus appears likely that related compounds are precursors of 2-pyridones in fungi. B. bassiana tenellin KO and WT strains proved to be equally pathogenic towards insect larvae; this indicated that tenellin is not involved in insect pathogenesis.

The sypA, sypS, and sypC synthetase genes encode twenty-two modules involved in the nonribosomal peptide synthesis of syringopeptin by Pseudomonas syringae pv. syringae B301D

Syringopeptin is a necrosis-inducing phytotoxin, composed of 22 amino acids attached to a 3-hydroxy fatty acid tail. Syringopeptin, produced by Pseudomonas syringae pv. syringae, functions as a virulence determinant in the plant-pathogen interaction. A 73,800-bp DNA region was sequenced, and analysis identified three large open reading frames, sypA, sypB, and sypC, that are 16.1, 16.3, and 40.6 kb in size. Sequence analysis of the putative SypA, SypB, and SypC sequences determined that they are homologous to peptide synthetases, containing five, five, and twelve amino acid activation modules, respectively. Each module exhibited characteristic domains for condensation, aminoacyl adenylation, and thiolation. Within the aminoacyl adenylation domain is a region responsible for substrate specificity. Phylogenetic analysis of the substrate-binding pockets resulted in clustering of the 22 syringopeptin modules into nine groups. This clustering reflects the substrate amino acids predicted to be recognized by each of the respective modules based on placement of the syringopeptin NRPS (nonribosomal peptide synthetase) system in the linear (type A) group. Finally, SypC contains two C-terminal thioesterase domains predicted to catalyze the release of syringopeptin from the synthetase and peptide cyclization to form the lactone ring. The syringopeptin synthetases, which carry 22 NRPS modules, represent the largest linear NRPS system described for a prokaryote.

Non-ribosomal peptide synthetases as technological platforms for the synthesis of highly modified peptide bioeffectors – Cyclosporin synthetase as a complex example

Many microbial peptide secondary metabolites possess important medicinal properties, of which the immunosuppressant cyclosporin A is an example. The enormous structural and functional diversity of these low-molecular weight peptides is attributable to their mode of biosynthesis. Peptide secondary metabolites are assembled non-ribosomally by multi-functional enzymes, termed non-ribosomal peptide synthetases. These systems consist of a multi-modular arrangement of the functional domains responsible for the catalysis of the partial reactions of peptide assembly. The extensive homology shared among NRPS systems allows for the generalisation of the knowledge garnered from studies of systems of diverse origins. In this review we shall focus the contemporary knowledge of non-ribosomal peptide biosynthesis on the structure and function of the cyclosporin biosynthetic system, with some emphasis on the re-direction of the biosynthetic potential of this system by combinatorial approaches.

The first gene in the biosynthesis of the polyketide antibiotic TA of Myxococcus xanthus codes for a unique PKS module coupled to a peptide synthetase

The polyketide antibiotic TA is synthesized by the Gram negative bacterium Myxococcus xanthus in a multi-step process in which a unique glycine-derived molecule is used as a starter unit and elongated through the condensation of 11 acetate molecules by polyketide synthases (PKSs). Analysis of a 7.2 kb DNA fragment, encoding the protein that carries out the first condensation step, revealed that the fragment constitutes a single open reading frame, referred to as Ta1, which lacks the 5' and 3' ends and displays two regions of similarity to other proteins. The first 1020 amino acid residues at the N terminus of the polypeptide are similar to sequences of the large family of enzymes encoding peptide synthetases. They are followed by a second region displaying a high degree of similarity to type I PKS genes. The genetic analysis of this open reading frame is compatible with the proposed chemical structure of TA. The data indicate that the genes encoding TA have a modular gene organization, typical of a type I PKS system. The unusual feature of Ta1 is that the first PKS module of TA resides on the same polypeptide as the peptide synthetase functional unit.

A putative lichenysin A synthetase operon in Bacillus licheniformis: initial characterization

Certain Bacillus licheniformis strains isolated from oil wells have been shown to produce a very effective biosurfactant, lichenysin A, which is structurally similar to another less active lipopeptide, surfactin. Surfactin, like many small peptides in prokaryotes and lower eukaryotes, is synthesized non-ribosomally by multi-enzyme peptide synthetase complex. Analysis of several peptide synthetases of bacterial and fungal origin has revealed a high degree of sequence conservation. Two 35-mer oligonucleotides derived from highly conserved motifs ('core I' and 'core II') of surfactin synthetase were used to identify the cloned putative operon of lichenysin A synthetase lchA from B. licheniformis BNP29, a strain not amenable to genetic manipulation in a BAC system (F-plasmid-based bacterial artificial chromosome) based on Escherichia coli and its single-copy plasmid F-factor. A 32.4 kb fragment containing lichenysin A biosynthesis locus was sequenced and analysed. The structural architecture of putative lichenysin A synthetase protein containing seven amino acid (aa) activation-thiolation, two epimerization and one thioesterase domains is discussed in terms of its similarity to surfactin and other peptide synthetases. The 100 aa peptide chain situated between the highly conserved signature sequences FDXX and NXYGPTE(IV)X within amino acid binding domains of peptide synthetases is proposed to be a minimal block dictating the substrate specificity of the enzymes. A new operon-type structure has been localized directly upstream from the lichenysin A synthetase genes which, on the basis of sequence determination, potentially encode a four-member ABC-type transport system involved in product secretion.

The bacitracin biosynthesis operon of Bacillus licheniformis ATCC 10716: molecular characterization of three multi-modular peptide synthetases

BACKGROUND

The branched cyclic dodecylpeptide antibiotic bacitracin, produced by special strains of Bacillus, is synthesized nonribosomally by a large multienzyme complex composed of the three bacitracin synthetases BA1, BA2 and BA3. These enzymes activate and incorporate the constituent amino acids of bacitracin by a thiotemplate mechanism in a pathway driven by a protein template. The biochemical features of these enzymes have been studied intensively but little is known about the molecular organization of their genes.

