Cloning genes for the biosynthesis of a macrolide antibiotic

Chemo-enzymatic total synthesis: current approaches toward the integration of chemical and enzymatic transformations

A steadily increasing number of reports have been published on chemo-enzymatic synthesis methods that integrate biosynthetic enzymatic transformations with chemical conversions. This review focuses on the total synthesis of natural products and classifies the enzymatic reactions into three categories. The total synthesis of five natural products: cotylenol, trichodimerol, chalcomoracin, tylactone, and saframycin A, as well as their analogs, is outlined with an emphasis on comparing these chemo-enzymatic syntheses with the corresponding natural biosynthetic pathways.

Functional insights into the mode of DNA and ligand binding of the TetR family regulator TylP from Streptomyces fradiae

Tetracycline repressors (TetRs) modulate multidrug efflux pathways in several pathogenic bacteria. In Streptomyces, they additionally regulate secondary metabolic pathways like antibiotic production. For instance, in the antibiotic producer Streptomyces fradiae, a layered network of TetRs regulates the levels of the commercially important antibiotic tylosin, with TylP occupying the top of this cascading network. TetRs exist in two functional states, the DNA-bound and the ligand-bound form, which are allosterically regulated. Here, to develop deeper insights into the factors that govern allostery, the crystal structure of TylP was solved to a resolution of 2.3 Å. The structure revealed that TylP possesses several unique features; notably, it harbors a unique C-terminal helix-loop extension that spans the entire length of the structure. This anchor connects the DNA-binding domain (DBD) with the ligand-binding domain (LBD) via a mix of positively charged and hydrogen-bonding interactions. Supporting EMSA studies with a series of ΔC truncated versions show that a systematic deletion of this region results in complete loss of DNA binding. The structure additionally revealed that TylP is markedly different in the orientation of its DBD and LBD architecture and the dimeric geometry from its hypothesized Streptomyces homologue CprB, which is a γ-butyrolactone regulator. Rather, TylP is closer in structural design to macrolide-binding TetRs found in pathogens. Supporting molecular dynamic studies suggested that TylP binds a macrolide intermediate in the tylosin pathway. Collectively, the structure along with corroborating biochemical studies provided insights into the novel mode of regulation of TetRs in antibiotic-producing organisms.

Characterization of the Two Methylation Steps Involved in the Biosynthesis of Mycinose in Tylosin

The S-adenosyl-l-methionine-dependent O-methyltransferases TylE and TylF catalyze the last two methylation reactions in the tylosin biosynthetic pathway of Streptomyces fradiae. It has long been known that the TylE-catalyzed C2‴-O-methylation of the 6-deoxy-d-allose bound to demethylmacrocin or demethyllactenocin precedes the TylF-catalyzed C3‴-O-methylation of the d-javose (C2‴-O-methylated 6-deoxy-d-allose) attached to macrocin or lactenocin. This study reveals the unexpected substrate promiscuity of TylE and TylF responsible for the biosynthesis of d-mycinose (C3‴-O-methylated d-javose) in tylosin through the identification of a new minor intermediate 2‴-O-demethyldesmycosin (2; 3‴-methyl-demethyllactenocin), which lacks a 2‴-O-methyl group on the mycinose moiety of desmycosin, along with 2‴-O-demethyltylosin (1; 3‴-methyl-demethylmacrocin) that was previously detected from the S. fradiae mutant containing a mutation in the tylE gene. These results unveil the unique substrate flexibility of TylE and TylF and demonstrate their potential for the engineered biosynthesis of novel glycosylated macrolide derivatives.

Recombinant microorganisms for industrial production of antibiotics

The enhancement of industrial antibiotic yield has been achieved through technological innovations and traditional strain improvement programs based on random mutation and screening. The development of recombinant DNA techniques and their application to antibiotic producing microorganisms has allowed yield increments and the design of biosynthetic pathways giving rise to new antibiotics. Genetic manipulations of the cephalosporin producing fungus Cephalosporium acremonium have included yield improvements, accomplished increasing biosynthetic gene dosage or enhancing oxygen uptake, and new biosynthetic capacities as 7-aminocephalosporanic acid (7-ACA) or penicillin G production. Similarly, in Penicillium chrysogenum, the industrial penicillin producing fungus, heterologous expression of cephalosporin biosynthetic genes has led to the biosynthesis of adipyl-7-aminodeacetoxycephalosporanic acid (adipyl-7-ADCA) and adipyl-7-ACA, compounds that can be transformed into the economically relevant 7-ADCA and 7-ACA intermediates. Escherichia coli expression of the genes encoding D-amino acid oxidase and cephalosporin acylase activities has simplified the bioconversion of cephalosporin C into 7-ACA, eliminating the use of organic solvents. The genetic manipulation of antibiotic producing actinomycetes has allowed productivity increments and the development of new hybrid antibiotics. A legal framework has been developed for the confined manipulation of genetically modified organisms.

