Mutational cloning in Streptomyces and the isolation of antibiotic production genes

Combinatorial biosynthesis: playing chess with the metabolism

Secondary metabolites are a group of natural products that produced by bacteria, fungi and plants. Many applications of these compounds from medicine to industry have been discovered. However, some changes in their structure and biosynthesis mechanism are necessary for their properties to be more suitable and also for their production to be profitable. The main and most useful method to achieve this goal is combinatorial biosynthesis. This technique uses the multi-unit essence of the secondary metabolites biosynthetic enzymes to make changes in their order, structure and also the organism that produces them.

RNase III is required for actinomycin production in Streptomyces antibioticus

Using insertional mutagenesis, we have disrupted the RNase III gene, rnc, of the actinomycin-producing streptomycete, Streptomyces antibioticus. Disruption was verified by Southern blotting. The resulting strain grows more vigorously than its parent on actinomycin production medium but produces significantly lower levels of actinomycin. Complementation of the rnc disruption with the wild-type rnc gene from S. antibioticus restored actinomycin production to nearly wild-type levels. Western blotting experiments demonstrated that the disruptant did not produce full-length or truncated forms of RNase III. Thus, as is the case in Streptomyces coelicolor, RNase III is required for antibiotic production in S. antibioticus. No differences in the chemical half-lives of bulk mRNA were observed in a comparison of the S. antibioticus rnc mutant and its parental strain.

Chapter 4. Analyzing the regulation of antibiotic production in streptomycetes

This chapter outlines the approaches and techniques that can be used to analyze the regulation of antibiotic production in streptomycetes. It describes how to isolate antibiotic nonproducing and overproducing mutants by UV, nitrosoguanidine (NTG), transposon, and insertion mutagenesis, and then how to use those mutants to identify regulatory genes. Other approaches to identify both pathway-specific and pleiotropic regulatory genes include overexpression and genome scanning. A variety of methods used to characterize pathway-specific regulatory genes for antibiotic biosynthesis are then covered, including transcriptional analysis and techniques that can be used to distinguish between direct and indirect regulation. Finally, genome-wide approaches that can be taken to characterize pleiotropic regulatory genes, including microarray and ChIP-on-Chip technologies, are described.

Extracellular signalling, translational control, two repressors and an activator all contribute to the regulation of methylenomycin production in Streptomyces coelicolor

Bioinformatic analysis of the plasmid-linked gene cluster associated with biosynthesis of methylenomycin (Mm) suggested that part of the cluster directs synthesis of a gamma-butyrolactone-like autoregulator. Autoregulator activity could be extracted from culture fluids, but differed from gamma-butyrolactones in being alkali resistant. The activity has recently been shown to comprise a series of novel autoregulator molecules, the methylenomycin furans (termed MMF). MMF autoregulator activity is shown to account for the ability of certain Mm non-producing mutants to act as 'secretors' in cosynthesis with other 'convertor' mutants. Three genes implicated in MMF biosynthesis are flanked by two regulatory genes, which are related to genes for gamma-butyrolactone-binding proteins. Genetic evidence suggests that these two genes encode components of a hetero-oligomeric repressor of MMF and Mm biosynthesis. The Mm biosynthetic genes themselves depend on the activator gene mmyB, which appears to be repressed by the putative MmyR/MmfR complex until enough MMF accumulates to release repression. The presence of TTA codons in mmyB and the main MMF biosynthetic gene causes Mm production to be dependent on the pleiotropically acting bldA gene, which encodes the tRNA for the rarely used UUA codon.

Genomewide insertional mutagenesis in Streptomyces coelicolor reveals additional genes involved in morphological differentiation

The filamentous soil bacterium Streptomyces coelicolor undergoes a complex cycle of morphological differentiation involving the formation of an aerial mycelium and the production of pigmented antibiotics. We have developed a procedure for generating insertional mutants of S. coelicolor based on in vitro transposition of a plasmid library of cloned S. coelicolor DNAs. The insertionally mutated library was introduced into S. coelicolor, and transposon insertions were recovered at widely scattered locations around the chromosome. Many of the insertions revealed previously uncharacterized genes, and several caused novel mutant phenotypes, such as altered pigment production, enhanced antibiotic sensitivity, delayed or impaired formation of aerial hyphae, and a block in spore formation. The sporulation mutant harbored an insertion in one of three adjacent genes that are apparently unique to Streptomyces but are each represented by at least 20 paralogs at dispersed locations in the chromosome. Individual members of the three families often are found grouped together in a characteristic arrangement, suggesting that they have a common function.