RESULTS

The entire bacitracin synthetase operon containing the genes bacA-bacC was cloned and sequenced, identifying a modular structure typical of peptide synthetases. The bacA gene product (BA1, 598kDa) contains five modules, with an internal epimerization domain attached to the fourth; bacB encodes BA2 (297kDa), and has two modules and a carboxy-terminal epimerization domain; bacC encodes BA3, five modules (723kDa) with additional internal epimerization domains attached to the second and fourth. A carboxy-terminal putative thioesterase domain was also detected in BA3. A putative cyclization domain was found in BA1 that may be involved in thiazoline ring formation. The adenylation/thioester-binding domains of the first two BA1 modules were overproduced and the detected amino-acid specificity coincides with the first two amino acids in bacitracin. Disruption of chromosomal bacB resulted in a bacitracin-deficient mutant.

CONCLUSIONS

The genes encoding the bacitracin synthetases BA1, BA2 and BA3 are organized in an operon, the structure of which reflects the modular architecture expected of peptide synthetases. In addition, a putative thiazoline ring formation domain was identified in the BA1 gene.

The tyrocidine biosynthesis operon of Bacillus brevis: complete nucleotide sequence and biochemical characterization of functional internal adenylation domains

The cyclic decapeptide antibiotic tyrocidine is produced by Bacillus brevis ATCC 8185 on an enzyme complex comprising three peptide synthetases, TycA, TycB, and TycC (tyrocidine synthetases 1, 2, and 3), via the nonribosomal pathway. However, previous molecular characterization of the tyrocidine synthetase-encoding operon was restricted to tycA, the gene that encodes the first one-module-bearing peptide synthetase. Here, we report the cloning and sequencing of the entire tyrocidine biosynthesis operon (39.5 kb) containing the tycA, tycB, and tycC genes. As deduced from the sequence data, TycB (404,562 Da) consists of three modules, including an epimerization domain, whereas TycC (723,577 Da) is composed of six modules and harbors a putative thioesterase domain at its C-terminal end. Each module incorporates one amino acid into the peptide product and can be further subdivided into domains responsible for substrate adenylation, thiolation, condensation, and epimerization (optional). We defined, cloned, and expressed in Escherichia coli five internal adenylation domains of TycB and TycC. Soluble His6-tagged proteins, ranging from 536 to 559 amino acids, were affinity purified and found to be active by amino acid-dependent ATP-PPi exchange assay. The detected amino acid specificities of the investigated domains manifested the colinear arrangement of the peptide product with the respective module in the corresponding peptide synthetases and explain the production of the four known naturally occurring tyrocidine variants. The Km values of the investigated adenylation domains for their amino acid substrates were found to be comparable to those published for undissected wild-type enzymes. These findings strongly support the functional integrities of single domains within multifunctional peptide synthetases. Directly downstream of the 3' end of the tycC gene, and probably transcribed in the tyrocidine operon, two tandem ABC transporters, which may be involved in conferring resistance against tyrocidine, and a putative thioesterase were found.

The tyrocidine biosynthesis operon of Bacillus brevis: complete nucleotide sequence and biochemical characterization of functional internal adenylation domains

The cyclic decapeptide antibiotic tyrocidine is produced by Bacillus brevis ATCC 8185 on an enzyme complex comprising three peptide synthetases, TycA, TycB, and TycC (tyrocidine synthetases 1, 2, and 3), via the nonribosomal pathway. However, previous molecular characterization of the tyrocidine synthetase-encoding operon was restricted to tycA, the gene that encodes the first one-module-bearing peptide synthetase. Here, we report the cloning and sequencing of the entire tyrocidine biosynthesis operon (39.5 kb) containing the tycA, tycB, and tycC genes. As deduced from the sequence data, TycB (404,562 Da) consists of three modules, including an epimerization domain, whereas TycC (723,577 Da) is composed of six modules and harbors a putative thioesterase domain at its C-terminal end. Each module incorporates one amino acid into the peptide product and can be further subdivided into domains responsible for substrate adenylation, thiolation, condensation, and epimerization (optional). We defined, cloned, and expressed in Escherichia coli five internal adenylation domains of TycB and TycC. Soluble His6-tagged proteins, ranging from 536 to 559 amino acids, were affinity purified and found to be active by amino acid-dependent ATP-PPi exchange assay. The detected amino acid specificities of the investigated domains manifested the colinear arrangement of the peptide product with the respective module in the corresponding peptide synthetases and explain the production of the four known naturally occurring tyrocidine variants. The Km values of the investigated adenylation domains for their amino acid substrates were found to be comparable to those published for undissected wild-type enzymes. These findings strongly support the functional integrities of single domains within multifunctional peptide synthetases. Directly downstream of the 3' end of the tycC gene, and probably transcribed in the tyrocidine operon, two tandem ABC transporters, which may be involved in conferring resistance against tyrocidine, and a putative thioesterase were found.

Substrate specificity of hybrid modules from peptide synthetases

Homologous modules from two different peptide synthetases were analyzed for functionally equivalent regions. Hybrids between the coding regions of the phenylalanine-activating module of tyrocidine synthetase and the valine-activating module of surfactin synthetase were constructed by combining the two reading frames at various highly conserved consensus sequences. The resulting DNA fragments were expressed in Escherichia coli as C-terminal fusions to the gene encoding for the maltose-binding protein. The fusion proteins were purified, and the amino acid specificities, the acceptance of different nucleotide analogues, and the substrate binding affinities were analyzed. We found evidence for a large N-terminal domain and a short C-terminal domain of about 19 kDa within the two modules, which are separated by the sequence motif GELCIGG. The two domains could be reciprocally transferred between the two modules, and the constructed hybrid proteins showed amino acid adenylating activity. Hybrid proteins fused at various consensus motifs within the two domains were inactive, indicating that the domains may fold independently and represent complex functional units. The N-terminal domain was found to be responsible for the amino acid specificity of the modules, and it is also involved in the recognition of the ribosyl and the phosphate moieties of the nucleotide substrate. For tyrocidine synthetase I, we could confine the sites for amino acid specificity to a region of 330 residues. The C-terminal domain is essential for the enzymatic activity and has a strong impact on the specific activity of the modules.