Strain improvement for production of pharmaceuticals and other microbial metabolites by fermentation

Microbes have been good to us. They have given us thousands of valuable products with novel structures and activities. In nature, they only produce tiny amounts of these secondary metabolic products as a matter of survival. Thus, these metabolites are not overproduced in nature, but they must be overproduced in the pharmaceutical industry. Genetic manipulations are used in industry to obtain strains that produce hundreds or thousands of times more than that produced by the originally isolated strain. These strain improvement programs traditionally employ mutagenesis followed by screening or selection; this is known as 'brute-force' technology. Today, they are supplemented by modern strategic technologies developed via advances in molecular biology, recombinant DNA technology, and genetics. The progress in strain improvement has increased fermentation productivity and decreased costs tremendously. These genetic programs also serve other goals such as the elimination of undesirable products or analogs, discovery of new antibiotics, and deciphering of biosynthetic pathways.

Regulation of tylosin production: role of a TylP-interactive ligand

Gamma-butyrolactones regulate secondary metabolism and, sometimes, sporulation in actinomycetes by binding to specific receptor proteins, causing their dissociation from DNA targets and releasing the latter from transcriptional repression. Previously, in engineered strains of Streptomyces lividans, we showed that TylP, a deduced gamma-butyrolactone receptor, downregulated reporter gene expression driven by tylP, tylQ or tylS promoter DNA. These genes all control tylosin production in Streptomyces fradiae. Thus, at early stages of fermentation, TylQ represses tylR whereas TylS is needed for transcriptional activation of tylR. Importantly, TylR is the key activator of tylosin-biosynthetic genes. Here, we show that HIS-tagged TylP binds to specific DNA sequences, similar to the targets for authentic gamma-butyrolactone receptors, in the promoters of tylP, tylQ and tylS. Moreover, such binding is disrupted by material produced in S. fradiae and extractable by organic solvent. That putative gamma-butyrolactone material was not produced when orf18 * was disrupted within the S. fradiae genome and only about 1% of that activity survived inactivation of orf16 *, suggesting roles for the respective gene products in gamma-butyrolactone synthesis. Continued synthesis of tylosin by the disrupted strains contrasts with other reports that loss of gamma-butyrolactones abolishes antibiotic production.

Genetic improvement of processes yielding microbial products

Although microorganisms are extremely good in presenting us with an amazing array of valuable products, they usually produce them only in amounts that they need for their own benefit; thus, they tend not to overproduce their metabolites. In strain improvement programs, a strain producing a high titer is usually the desired goal. Genetics has had a long history of contributing to the production of microbial products. The tremendous increases in fermentation productivity and the resulting decreases in costs have come about mainly by mutagenesis and screening/selection for higher producing microbial strains and the application of recombinant DNA technology.

Production of hybrid 16-membered macrolides by expressing combinations of polyketide synthase genes in engineered Streptomyces fradiae hosts

Combinations of the five polyketide synthase (PKS) genes for biosynthesis of tylosin in Streptomyces fradiae (tylG), spiramycin in Streptomyces ambofaciens (srmG), or chalcomycin in Streptomyces bikiniensis (chmG) were expressed in engineered hosts derived from a tylosin-producing strain of S. fradiae. Surprisingly efficient synthesis of compounds predicted from the expressed hybrid PKS was obtained. The post-PKS tailoring enzymes of tylosin biosynthesis acted efficiently on the hybrid intermediates with the exception of TylH-catalyzed hydroxylation of the methyl group at C14, which was efficient if C4 bore a methyl group, but inefficient if a methoxyl was present. Moreover, for some compounds, oxidation of the C6 ethyl side chain to an unprecedented carboxylic acid was observed. By also expressing chmH, a homolog of tylH from the chalcomycin gene cluster, efficient hydroxylation of the 14-methyl group was restored.