Actinomycin production persists in a strain of Streptomyces antibioticus lacking phenoxazinone synthase

Truncated fragments of the phenoxazinone synthase gene, phsA, were prepared by the PCR. The resulting fragments were cloned into conjugative plasmid pKC1132 and transferred to Streptomyces antibioticus by conjugation from Escherichia coli. Two of the resulting constructs were integrated into the S. antibioticus chromosome by homologous recombination, and each of the resulting strains, designated 3720/pJSE173 and 3720/pJSE174, contained a disrupted phsA gene. Strain 3720/pJSE173 grew poorly, and Southern blotting suggested that genetic changes other than the disruption of the phsA gene might have occurred during the construction of that strain. Strain 3720/pJSE174 sporulated well and grew normally on the medium used to prepare inocula for antibiotic production. Strain 3720/pJSE174 also grew as well as the wild-type strain on antibiotic production medium containing either 1 or 5.7 mM phosphate. Strain 3720/pJSE174 was shown to be devoid of phenoxazinone synthase (PHS) activity, and PHS protein was undetectable in this strain by Western blotting. Despite the absence of detectable PHS activity, strain 3720/pJSE174 produced slightly more actinomycin than did the wild-type parent strain in medium containing 1 or 5.7 mM phosphate. The observation that strain 3720/pJSE174, lacking detectable PHS protein or enzyme activity, retained the ability to produce actinomycin supports the conclusion that PHS is not required for actinomycin biosynthesis in S. antibioticus.

An additional regulatory gene for actinorhodin production in Streptomyces lividans involves a LysR-type transcriptional regulator

The sequence of a 4.8-kbp DNA fragment adjacent to the right-hand end of the actinorhodin biosynthetic (act) cluster downstream of actVB-orf6 from Streptomyces coelicolor A3(2) reveals six complete open reading frames, named orf7 to orf12. The deduced amino acid sequences from orf7, orf10, and orf11 show significant similarities with the following products in the databases: a putative protein from the S. coelicolor SCP3 plasmid, LysR-type transcriptional regulators, and proteins belonging to the family of short-chain dehydrogenases/reductases, respectively. The deduced product of orf8 reveals low similarities with several methyltransferases from different sources, while orf9 and orf12 products show no similarities with other known proteins. Disruptions of orf10 and orf11 genes in S. coelicolor appear to have no significant effect on the production of actinorhodin. Nevertheless, disruption or deletion of orf10 in Streptomyces lividans causes actinorhodin overproduction. The introduction of extra copies of orf10 and orf11 genes in an S. coelicolor actIII mutant restores the ability to produce actinorhodin. Transcriptional analysis and DNA footprinting indicate that Orf10 represses its own transcription and regulates orf11 transcription, expression of which might require the presence of an unknown inducer. No DNA target for Orf10 protein was found within the act cluster.

Proof that the ACTVI genetic region of Streptomyces coelicolor A3(2) is involved in stereospecific pyran ring formation in the biosynthesis of actinorhodin

Pyran ring formation in the biosynthesis of actinorhodin in Streptomyces coelicolor A3(2) was studied using the act cluster deficient strain, CH999, carrying pRM5-based plasmids harbouring combinations of the actVI genes. The strain, CH999/pIJ5660 (pRM5 + actVI-ORF1), produced a chiral intermediate, (S)-DNPA, suggesting that the actVI-ORF1 product is a reductase determining the C-3 stereochemical centre.