Sequence and genetic organization of a Bacillus subtilis operon encoding 2,3-dihydroxybenzoate biosynthetic enzymes

Under iron-limiting conditions, Bacillus subtilis (Bs) produces the siderophore 2,3-dihydroxybenzoate (DHB) to acquire extracellular iron. In Escherichia coli (Ec), DHB is a precursor of the siderophore enterobactin, which suggested that Bs may possess similar biosynthetic enzymes. The sequences of two overlapping Bs clones capable of complementing Ec enterobactin mutants [Grossman, T.H., Tuckman, M., Ellestad, S. and Osburne, M.S. (1993) Isolation and characterization of Bacillus subtilis genes involved in siderophore biosynthesis: Relationship between B. subtilis sfpo and Escherichia coli entD genes. J. Bacteriol. 175, 6203-6211] were analyzed and five open reading frames were identified. These genes are located near 291 degrees on the Bs chromosome and have been termed dhbA, dhbC, dhbE, dhbB and dhbF, based on similarities to Ec ent homologs. Amino-acid identities between gene product homologs are: EntA and DhbA, 41%; EntC and DhbC, 35%; EntE and DhbE, 48%; EntB and DhbB, 54%; and EntF and DhbF, 29%. DhbC is also 35% identical to the Bs menaquinone-specific isochorismate synthase, MenF, illustrating an example of gene duplication. Operon disruption studies suggested that the dhb genes comprise an operon of at least four genes.

Engineered biosynthesis of peptide antibiotics

In certain bacteria and filamentous fungi, a wide variety of bioactive peptides are produced non-ribosomally on large protein templates, called peptide synthetases. Recently, significant progress has been made towards understanding the modular arrangement of these complex multifunctional enzymes and the mechanisms by which they generate their corresponding peptide products. It has now been established that the synthesis of bioactive peptides and the specification of their sequence are brought about by a protein template that contains the appropriate number and the correct order of activating units (domains). These advances have enabled the development of a technique that permits the construction of hybrid genes encoding peptide synthetases with specifically altered substrate specificities. A programmed alteration within the primary structure of a peptide antibiotic is achieved by the substitution of an amino acid-activating domain in the corresponding protein template at the genetic level by a two-step recombination method. It utilizes successive gene disruption and reconstitution and demonstrates, for the first time, the potential of genetic engineering in the biosynthesis of novel peptide antibiotics. Many organisms, for instance those that cause diseases like tuberculosis and pneumonia, have evolved potent mechanisms of drug resistance. Therefore, the targeted engineering of peptide antibiotics could be one potential strategy for the development of novel drugs that overcome this resistance.

Organization and expression in Pseudomonas putida of the gene cluster involved in cephalosporin biosynthesis from Lysobacter lactamgenus YK90

The Lysobacter lactamgenus YK90 pcbAB gene encoding delta-(L-alpha-aminoadipyl)-L-cysteinyl-D-valine (ACV) synthetase is located immediately upstream of the pcbC gene in the same orientation in the gene cluster involved in cephalosporin biosynthesis. The pcbAB gene encodes a large polypeptide composed of 3722 amino acid residues with a molecular mass of 411593 Da. The predicted amino acid sequence has a high degree of similarity with those of known ACV synthetases from fungi and actinomycetes. Within the pcbAB amino acid sequence, three conserved and repeated domains of about 600 amino acids were identified. the domains also share a high degree of similarity with non-ribosomal peptide synthetases such as gramicidin synthetase 2 of Bacillus brevis. The pcbAB gene was expressed under the control of the lac promoter in Pseudomonas putida. Expression of the gene cluster involved in cephalosporin biosynthesis in P. putida led to the accumulation of beta-lactam antibiotics. Deletion analysis of an open-reading frame located between the cefE and cefD genes from the gene cluster revealed that it encoded deacetylcephalosporin C synthetase (cefF). From the results presented here and those of previous studies, the genes involved in cephalosporin biosynthesis in L. lactamgenus appear to be clustered in the order pcbAB-pcbC- cefE-cefF-cefD-bla in the same orientation within a 17-kb region of DNA.

A nonribosomal system of peptide biosynthesis

This review covers peptide structures originating from the concerted action of enzyme systems without the direct participation of nucleic acids. Biosynthesis proceeds by formation of linear peptidyl intermediates which may be enzymatically modified as well as transformed into specific cyclic structures. The respective enzyme systems are constructed of biosynthetic modules integrated into multienzyme structures. Genetic and DNA-sequence analysis of biosynthetic gene clusters have revealed extensive similarities between prokaryotic and eukaryotic systems, conserved principles of organisation, and a unique mechanism of transport of intermediates during elongation and modification steps involving 4'-phospho-pantetheine. These similarities permit the identification of peptide synthetases and related aminoacyl-ligases and acyl-ligases from sequence data. Similarities to other biosynthetic systems involved in the assembly of polyketide metabolites are discussed.

The peptide synthetase gene phsA from Streptomyces viridochromogenes is not juxtaposed with other genes involved in nonribosomal biosynthesis of peptides

By complementation of a previously described non-phosphinothricin tripeptide (PTT)-producing mutant, NTG1, which is blocked in nonribosomal synthesis of the peptide, a DNA fragment including the putative peptide synthetase gene phsA was isolated (W. Wohlleben, R. Alijah, J. Dorendorf, D. Hillemann, B. Nussbaumer, and S. Pelzer, Gene 115:127-132, 1992). Sequence analysis of phsA revealed that it encodes a protein of 622 amino acids with regions which are highly similar to core motifs characteristic for peptide synthetases. PhsA represents one functional domain of a peptide synthetase which is necessary for activation and condensation of one amino acid, probably N-acetyl-demethyl-phosphinothricin. With regard to the arrangement of the flanking genes, phsA is the first peptide synthetase gene which is not in the direct neighborhood of additional peptide synthetase genes involved in the formation of peptide antibiotics. Gene disruption mutants with internal fragments of phsA subcloned in temperature-sensitive pGM vectors were generated. Integration occurred either into the chromosomal copy of phsA or into a gene outside the known phsA locus, resulting in two classes of non-PTT-producing mutants. In cofeeding experiments the former phsA mutants showed the same phenotype as did NTG1, which confirmed participation of phsA in nonribosomal synthesis of PTT. A truncated phsA gene was overexpressed in Escherichia coli, and the resulting protein of 593 amino acids was purified for raising antibodies. By performing immunoblotting experiments, the expression of phsA could be detected in Streptomyces viridochromogenes Tü494 in the stationary-growth phase after 4 days of incubation.