Formation of unusual sugars: mechanistic studies and biosynthetic applications

Carbohydrates are highly abundant biomolecules found extensively in nature. Besides playing important roles in energy storage and supply, they often serve as essential biosynthetic precursors or structural elements needed to sustain all forms of life. A number of unusual sugars that have certain hydroxyl groups replaced by a hydrogen, an amino group, or an alkyl side chain play crucial roles in determining the biological activity of the parent natural products in bacterial lipopolysaccharides or secondary metabolite antibiotics. Recent investigation of the biosynthesis of these monosaccharides has led to the identification of the gene clusters whose protein products facilitate the unusual sugar formation from the ubiquitous NDP-glucose precursors. This review summarizes the mechanistic studies of a few enzymes crucial to the biosynthesis of C-2, C-3, C-4, and C-6 deoxysugars, the characterization and mutagenesis of nucleotidyl transferases that can recognize and couple structural analogs of their natural substrates and the identification of glycosyltransferases with promiscuous substrate specificity. Information gleaned from these studies has allowed pathway engineering, resulting in the creation of new macrolides with unnatural deoxysugar moieties for biological activity screening. This represents a significant progress toward our goal of searching for more potent agents against infectious diseases and malignant tumors.

Regulation of tylosin production and morphological differentiation in Streptomyces fradiae by TylP, a deduced gamma-butyrolactone receptor

During promoter-probe analysis carried out in Streptomyces lividans, the TylP protein powerfully inhibited reporter gene expression from the tylP promoter, raising the likelihood that tylP is autoregulated in its native host, Streptomyces fradiae. Also in S. lividans, TylP negatively controlled the tylQ promoter, even though tylQ could still be switched off in S. fradiae strains specifically disrupted in tylP. Under the latter conditions, tylosin production was brought forward and enhanced, whereas overexpression of tylP resulted in reduced levels of the antibiotic, accompanied by barely detectable transcription from multiple genes of the tylosin biosynthetic cluster. Unexpectedly, overexpression of tylP reduced transcription of tylS, a transcriptional activator essential for tylosin production. This was probably a direct effect, as TylP also reduced expression from the tylS promoter in S. lividans. For these several reasons, we conclude that TylP acts as a repressor during tylosin biosynthesis. In addition, TylP influences morphological differentiation in S. fradiae. On solid media, strains in which tylP was disrupted sporulated significantly earlier than wild type and, in liquid culture, displayed hyperfragmentation.

Differential roles of two SARP-encoding regulatory genes during tylosin biosynthesis

The tylosin biosynthetic gene cluster of Streptomyces fradiae is remarkable in harbouring at least five regulatory genes, two of which (tylS and tylT) encode proteins of the Streptomyces antibiotic regulatory protein (SARP) family. The aim of the present work was to assess the respective contributions of TylS and TylT to tylosin production. A combination of targeted gene disruption, fermentation studies and gene expression analysis via reverse transcriptase-polymerase chain reaction (RT-PCR) suggests that tylS is essential for tylosin production and controls the expression of tylR (previously shown to be a global activator of the biosynthetic pathway) plus at least one other gene involved in polyketide metabolism or regulation thereof. This is the first demonstration of a SARP acting to control another regulatory gene during antibiotic biosynthesis. In contrast, tylT is not essential for tylosin production.

Expression analysis of the tylosin-biosynthetic gene cluster: pivotal regulatory role of the tylQ product

Expression analysis by RT-PCR, applied to the entire tyl cluster, revealed that the pattern of transcription is more complex than expected. For example, the five tylG polyketide synthase genes are not necessarily cotranscribed or even coregulated. Among the regulatory genes, tylQ has emerged as a key factor. Although several genes (including the positive regulator, tylS) were possibly expressed constitutively, only tylQ was silent during secondary metabolism. Analysis of engineered strains, in which tylQ was disrupted or overexpressed, showed that the TylQ protein is a transcriptional repressor that blocks tylosin biosynthesis by controlling expression of the activator, tylR. Before tylosin production can be triggered, tylQ must be switched off, or at least downregulated.