A silent ABC transporter isolated from Streptomyces rochei F20 induces multidrug resistance

In the search for heterologous activators for actinorhodin production in Streptomyces lividans, 3.4 kb of DNA from Streptomyces rochei F20 (a streptothricin producer) were characterized. Subcloning experiments showed that the minimal DNA fragment required for activation was 0.4 kb in size. The activation is mediated by increasing the levels of transcription of the actII-ORF4 gene. Sequencing of the minimal activating fragment did not reveal any clues about its mechanism; nevertheless, it was shown to overlap the 3' end of two convergent genes, one of whose translated products (ORF2) strongly resembles that of other genes belonging to the ABC transporter superfamily. Computer-assisted analysis of the 3.4-kb DNA sequence showed the 3' terminus of an open reading frame (ORF), i.e., ORFA, and three complete ORFs (ORF1, ORF2, and ORFB). Searches in the databases with their respective gene products revealed similarities for ORF1 and ORF2 with ATP-binding proteins and transmembrane proteins, respectively, which are found in members of the ABC transporter superfamily. No similarities for ORFA and ORFB were found in the databases. Insertional inactivation of ORF1 and ORF2, their transcription analysis, and their cloning in heterologous hosts suggested that these genes were not expressed under our experimental conditions; however, cloning of ORF1 and ORF2 together (but not separately) under the control of an expressing promoter induced resistance to several chemically different drugs: oleandomycin, erythromycin, spiramycin, doxorubicin, and tetracycline. Thus, this genetic system, named msr, is a new bacterial multidrug ABC transporter.

Transcriptional regulation of Streptomyces coelicolor pathway-specific antibiotic regulators by the absA and absB loci

The four antibiotics produced by Streptomyces coelicolor are all affected by mutations in the absA and absB loci. The absA locus encodes a putative two-component signal transduction system, and the absB locus encodes a homolog of Escherichia coli RNase III. We assessed whether these loci control synthesis of the antibiotics actinorhodin and undecylprodigiosin by regulating transcript abundance from the biosynthetic and regulatory genes specific for each antibiotic. Strains that were Abs- (for antibiotic synthesis deficient) due to mutations in absA or absB were examined. In the Abs- absA mutant strain, transcripts for the actinorhodin biosynthetic genes actVI-ORF1 and actI, and for the pathway-specific regulatory gene actII-ORF4, were substantially lower in abundance than in the parent strain. The level of the transcript for the undecylprodigiosin pathway-specific regulatory gene redD was similarly reduced in this mutant. Additionally, a strain that exhibits precocious hyperproduction of antibiotics (Pha phenotype) due to disruption of the absA locus contained elevated levels of the actVI-ORF1, actII-ORF4, and redD transcripts. In the absB mutant strain, actVI-ORF1, actI, actII-ORF4, and redD transcript levels were also substantially lower than in the parent strain. These results establish that the abs genes affect production of antibiotics through regulation of expression of the antibiotic-specific regulatory genes in S. coelicolor.

Streptothricin biosynthesis is catalyzed by enzymes related to nonribosomal peptide bond formation

In a search for strains producing biocides with a wide spectrum of activity, a new strain was isolated. This strain was taxonomically characterized as Streptomyces rochei F20, and the chemical structure of the bioactive product extracted from its fermentation broth was determined to be a mixture of streptothricins. From a genomic library of the producer strain prepared in the heterologous host Streptomyces lividans, a 7.2-kb DNA fragment which conferred resistance to the antibiotic was isolated. DNA sequencing of 5.2 kb from the cloned fragment revealed five open reading frames (ORFs) such that ORF1, -2, -3, and -4 were transcribed in the same direction while ORF5 was convergently arranged. The deduced product of ORF1 strongly resembled those of genes involved in peptide formation by a nonribosomal mechanism; the ORF2 product strongly resembled that of mphA and mphB isolated from Escherichia coli, which determines resistance to several macrolides by a macrolide 2'-phosphotransferase activity; the ORF3 product had similarities with several hydrolases; and the ORF5 product strongly resembled streptothricin acetyltransferases from different gram-positive and gram-negative bacteria. ORF5 was shown to be responsible for acetyl coenzyme A-dependent streptothricin acetylation. No similarities in the databases for the ORF4 product were found. Unlike other peptide synthases, that for streptothricin biosynthesis was arranged as a multienzymatic system rather than a multifunctional protein. Insertional inactivation of ORF1 and ORF2 (and to a lesser degree, of ORF3) abolishes antibiotic biosynthesis, suggesting their involvement in the streptothricin biosynthetic pathway.