Analysis of the syrB and syrC genes of Pseudomonas syringae pv. syringae indicates that syringomycin is synthesized by a thiotemplate mechanism

The syrB and syrC genes are required for synthesis of syringomycin, a lipodepsipeptide phytotoxin produced by Pseudomonas syringae pv. syringae, and are induced by plant-derived signal molecules. A 4,842-bp chromosomal region containing the syrB and syrC genes of strain B301D was sequenced and characterized. The open reading frame (ORF) of syrB was 2,847 bp in length and was predicted to encode an approximately 105-kDa protein, SyrB, with 949 amino acids. Searches of databases revealed that SyrB shares homology with members of a superfamily of adenylate-forming enzymes involved in peptide antibiotic and siderophore synthesis in a diverse spectrum of microorganisms. SyrB exhibited the highest degree of overall similarity (56.4%) and identity (33.8%) with the first amino acid-activating domain of pyoverdin synthetase, PvdD, of Pseudomonas aeruginosa. The N-terminal portion of SyrB contained a domain of approximately 600 amino acids that resembles the amino acid-activating domains of thiotemplate-employing peptide synthetases. The SyrB domain contained six signature core sequences with the same order and spacing as observed in all known amino acid-activating domains involved in nonribosomal peptide synthesis. Core sequence 6 of SyrB, for example, was similar to the binding site for 4'-phosphopantetheine, a cofactor required for thioester formation. The syrC ORF (1,299 bp) was located 175 bp downstream of the syrB ORF. Analysis of the transcriptional and translational relationship between the syrB and syrC genes demonstrated that they are expressed independently. The syrC ORF was predicted to encode an approximately 48-kDa protein product of 433 amino acids which is 42 to 48% similar to a number of thioesterases, including fatty acid thioesterases, haloperoxidases, and acyltransferases, that contain a characteristic GXS (C) XG motif. In addition, a zinc-binding motif was found near the C terminus of SyrC. The data suggest that SyrB and SyrC function as peptide synthetases in a thiotemplate mechanism of syringomycin biosynthesis.

Peptides

If we include beta-lactam antibiotics on the grounds that they have the same biosynthetic origin, peptides remain commercially the most important group of pharmaceuticals. However, our increasing knowledge of the genetic and enzymic background to biosynthesis, and of the regulation of metabolite production, will eventually bring a more unified approach to bioactive compounds. Mixing of structural types will become important, and we will be able to use our knowledge of biosynthetic genes and their regulatory networks. We will also benefit from an appreciation of the modular organization of catalytic functions, substrate transfer mechanisms and signalling between interacting enzymes. Since all of this is, in fact, the basis for enzymic synthesis of complex natural products in vivo, the exploitation of living cells requires mastery of a formidable network of cellular controls and compartments. For the present we are able to see fascinating connections emerging between genes in a variety of reaction sequences, not only in biosynthetic but also in degradative pathways. Peptide synthetases show surprising similarities to acylcoenzyme A synthetases, which are key enzymes in forming polyketides as well as in generating the CoA-derivatives that serve as substrates in degradative pathways. 4'-Phosphopantetheine, the functional half of CoA, plays a key role as the intrinsic transfer cofactor in various multienzyme systems. The comparatively small catalogue of reactions modifying natural products, notably epimerization, methylation, hydroxylation, decarboxylation (of peptides) and reduction/dehydration (of polyketides) can be found within or amongst biosynthetic proteins, generally as modules and organized in a specified order. The biochemist is coming close to the synthetic chemist's recipes, and may soon be recruiting proteins to carry them out.

Isolation and characterization of Tn917-generated bacitracin deficient mutants of Bacillus licheniformis

Two Tn917-generated bacitracin deficient mutants of Bacillus licheniformis were isolated. Southern blot analysis of chromosomal DNA extracted from both insertional mutants showed that Tn917 inserted in the vicinity of the gene coding for the enzyme BA2 of the bacitracin synthetase enzyme complex. Measurements of bacitracin synthetase activity in cell-free extracts and positive hybridization signals in the vicinity of the BA2 gene indicate that in both bacitracin deficient mutants Tn917 could be inserted in the BA1 gene or in segments involved in regulation. Thus, it could be possible that the genes for bacitracin synthetase are clustered in the B. licheniformis genome.

Analysis of core sequences in the D-Phe activating domain of the multifunctional peptide synthetase TycA by site-directed mutagenesis

The D-phenylalanine-activating enzyme tyrocidine synthetase I (TycA) from Bacillus brevis ATCC 8185 was overexpressed in Escherichia coli, purified to homogeneity, and assayed for ATP-PPi exchange and covalent binding of phenylalanine by the thiotemplate mechanism. Amino acid exchanges in four different cores of TycA created by site-directed mutagenesis revealed the amino acid residues involved in aminoacyladenylate formation and in covalent thioester formation. Mutations in the putative ATP-binding site SGTTGKPKG caused a decreased phenylalanine-dependent ATP-PPi exchange activity to 10% of the wild-type level for a Lys-186-to-Arg substitution and an almost complete loss of activity (< 1%) for a Lys-186-to-Thr exchange. Alteration of Asp-401 to Asn in the ATPase motif TGDL of TycA decreased the phenylalanine-dependent ATP-PPi exchange activity to 75% of wild type, while an Asp-401-to-Ser mutation decreased the activity to 10% of the wild-type level. Replacement of Ser-562 in the putative thioester-binding motif LGGDSI to Ala or Gly caused a reduction in trichloroacetic acid-precipitable TycA-[14C]phenylalanine complex to one-third of the wild-type level. However, no cleavable [14C]phenylalanine could be detected after treatment with performic acid, indicating that the resulting mutant was unable to form thioester with phenylalanine. In E. coli, TycA was labeled with beta-[3H]alanine, a precursor of 4'-phosphopantetheine, indicating that TycA is modified with a beta-alanine-containing cofactor.