Feedback control of polyketide metabolism during tylosin production

Tylosin is produced by Streptomyces fradiae via a combination of polyketide metabolism and synthesis of three deoxyhexose sugars, of which mycaminose is the first to be added to the polyketide aglycone, tylactone (protylonolide). Previously, disruption of the gene (tylMII) encoding attachment of mycaminose to the aglycone unexpectedly abolished accumulation of the latter, raising the possibility of a link between polyketide metabolism and deoxyhexose biosynthesis in S. fradiae. However, at that time, it was not possible to eliminate an alternative explanation, namely, that downstream effects on the expression of other genes, not involved in mycaminose metabolism, might have contributed to this phenomenon. Here, it is shown that disruption of any of the four genes (tylMI--III and tylB) specifically involved in mycaminose biosynthesis elicits a similar response, confirming that production of mycaminosyl-tylactone directly influences polyketide metabolism in S. fradiae. Under similar conditions, when mycaminose biosynthesis was specifically blocked by gene disruption, accumulation of tylactone could be restored by exogenous addition of glycosylated tylosin precursors. Moreover, certain other macrolides, not of the tylosin pathway, were also found to elicit qualitatively similar effects. Comparison of the structures of stimulatory macrolides will facilitate studies of the stimulatory mechanism.

Conjugation and transformation of Streptomyces species by tylosin resistance

The tlrB gene from Streptomyces fradiae has been cloned and used to construct bifunctional Streptomyces-Escherichia coli shuttle vectors carrying the antibiotic resistance genes to kanamycin-neomycin, thiostrepton and tylosin as selection markers. In the same way, the tlrB gene was subcloned in plasmids including the apramycin resistance gene and the oriT sequence from the plasmid pSET152 to facilitate conjugation of Streptomyces spores. The usefulness of the tlrB gene as tylosin resistance marker was ascertained in Streptomyces lividans, Streptomyces parvulus and Streptomyces coelicolor, but not in Streptomyces clavuligerus. The tlrB gene constitutes a useful selection marker when high-frequency of conjugation/transformation is not required or as secondary marker in recombinant Streptomyces species where thiostrepton and kanamycin have been utilized for primary selection.

The mycarose-biosynthetic genes of Streptomyces fradiae, producer of tylosin

The tylCK region of the Streptomyces fradiae genome was sequenced, revealing an incomplete set of five tylC genes encoding all-but-one of the enzymes involved in the biosynthesis of mycarose. The latter is a 6-deoxyhexose sugar required during production of the macrolide antibiotic, tylosin. The missing mycarose-biosynthetic gene, tylCVI, was found about 50 kb distant from its functional partners, on the other side of the tylG (polyketide synthase) gene complex. Mutational analysis, involving targeted gene transplacement, was employed to confirm the functions of specific genes, including tylCVI. Particularly interesting was the similarity between the tylosin-biosynthetic mycarosyltransferase enzyme, TylCV, and proteins of the macrolide glycosyltransferase (MGT) family that inactivate macrolides via glycosylation of attached sugar residues and are involved in resistance and/or antibiotic efflux. The arrangement of genes within the 'mycarose cluster' would allow their expression as two short operons with divergent, and perhaps co-regulated, promoters. Whether displacement of tylCVI relative to the other tylC genes provides additional regulatory opportunities remains to be established.

Characterization and targeted disruption of a glycosyltransferase gene in the tylosin producer, Streptomyces fradiae

An open reading frame, designated tylN, has been identified by sequence analysis at one end of the tylosin biosynthetic gene cluster of Streptomyces fradiae, alongside a cluster of genes encoding the biosynthesis of dTDP-deoxyallose. This 6-deoxyhexose sugar is converted to mycinose, via bis O-methylation, following attachment to the polyketide lactone during tylosin biosynthesis. The deduced product of tylN is similar to several glycosyltransferases, authentic and putative, and displays a consensus sequence motif that appears to be characteristic of a sub-group of such enzymes. Specific disruption of tylN within the S. fradiae genome resulted in the production of demycinosyl-tylosin, whereas other glycosyltransferase activities involved in tylosin biosynthesis were not affected. Evidently, tylN encodes deoxyallosyl transferase.

Stimulation of polyketide metabolism in Streptomyces fradiae by tylosin and its glycosylated precursors

Three glycosyltransferases are involved in tylosin biosynthesis in Streptomyces fradiae. The first sugar to be added to the polyketide aglycone (tylactone) is mycaminose and the gene encoding mycaminosyltransferase is orf2* (tylM2). However, targeted disruption of orf2* did not lead to the accumulation of tylactone under conditions that normally favour tylosin production; instead, the synthesis of tylactone was virtually abolished. This may, in part, have resulted from a polar effect on the expression of genes downstream of orf2*, particularly orf4* (ccr) which encodes crotonyl-CoA reductase, an enzyme that supplies 4-carbon extender units for polyketide metabolism. However, that cannot be the entire explanation, since tylosin production was restored at about 10% of the wild-type level when orf2* was re-introduced into the disrupted strain. When glycosylated precursors of tylosin were fed to the disrupted strain, they were converted to tylosin, confirming that two of the three glycosyltransferase activities associated with tylosin biosynthesis were still intact. Interestingly, however, tylactone also accumulated under such conditions and, to a much lesser extent, when tylosin was added to similar fermentations. It is concluded that glycosylated macrolides exert a pronounced positive effect on polyketide metabolism in S. fradiae.