Analysis of surfactin synthetase subunits in srfA mutants of Bacillus subtilis OKB105

The srfA operon of Bacillus subtilis functions in the biosynthesis of the lipopeptide antibiotic surfactin. On the basis of nucleotide sequence and genetic analysis, it is believed to encode three enzymes (E1A, E1B, and E2) that catalyze the incorporation of the surfactin substrate amino acids. Insertion, deletion, and amino acid substitution mutations of srfA were analyzed for subunit composition and activity as determined by assays of both amino acid-dependent ATP-PPi exchange and aminoacyl thioester formation. Insertion mutations in srfAA (encoding E1A, the subunit that incorporates Glu, Leu, and D-Leu) eliminated production and activity of all three enzymes. Deletions within srfAA and extending from srfAA to srfAB (encoding E1B, which incorporates Val, Asp, and D-Leu) abolished the activity and production of all three enzymes. Insertions between srfAA and srfAB and within srfAB eliminate the production and activity of E1B and E2. An insertion mutation in srfAC (encoding E2, which incorporates Leu) abolished the activity of E2 only. Mutations of the active serine in the putative 4'-phosphopantetheine-binding motif of the second and third domains of E1A eliminated thioester formation and severely reduced the ATP-PPi exchange activity of the two domains. However, the same mutation in the first domain of E1B had little effect on Val-dependent ATP-PPi exchange activity but abolished thioester formation. These results indicate that the coding assignments of the srfA genes are srfAA (E1A), srfAB (E1B), and srfAC (E2).

Amino-acylation site mutations in amino acid-activating domains of surfactin synthetase: effects on surfactin production and competence development in Bacillus subtilis

The part of the srfA operon of Bacillus subtilis that contains the region required for competence development is composed of the first four amino acid-activating domains which are responsible for the incorporation of Glu, Leu, D-Leu, and Val into the peptide moiety of the lipopeptide surfactin. Ser-to-Ala substitutions were made in the amino-acylation site of each domain, and their effects on surfactin production and competence development were examined. All of the mutations conferred a surfactin-negative phenotype, supporting the finding that the conserved Ser in the amino-acylation site is required for peptide synthesis. However, none of the mutations affected significantly competence development or the expression of a lacZ fusion to the late competence operon comG. This, coupled with recent findings that only the fourth, Val-activating, domain is required for competence, suggests that some activity, other than amino-acylation and perhaps unrelated to peptide synthesis, possessed by the fourth domain is involved in the role of srfA in regulating competence development.

Regulation of peptide antibiotic production in Bacillus

In Bacillus species, starvation leads to the activation of a number of processes that affect the ability to survive during periods of nutritional stress. Activities that are induced include the development of genetic competence, sporulation, the synthesis of degradative enzymes, motility, and antibiotic production. The genes that function in these processes are activated during the transition from exponential to stationary phase and are controlled by mechanisms that operate primarily at the level of transcription initiation. One class of genes functions in the synthesis of special metabolites such as the peptide antibiotics tyrocidine and gramicidin S as well as the cyclic lipopeptide surfactin. These genes include the grs and tyc operons in Bacillus brevis, which encode gramicidin S synthetase and tyrocidine synthetase, respectively, and the srfA operon of Bacillus subtilis which encodes the enzymes of the surfactin synthetase complex. Peptide antibiotic biosynthesis genes are regulated by factors as diverse as the early sporulation gene product Spo0A, the transition-state regulator AbrB, and gene products (ComA, ComP, and ComQ) required for the initiation of the competence developmental pathway.

Nucleotide sequence of 5' portion of srfA that contains the region required for competence establishment in Bacillus subtilus

The nucleotide sequence of the 20,535 base pairs of the 5' end of the srfA operon, containing the region required for competence development, was determined. This included the srfA promoter region, the first open reading frame, srfAA, encoding surfactin synthetase I and part of the second open reading frame, srfAB, encoding surfactin synthetase II. Three amino acid-activating domains characteristic of those found in peptide synthetases could be discerned in both srfAA (activating Glu, Leu and D-Leu) and srfAB (activating Val, Asp, and D-Leu). The presence of a conserved spacer motif in the amino-terminal end of srfAA suggests that the srfAA product may not initiate surfactin synthesis. The portion of srfA that contains the region required for competence is composed of srfAA and the first amino acid-activating domain of srfAB.

Multidomain enzymes involved in peptide synthesis

Biosynthesis of peptides in non-ribosomal systems is catalyzed by multifunctional enzymes that employ the thio-template mechanism. Recent studies on the analysis of the primary structure of several peptide synthetases have revealed that they are organized in highly conserved and repeated functional domains. The aligned domains provide the template for peptide synthesis, and their order determines the sequence of the peptide product.

[Molecular biology and regulatory mechanisms of antibiotic production in Bacillus]

Several species of the genus Bacillus produce linear and cyclic peptide antibiotics nonribosomally through multienzyme complexes by the so-called thiotemplate mechanism. Molecular genetic studies have shown that some peptide antibiotic biosynthesis genes are organized in operons and that they are expressed postexponentially under conditions that also activate the process of endospore formation in Bacillus. Furthermore, DNA-sequence analysis of some multifunctional peptide synthetase genes revealed that they contain a highly conserved and repeated domain structure. The same domain was also found to be conserved within a superfamily of peptide synthetases and adenylate-forming enzymes of diverse origins. Based on sequence homology and functional similarity I conclude that those enzymes bearing domain(s) represent a family of superenzymes which may have a common evolutionary origin.