Analysis of four tylosin biosynthetic genes from the tylLM region of the Streptomyces fradiae genome

The tylLM region of the tylosin biosynthetic gene cluster of Streptomyces fradiae contains four open reading frames (orfs1*-4*). The function of the orf1* product is not known. The product of orf2* (tylM2) is the glycosyltransferase that adds mycaminose to the 5-hydroxyl group of tylactone, the polyketide aglycone of tylosin (Ty). A methyltransferase, responsible for 3-N-methylation during mycaminose production, is encoded by orf3* (tylM1). The product of orf4* (cer) is crotonyl-CoA reductase, which converts acetoacetyl-CoA to butyryl-CoA for use as a 4C extender unit during tylactone production.

Deletion analysis of the avermectin biosynthetic genes of Streptomyces avermitilis by gene cluster displacement

Streptomyces avermitilis produces a group of glycosylated, methylated macrocyclic lactones, the avermectins, which have potent anthelmintic activity. A homologous recombination strategy termed gene cluster displacement was used to construct Neor deletion strains with defined endpoints and to clone the corresponding complementary DNA encoding functions for avermectin biosynthesis (avr). Thirty-five unique deletions of 0.5 to > 100 kb over a continuous 150-kb region were introduced into S. avermitilis. Analysis of the avermectin phenotypes of the deletion-containing strains defined the extent and ends of the 95-kb avr gene cluster, identified a regulatory region, and mapped several avr functions. A 60-kb region in the central portion determines the synthesis of the macrolide ring. A 13-kb region at one end of the cluster is responsible for synthesis and attachment of oleandrose disaccharide. A 10-kb region at the other end has functions for positive regulation and C-5 O methylation. Physical analysis of the deletions and of in vivo-cloned fragments refined a 130-kb physical map of the avr gene cluster region.

Synthesis of hydrolytic enzymes during production of tylosin by Streptomyces fradiae

The exposure of a wild-type tylosin producing strain of Streptomyces fradiae to mutagenic agents resulted in the isolation of several tylosin over-producing strains. Examination of three mutants, T4310, 612 and 3204 showed that improved tylosin production was associated with increased hydrolytic enzyme activity and cell growth. The wild-type strain showed lower levels of hydrolytic activity including, protease, amylase, lipase and esterase activities and attained a lower cell density than the mutants.

Transcription and cancer

The normal growth, development and function of an organism requires precise and co-ordinated control of gene expression. A major part of this control is exerted by regulating messenger RNA (mRNA) production and involves complex interactions between an array of transcriptionally active proteins and specific regulatory DNA sequences. The combination of such proteins and DNA sequences is specific for given gene or group of genes in a particular cell type and the proteins regulating the same gene may vary between cell types. In addition the expression or activity of these regulatory proteins may be modified depending on the state of differentiation of a cell or in response to an external stimulus. Thus, the differentiation of embryonic cells into diverse tissues is achieved and the mature structure and function of the organism is maintained. This review focusses on the role of perturbations of these transcriptional controls in neoplasia. Deregulation of transcription may result in the failure to express genes responsible for cellular differentiation, or alternatively, in the transcription of genes involved in cell division, through the inappropriate expression or activation of positively acting transcription factors and nuclear oncogenes. Whether the biochemical abnormalities that lead to the disordered growth and differentiation of a malignant tumour affect cell surface receptors, membrane or cytoplasmic signalling proteins or nuclear transcription factors, the end result is the inappropriate expression of some genes and failure to express others. Current research is starting to elucidate which of the elements of this complicated system are important in neoplasia.

Cloning and characterization of the isopenicillin N synthase gene of Streptomyces griseus NRRL 3851 and studies of expression and complementation of the cephamycin pathway in Streptomyces clavuligerus

A gene, pcbC, encoding the isopenicillin N synthase of Streptomyces griseus NRRL 3851, has been cloned in a 6.4-kb Bg/II DNA fragment and located in an internal 1.55-kb PvuII segment by hybridization with the Penicillium chrysogenum pcbC gene. Hybridization studies revealed the presence of homologous sequences in the DNAs of several Streptomyces strains and Nocardia lactamdurans. The S. griseus pcbC gene was not expressed in Streptomyces lividans but was expressed in Streptomyces clavuligerus and complemented a mutation, nce2, that impaired isopenicillin N synthase and cephamycin biosynthesis. The pcbC gene contained an open reading frame of 990 nucleotides that encodes a protein of 329 amino acids with a deduced Mr of 37,371. The isopenicillin N synthase formed after expression of the pcbC gene in the S. clavuligerus nce2 mutant strain was found to have an Mr of 38,000 by gel filtration. A protein of about 38 kDa was observed in sodium dodecyl sulfate-polyacrylamide gel electrophoresis gels of extracts of a transformant of the nce2 mutant strain; this protein was absent from the untransformed mutant strain. The G+C content of the pcbC gene was 63.6%, and the strongly biased codon usage was typical of that of Streptomyces strains. A transcription initiation site was found 44 nucleotides upstream of the ATG translation initiation triplet. A transcript of 1.1 kb was observed in the donor S. griseus strain and also in the S. clavuligerus nce2 mutant strain transformed with the pcbC gene, suggesting that it is transcribed as a monocistronic mRNA.

Genetic complementation of Streptomyces tendae deficient in nikkomycin production

Streptomyces tendae Tü 901 produces the nucleoside peptide antibiotic nikkomycin. In shot-gun cloning experiments using pIJ699 as vector we isolated a 9.4-kb DNA fragment from S. tendae which complemented the nikkomycin nonproducing mutant NP9 to the formation of nikkomycin C/Cx and Kx. Nikkomycins were identified by HPLC analyses and their characteristic UV spectra. In Southern hybridization experiments the cloned DNA exclusively reacted with S. tendae DNA sequences. As shown by Northern dot blotting, transcripts of the isolated DNA fragment were only detected during stationary growth and correlated with the extent of nikkomycin production. When the recombinant plasmid pNP113 containing the 9.4-kb DNA fragment was transferred into the over-producing mutant Tü901/S2566, transformants exhibited a significantly decreased capacity for forming nikkomycin. Southern analysis of genomic DNA of these transformants revealed that severe rearrangements occurred in DNA sequences homologous to the 9.4-kb insert of pNP113.

Branched-chain fatty acids produced by mutants of Streptomyces fradiae, putative precursors of the lactone ring of tylosin

Three branched-chain fatty acids (7-hydroxy-4,6-dimethylnona-2,4-dienoic acid [compound 1], its 7-epimer [compound 2], and 7-keto-4,6-dimethylnona-2,4-dienoic acid [compound 3]) and a ketone (9-hydroxy-6,8-dimethylundeca-4,6-dien-3-one [compound 4]) were isolated from the culture broth of mutants of Streptomyces fradiae which were blocked in the biosynthesis of the macrolide antibiotic tylosin. Two phenotypic classes of mutants of this organism which were blocked in the addition of mycaminose to tylactone (compound 6) accumulated these compounds. These compounds were not produced by mutants which were blocked in lactone synthesis, in steps beyond mycaminose addition, or by the wild-type strain. Synthesis of these compounds, like synthesis of tylosin, was inhibited by the addition of cerulenin. Compounds 1, 2, and 3 were partially interconvertible by these mutants; but they were not produced from the degradation of tylactone and they were not directly incorporated into tylosin by intact cells. The structures of compounds 1 and 2 were equivalent to that of a predicted intermediate (S. Yue, J. S. Duncan, Y. Yamamoto, and C. R. Hutchinson, J. Am. Chem. Soc. 109:1253-1255, 1987) in the biosynthesis of tylactone. The ketone (compound 4) reported previously (N. D. Jones, M. O. Chaney, H. A. Kirst, G. M. Wild, R. H. Baltz, R. L. Hamill, and J. W. Paschal, J. Antibiot. 35:420-425, 1982) appears to be the decarboxylation product of the intermediate following that represented by compound 1. This represents the first report of the isolation of putative precursors of tylactone from tylosin-producing organisms.