Clusters of genes for the biosynthesis of antibiotics: Regulatory genes and overproduction of pharmaceuticals

In the last decade numerous genes involved in the biosynthesis of antibiotics, pigments, herbicides and other secondary metabolites have been cloned. The genes involved in the biosynthesis of penicillin, cephalosporin and cephamycins are organized in clusters as occurs also with the biosynthetic genes of other antibiotics and secondary metabolites (see review by Martín and Liras [65]). We have cloned genes involved in the biosynthesis of beta-lactam antibiotics from five different beta-lactam producing organisms both eucaryotic (Penicillium chrysogenum, Cephalosporium acremonium (syn. Acremonium chrysogenum) Aspergillus nidulans) and procaryotic (Nocardia lactamdurans, Streptomyces clavuligerus). In P. chrysogenum and A. nidulans the organization of the pcbAB, pcbC and penDE genes for ACV synthetase, IPN synthase and IPN acyltransferase showed a similar arrangement. In A. chrysogenum two different clusters of genes have been cloned. The cluster of early genes encodes ACV synthetase and IPN synthase, whereas the cluster of late genes encodes deacetoxycephalosporin C synthetase/hydroxylase and deacetylcephalosporin C acetyltransferase. In N. lactamdurans and S. clavuligerus a cluster of early cephamycin genes has been fully characterized. It includes the lat (for lysine-6-aminotransferase), pcbAB (for ACV synthase) and pcbC (for IPN synthase) genes. Pathway-specific regulatory genes which act in a positive (or negative) form are associated with clusters of genes involved in antibiotic biosynthesis. In addition, widely acting positive regulatory elements exert a pleiotropic control on secondary metabolism and differentiation of antibiotic producing microorganisms. The application of recombinant DNA techniques will contribute significantly to the improvement of fermentation organisms.

ACV synthetase

ACV synthetase (ACVS) is the first enzyme and plays a key role in the biosynthesis of all natural penicillins and cephalosporins. The enzyme is extremely unstable and little had been known about it until recently. This article summarizes the progress in research on this enzyme, including the establishment of a cell-free assay system, stabilization, purification, characterization, and gene cloning. A possible reaction sequence for ACVS catalysis is suggested.

Non-ribosomal peptide synthesis

Many peptides are synthesized by the multienzyme thiotemplate mechanism. This is catalyzed by large, multifunctional enzymes called peptide synthetases. Recent studies have focused on elucidating the primary structure of the peptide synthetases and defining their functional domains. These are essential first steps in the detailed mutational analysis of peptide synthetase function.

Transcriptional organization and regulation of the nosiheptide resistance gene in Streptomyces actuosus

The nosiheptide resistance gene (nshR) and a putative regulatory gene (nshA) are found together on a 2326 bp BamHI-PstI DNA fragment isolated from Streptomyces actuosus ATCC 25421. The putative regulatory gene, nshA, situated upstream from the nosiheptide resistance gene in the 2326 bp DNA fragment, contains apparent DNA-binding and RNA-binding domains. Interruption of nshA in the chromosome of S. actuosus alters nosiheptide production, suggesting that nshA is involved in regulation of nosiheptide biosynthesis. Two transcription initiation sites were found upstream of nshA as demonstrated by high-resolution S1 nuclease mapping. A weak transcription start site for nshR was found which initiated transcription from the first nucleotide of the open reading frame. Although a stem-loop structure with apparent termination activity was found between nshA and nshR, readthrough of transcription between nshA and nshR was demonstrated by S1 nuclease mapping of the 3' terminus of the nshA transcript. Time-course S1 experiments of the three promoters (nshA-pl, nshA-p2, nshR-p) indicated highly regulated differential expression of the promoters. nshA-p2 is a strong, constitutive promoter whereas 30% of the total nshA-p1/p2 transcript reads through the terminator and into the nshR gene, accounting for more than half of the total steady-state nshR transcript. The implications of the regulation of nshA and nshR gene expression, as well as the expression of two other linked genes, are presented.

Genetic competence in Bacillus subtilis

Genetic competence may be defined as a physiological state enabling a bacterial culture to bind and take up high-molecular-weight exogenous DNA (transformation). In Bacillus subtilis, competence develops postexponentially and only in certain media. In addition, only a minority of the cells in a competent culture become competent, and these are physiologically distinct. Thus, competence is subject to three regulatory modalities: growth stage specific, nutritionally responsive, and cell type specific. This review summarizes the present state of knowledge concerning competence in B. subtilis. The study of genes required for transformability has permitted their classification into two broad categories. Late competence genes are expressed under competence control and specify products required for the binding, uptake, and processing of transforming DNA. Regulatory genes specify products that are needed for the expression of the late genes. Several of the late competence gene products have been shown to be membrane localized, and others are predicted to be membrane associated on the basis of amino acid sequence data. Several of these predicted protein sequences show a striking resemblance to gene products that are involved in the export and/or assembly of extracellular proteins and structures in gram-negative organisms. This observation is consistent with the idea that the late products are directly involved in transport of DNA and is equally consistent with the notion that they play a morphogenetic role in the assembly of a transport apparatus. The competence regulatory apparatus constitutes an elaborate signal transduction system that senses and interprets environmental information and passes this information to the competence-specific transcriptional machinery. Many of the regulatory gene products have been identified and partially characterized, and their interactions have been studied genetically and in some cases biochemically as well. These include several histidine kinase and response regulator members of the bacterial two-component signal transduction machinery, as well as a number of known transcriptionally active proteins. Results of genetic studies are consistent with the notion that the regulatory proteins interact in a hierarchical way to make up a regulatory pathway, and it is possible to propose a provisional scheme for the organization of this pathway. It is remarkable that almost all of the regulatory gene products appear to play roles in the control of various forms of postexponential expression in addition to competence, e.g., sporulation, degradative-enzyme production, motility, and antibiotic production. This has led to the notion of a signal transduction network which transduces environmental information to determine the levels and timing of expression of the ultimate products characteristic of each of these systems.