Cloning of spiramycin biosynthetic genes and their use in constructing Streptomyces ambofaciens mutants defective in spiramycin biosynthesis

Several cosmid clones from Streptomyces ambofaciens containing the spiramycin resistance gene srmB were introduced into S. fradiae PM73, a mutant defective in tylosin synthesis, resulting in tylosin synthesis. The DNA responsible for this complementation was localized to a 10.5-kilobase EcoRI fragment. A 32-kilobase DNA segment which included the srmB spiramycin resistance gene and DNA which complemented the defect in strain PM73 were mutagenized in vivo with Tn10 carrying the gene for Nmr (which is expressed in Streptomyces spp.) or in vitro by insertional mutagenesis with a drug resistance gene (Nmr) cassette. When these mutagenized DNA segments were crossed into the S. ambofaciens chromosome, three mutant classes blocked in spiramycin synthesis were obtained. One mutant accumulated two precursors of spiramycin, platenolide I and platenolide II. Two mutants, when cofermented with the platenolide-accumulating mutant, produced spiramycin. Tylactone supplementation of these two mutants resulted in the synthesis of a group of compounds exhibiting antibiotic activity. Two other mutants failed to coferment with any of the other mutants or to respond to tylactone supplementation.

The Improving Prospects for Yield Increase by Genetic Engineering in Antibiotic-Producing Streptomycetes

Molecular genetics has spawned a dramatic expansion of the biotechnology industry in the direction of the products of single genes. On the other hand, antibiotics--some of the classical products of biotechnology--result from the concerted action of many genes, and it is therefore less straightforward to apply the new techniques to antibiotic production. Studies of cloned genes for antibiotic biosynthesis are now providing information that should allow the application of a combination of traditional and recombinant DNA methodology to the improvement of yield in antibiotic-producing Streptomyces species.

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.

Cloning of genes governing the deoxysugar portion of the erythromycin biosynthesis pathway in Saccharopolyspora erythraea (Streptomyces erythreus)

Genes that govern the formation of deoxysugars or their attachment to erythronolide B and 3 alpha-mycarosyl erythronolide B, intermediates of the biosynthesis of the 14-membered macrolide antibiotic erythromycin, were cloned from Saccharopolyspora erythraea (formerly Streptomyces erythreus). Segments of DNA that complement the eryB25, eryB26, eryB46, eryC1-60, and eryD24 mutations blocking the formation of erythronolide B or 3 alpha-mycarosyl erythronolide B, when cloned in Escherichia coli-Streptomyces shuttle cosmids or plasmid vectors that can transform S. erythraea, were located in a ca. 18-kilobase-pair region upstream of the erythromycin resistance (ermE) gene. The eryC1 gene lies just to the 5' side of ermE, and one (or possibly two) eryB gene is approximately 12 kilobase pairs farther upstream. Another eryB gene may be in the same region, while an additional eryB mutation appears to be located elsewhere. The eryD gene lies between the eryB and eryC1 genes and may regulate their function on the basis of the phenotype of an EryD- mutant.

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

From a genomic library of the tyrocidine producer Bacillus brevis ATCC 8185 constructed in the bacteriophage vector EMBL3, a recombinant phage which contains the structural genes coding for tyrocidine synthetases 1 and 2, TycA and TycB, was identified. The location of the tycA gene within the 16-kilobase insert of this clone, EMBL25-1, was mapped by hybridization studies by using the previously isolated tycA DNA as a probe. Restriction analyses, the construction of subclones, and the analysis of proteins encoded by the subclones located the tycB gene at the 3' end of the tycA gene and revealed that the two genes are transcribed in the same direction. Nuclease S1 protection studies and DNA sequencing studies of the intergenic region indicated that tycA and tycB are separated by a 94-base-pair noncoding region and suggested that these genes are organized as an operon.

Transduction and transformation of plasmid DNA in Streptomyces fradiae strains that express different levels of restriction

We constructed nonrestricting strains of Streptomyces fradiae blocked in different steps in tylosin biosynthesis. Plasmid transformation frequencies were 10(3)- to 10(4)-fold higher and bacteriophage plating efficiencies were 10(4)- to 10(8)-fold higher in the nonrestricting strains than in the restricting strains. The efficiencies of transduction of plasmid pRHB101 in S. fradiae strains varied by over 1,000-fold, depending on growth conditions, and optimum transduction frequencies were obtained when cells were grown to mid-exponential phase at 39 degrees C. Under these conditions, restricting and nonrestricting strains were transduced at frequencies that differed by only two- to fivefold.