The cephamycin biosynthetic genes pcbAB, encoding a large multidomain peptide synthetase, and pcbC of Nocardia lactamdurans are clustered together in an organization different from the same genes in Acremonium chrysogenum and Penicillium chrysogenum

A 34 kb fragment of the Nocardia lactamdurans DNA carrying the cluster of early cephamycin biosynthetic genes was cloned in lambda EMBL3 by hybridization with probes internal to the pcbAB and pcbC genes of Penicillium chrysogenum and Streptomyces griseus. The pcbAB and pcbC genes were found to be closely linked together in the genome of N. lactamdurans. The pcbAB gene of N. lactamdurans showed the same orientation as the pcbC gene, in contrast to the divergent expression of the genes in the pcbAB-pcbC cluster of P. chrysogenum and Acremonium chrysogenum. The pcbAB gene encodes a large (3649 amino acids) multidomain delta-(L-alpha-aminoadipyl)-L-cysteinyl-D-valine synthetase with a deduced Mr of 404,134. This enzyme contains three repeated domains and a consensus thioesterase active-site sequence. The pcbC gene encodes a protein of 328 amino acids with a deduced Mr of 37,469, which is similar to other isopenicillin N synthases except that it lacks one of two cysteine residues conserved in all other isopenicillin N synthases. The different organization of the pcbAB-pcbC gene cluster in N. lactamadurans and Streptomyces clavuligerus relative to P. chrysogenum and A. chrysogenum is intriguing in relation to the hypothesis of horizontal transference of these genes from actinomycetes to filamentous fungi by a single transfer event.

Characterization of the Cephalosporium acremonium pcbAB gene encoding alpha-aminoadipyl-cysteinyl-valine synthetase, a large multidomain peptide synthetase: linkage to the pcbC gene as a cluster of early cephalosporin biosynthetic genes and evidence of multiple functional domains

A 24-kb region of Cephalosporium acremonium C10 DNA was cloned by hybridization with the pcbAB and pcbC genes of Penicillium chrysogenum. A 3.2-kb BamHI fragment of this region complemented the mutation in the structural pcbC gene of the C. acremonium N2 mutant, resulting in cephalosporin production. A functional alpha-aminoadipyl-cysteinyl-valine (ACV) synthetase was encoded by a 15.6-kb EcoRI-BamHI DNA fragment, as shown by complementation of an ACV synthetase-deficient mutant of P. chrysogenum. Two transcripts of 1.15 and 11.4 kb were found by Northern (RNA blot) hybridization with probes internal to the pcbC and pcbAB genes, respectively. An open reading frame of 11,136 bp was located upstream of the pcbC gene that matched the 11.4-kb transcript initiation and termination regions. It encoded a protein of 3,712 amino acids with a deduced Mr of 414,791. The nucleotide sequence of the gene showed 62.9% similarity to the pcbAB gene encoding the ACV synthetase of P. chrysogenum; 54.9% of the amino acids were identical in both ACV synthetases. Three highly repetitive regions occur in the deduced amino acid sequence of C. acremonium ACV synthetase. Each is similar to the three repetitive domains in the deduced sequence of P. chrysogenum ACV synthetase and also to the amino acid sequence of gramicidin synthetase I and tyrocidine synthetase I of Bacillus brevis. These regions probably correspond to amino acid activating domains in the ACV synthetase protein. In addition, a thioesterase domain was present in the ACV synthetases of both fungi. A similarity has been found between the domains existing in multienzyme nonribosomal peptide synthetases and polyketide and fatty acid synthetases. The pcbAB gene is linked to the pcbC gene, forming a cluster of early cephalosporin-biosynthetic genes.

srfA is an operon required for surfactin production, competence development, and efficient sporulation in Bacillus subtilis

The srfA locus of Bacillus subtilis is defined by a transposon Tn917 insertion and is required for production of the peptide secondary metabolite surfactin. The srfA locus was isolated by cloning the DNA flanking srfA::Tn917 insertions followed by chromosome walking. The cloned region is an operon of over 25 kb which covers the transcription initiation region but not the intact 3' end of srfA. csh-293, which was previously identified as a Tn917lac mutation that impairs competence development and causes a conditional defect in sporulation, was known to be located in the vicinity of the srfA locus within the B. subtilis genome. The csh-293::Tn917lac mutation was discovered to cause a defect in surfactin production and was shown to be located in the srfA operon by its cotransformation with srfA mutations and by Southern hybridization analysis. Insertion mutations in srfA, created by the chromosomal integration of plasmids bearing overlapping srfA DNA fragments, were examined for their effects on surfactin production, competence, and sporulation. All three processes were found to require the intact 5' half of the srfA operon, whereas the 3' half of srfA was found to be required for sporulation and surfactin production but not competence. These experiments show that srfA gene products function in B. subtilis cell specialization and differentiation.

Isolation and characterization of comL, a transcription unit involved in competence development of Bacillus subtilis

Using the transformation-deficient mutant M465, which was previously isolated by means of insertional mutagenesis with plasmid pHV60, a transcription unit comL required for genetic competence of Bacillus subtilis was identified. A chromosomal DNA fragment flanking the inserted pHV60 was isolated and used to screen two different libraries of B. subtilis DNA in phage lambda EMBL4 and lambda EMBL12, respectively. With the aid of six recombinant phages that hybridize with this chromosomal fragment a restriction map of about 23 kb of B. subtilis chromosomal DNA was constructed. Using small adjoining pieces of this chromosomal DNA in Campbell integrations, the size of the transcription unit involved in competence development could be delimited to about 15 kb. By insertion of a promoterless lacZ gene into comL, the transcriptional regulation of comL was analysed and epistatic interactions among various other com genes were determined. The results of these experiments indicated that comL is optimally expressed in glucose-based minimal medium when the culture enters the stationary phase of growth and that the expression of late competence genes is dependent on previous transcription of comL, which in turn is dependent on the gene products of comA and comB.

Cloning and sequencing of a bile acid-inducible operon from Eubacterium sp. strain VPI 12708

Two bile acid-inducible polypeptides from Eubacterium sp. strain VPI 12708 with molecular weights of 27,000 and approximately 45,000 have previously been shown to be encoded by genes residing on a 2.9-kb EcoRI fragment. We now report the cloning and sequencing of three additional overlapping DNA fragments upstream from this EcoRI fragment. Together, these four fragments contain a large segment of a bile acid-inducible operon which encodes the 27,000- and 45,000-Mr (now shown to be 47,500-Mr) polypeptides and open reading frames potentially coding for four additional polypeptides with molecular weights of 59,500, 58,000, 19,500, and 9,000 to 11,500. A bile acid-inducible polypeptide with an apparent Mr of 23,500, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, was purified to homogeneity, and the N-terminal amino acid sequence that was obtained matched the sequence deduced from the open reading frame coding for the 19,500-Mr polypeptide. A short DNA segment containing the 3' downstream end of the gene coding for the 47,500-Mr polypeptide was not successfully cloned but was directly sequenced from DNA fragments synthesized by polymerase chain reaction. The mRNA initiation site for the bile acid-inducible operon was shown by primer extension to be immediately upstream from the gene encoding the 58,000-Mr polypeptide. A potential promoter region upstream from the mRNA initiation site displayed significant homology with the promoter regions of previously identified bile acid-inducible genes from Eubacterium sp. strain VPI 12708. We hypothesize that this bile acid-inducible operon codes for most of the enzymes involved in the bile acid 7 alpha-dehydroxylation pathway in this bacterium.

Nonribosomal biosynthesis of peptide antibiotics

Peptide antibiotics are known to contain non-protein amino acids, D-amino acids, hydroxy acids, and other unusual constituents. In addition they may be modified by N-methylation and cyclization reactions. Their biosynthetic origin has been connected in many cases to an enzymatic system referred to as the 'thiotemplate multienzymic mechanism'. This mechanism includes the activation of the constituent residues as adenylates on the enzymic template, the acylation of specific template thiol groups, epimerization or N-methylation at this thioester stage, and polymerization in the sequence directed by the multienzymic structure with the aid of 4'-phosphopantetheine as a cofactor, including possible cyclization or terminal modification reactions. The reaction sequences leading to gramicidin S, tyrocidine, cyclosporine, bacitracin, polymyxin, actinomycin, enniatin, beauvericin, delta-(L-alpha-aminoadipyl)-L-cysteinyl-D-valine and linear gramicidin are discussed. The structures of the multienzymes, their genetic organization, the biological functions of these peptides and results on related systems are discussed.

Antibiotics--cloning of biosynthetic pathways

Biosynthetic pathways leading to antibiotics have often been found to be clustered, and new organizational forms of multifunctional enzymes have been discovered. Such polyenzymes accomplish the synthesis of complex metabolites such as peptides or polyketides by a sequence of enzymatic reactions. So, reactions leading to the tripeptide precursor of beta-lactam antibiotics, ACV, or to the cycloundecapeptide cyclosporine have been fused into single polypeptide chain synthetases, respectively. In certain isofunctional sites restricted similarities have been detected.

Streptomyces genes involved in biosynthesis of the peptide antibiotic valinomycin

We have identified genes from Streptomyces levoris A-9 involved in the biosynthesis of the peptide antibiotic valinomycin. Two segments of chromosomal DNA were recovered from genomic libraries, constructed by using the low-copy-number plasmid pIJ922, by complementation of valinomycin-deficient (vlm) mutants of S. levoris A-9. One set of plasmids restored valinomycin production to only one mutant, that carrying vlm-1, whereas a second set of plasmids restored productivity to seven vlm mutants, those carrying vlm-2 through vlm-8. Additional complementation studies using subcloned restriction enzyme fragments showed that the vlm-1+ gene was contained within a 2.5-kilobase (kb) DNA region, whereas alleles vlm-2+ through vlm-8+ were contained in a 12-kb region, representing at least three genes. Physical mapping experiments based on the isolation of cosmid clones showed that the two vlm loci were 50 to 70 kb apart. Southern hybridization experiments demonstrated that the vlm-2+ gene cluster was highly conserved among other valinomycin-producing Streptomyces strains, whereas the vlm-1+ gene was ubiquitous among Streptomyces species tested. Increasing the copy number of the vlm-2+ gene cluster in S. levoris A-9 by the introduction of low-copy-number recombinant plasmids resulted in a concomitant increase in the level of valinomycin production.

Molecular biology of antibiotic production in Bacillus

Several species of the genus Bacillus produce peptide antibiotics which are synthesized either through a ribosomal or non-ribosomal mechanism. The antibiotics gramicidin, tyrocidine, and bacitracin are synthesized nonribosomally by the multienzyme thiotemplate mechanism. Surfactin and mycobacillin are also synthesized nonribosomally but by a mechanism that, apparently, is distinct from that of the multienzyme thiotemplate. Other antibiotics such as subtilin are gene encoded and are ribosomally synthesized. Molecular genetic and DNA sequence analysis have shown that biosynthesis genes for some antibiotics are clustered into polycistronic transcription units and are under the control of global regulatory systems that govern the expression of genes that are induced when Bacillus cells enter stationary phase of growth. Future experiments involving the molecular dissection of peptide antibiotic biosynthesis genes in Bacillus will be attempted in hopes of further examining the mechanism and regulation of antibiotic production.

Gramicidin S biosynthesis operon containing the structural genes grsA and grsB has an open reading frame encoding a protein homologous to fatty acid thioesterases

The DNA sequence of about 5.9 kilobase pairs (kbp) of the gramicidin S biosynthesis operon (grs) was determined. Three open reading frames were identified; the corresponding genes, called grsT, grsA, and grsB, were found to be organized in one transcriptional unit, not two as previously reported (M. Krause and M. A. Marahiel, J. Bacteriol. 170:4669-4674, 1988). The entire nucleotide sequence of grsA, coding for the 126.663-kilodalton gramicidin S synthetase 1, grsT, encoding a 29.191-kilodalton protein of unknown function, and 732 bp of the 5' end of grsB, encoding the gramicidin S synthetase 2, were determined. A single initiation site of transcription 81 bp upstream of the grsT initiation condon GTG was identified by high-resolution S1 mapping studies. The sequence of the grsA gene product showed a high degree of homology to the tyrocidine synthetase 1 (TycA protein), and that of grsT exhibited a significant degree of homology to vertebrate fatty acid thioesterases.