Cloning, characterization, and expression in Escherichia coli of the Streptomyces clavuligerus gene encoding deacetoxycephalosporin C synthetase

Biosynthesis of cephalosporin antibiotics involves an expansion of the five-membered thiazolidine ring of penicillin N to the six-membered dihydrothiazine ring of deacetoxycephalosporin C by a deacetoxycephalosporin C synthetase (DAOCS) enzyme activity. Hydroxylation of deacetoxycephalosporin C to form deacetylcephalosporin C by a deacetylcephalosporin C synthetase (DACS) activity is the next step in biosynthesis of cephalosporins. In Cephalosporium acremonium, both of these catalytic activities are exhibited by a bifunctional enzyme, DAOCS-DACS, encoded by a single gene, cefEF. In Streptomyces clavuligerus, separable enzymes, DAOCS (expandase) and DACS (hydroxylase), catalyze these respective reactions. We have cloned, sequenced, and expressed in E. coli an S. clavuligerus gene, designated cefE, which encodes DAOCS but not DACS. The deduced amino acid sequence of DAOCS from S. clavuligerus (calculated Mr of 34,519) shows marked similarity (approximately 57%) to the deduced sequence of DAOCS-DACS from C. acremonium; however, the latter sequence is longer by 21 amino acid residues.

Cloning and characterization of the gene for immunogenic protein MPB64 of Mycobacterium bovis BCG

The gene for immunogenic protein MPB64 found in culture filtrates of only Mycobacterium tuberculosis and some strains of Mycobacterium bovis BCG was cloned by using a single-probe method and was sequenced. The gene analysis revealed that the structural gene for MPB64 consisted of 618 base pairs, and its deduced molecular weight was 22,400. Twenty-two amino acids for a putative signal peptide and 205 amino acids for the MPB64 protein were observed. In the coding region, the third letter of the codon showed a biased codon and a high G+C content (78.5%). The gene was expressed in Escherichia coli by using an E. coli expression vector. The product showed migration similar to that of the authentic MPB64 protein by electrophoresis and reacted with the polyclonal and the monoclonal antibodies raised against the MPB64 protein. The strict specificity of MPB64 could be applied to immunodiagnosis of tuberculosis.

Organization of the biosynthesis genes for the peptide antibiotic gramicidin S

A recombinant bacteriophage containing the intact Bacillus brevis gene for gramicidin S synthetase 1, grsA, and the 5' end of the gramicidin S synthetase 2 gene, grsB, was identified by screening an EMBL3 library with anti-GrsA antibodies. This clone, EMBL315, has a 14-kilobase (kb) insert that hybridizes to the previously isolated 3.9-kb fragment of the grsB gene, which encodes the 155-kilodalton ornithine-activating domain of gramicidin S synthetase 2. Deletion and subcloning experiments with the 14-kb insert located the grsA structural gene and its putative promoter on a 4.5-kb PvuII fragment which encoded the full-length 120-kilodalton protein in Escherichia coli. In addition, hybridization analysis revealed that the 5' end of the grsB gene is located approximately 3 kb from the grsA structural gene. Furthermore, these studies indicated that grsA and grsB are transcribed in opposite orientations.

Cloning and expression of the Mycobacterium bovis BCG gene for extracellular alpha antigen

The gene for the extracellular alpha antigen of Mycobacterium bovis BCG was cloned by using a single probe restricted to G or C in the third position. This technique should have great potential for the isolation of mycobacterial antigen genes. The gene analysis revealed that the alpha antigen gene encoded 323 amino acid residues, including 40 amino acids for signal peptide followed by 283 amino acids for mature protein. This is the first report on the structure of the mycobacterial signal peptide. The promoter-like sequence and ribosome-binding site were observed upstream of the open reading frame. In the coding region, the third position of the codon showed high G + C content (86%). The gene was expressed as an unfused protein in Escherichia coli by using an E. coli expression vector. This protein, which reacted with polyclonal antibody raised against alpha antigen from Mycobacterium tuberculosis, would be applicable to the immunodiagnosis of tuberculosis.

The impact of genetic engineering on the commercial production of antibiotics by Streptomyces and related bacteria

Developments in Streptomyces genetics that have laid a foundation for this field over the past ten years are reviewed and discussed to suggest how this knowledge might useful for improving the commercial production of antibiotics. This brief analysis predicts a bright future for the application of Streptomyces genetics in antibiotic production.