Regulation of the dnaK operon of Streptomyces coelicolor A3(2) is governed by HspR, an autoregulatory repressor protein

The dnaK operon of Streptomyces coelicolor contains four genes (5'-dnaK-grpE-dnaJ-hspR). The fourth gene encodes a novel heat shock protein, HspR, which appears so far to be unique to the high-G+C actinomycete group of bacteria. HspR binds with high specificity to three inverted repeat sequences in the promoter region of the S. coelicolor dnaK operon, strongly suggesting a direct role for HspR in heat shock gene regulation. Here we present genetic and biochemical evidence that HspR is the repressor of the dnaK operon. Disruption of hspR leads to high-level constitutive transcription of the dnaK operon. Parallel transcriptional analyses of groESL1 and groEL2 expression demonstrated that heat shock regulation of the groE genes was essentially unaffected in an hspR null mutant, although the basal (uninduced) level of groEL2 transcription was slightly elevated compared with the wild type. The results of HspR titration experiments, where the dnaK operon promoter region was cloned at ca. 50 copies per chromosome, were consistent with the prediction that HspR functions as a negative autoregulator. His-tagged HspR, overproduced and purified from Escherichia coli, was shown to repress transcription from the dnaK operon promoter in vitro, providing additional evidence for the proposal that HspR directly regulates transcription of the dnaK operon. These studies indicate that there are at least two transcriptional mechanisms for controlling heat shock genes in S. coelicolor--one controlling the dnaK operon and another controlling the groE genes.

Suicide plasmids containing promoterless reporter genes can simultaneously disrupt and create fusions to target genes of diverse bacteria

We describe several plasmids that are designed to create fusions between chromosomal or plasmid-encoded genes and the lacZ, phoA or gfp reporter genes. These plasmids all contain the vegetative origin of R6K, but lack the R6K pir gene, and therefore fail to replicate in strains lacking pir. Fragments of target genes are introduced into these plasmids, and fusions are created in a single step as a consequence of (Campbell-type) integration of the entire plasmid by homologous recombination. Cloned fragments containing either an intact 5'-end of the target gene including its promoter or an intact 3'-end of the gene preserve a functional copy of that gene, while fragments lacking both 5'- and 3'-ends of the target gene cause a gene disruption. In addition to facilitating measurements of gene expression, some plasmids create translational fusions to beta-galactosidase or alkaline phosphatase and are therefore useful in studying the membrane topology of a target protein. We demonstrate the utility of these plasmids by constructing and testing two operon fusions and two protein fusions between the virG gene of Agrobacterium tumefaciens and lacZ.

Gene disruption and replacement in the rapamycin-producing Streptomyces hygroscopicus strain ATCC 29253

A system for gene disruption and replacement based on a streptomycete temperate phage vector was developed to introduce DNA in the rapamycin-producing Streptomyces hygroscopicus strain ATCC 29253. This will be useful in attempts to produce, through genetic manipulation, novel forms of the therapeutically important immunosuppressive drug rapamycin. Recombinant phages were constructed from the phi C31 phage derivative KC515 (C+ attp) carrying a thiostrepton or viomycin resistance gene along with segments of the S. hygroscopicus chromosome. Each of the cloned segments also contained the aphll neomycin/kanamycin resistance gene to enable gene replacement by loss of the phage-derived DNA. Specific deletion of the entire polyketide synthase (PKS) believed to govern rapamycin biosynthesis resulted in the loss of rapamycin production. In contrast, disruption or deletion of a region predicted to encode four PKS open reading frames, or another region predicted to encode another PKS plus a cytochrome P450 hydroxylase and ferredoxin, had no effect on the production of rapamycin or nigericin, a polyether antibiotic also produced by S. hygroscopicus. Therefore, S. hygroscopicus may have the capacity to produce polyketides additional to rapamycin and nigericin.

Denaturation of circular or linear DNA facilitates targeted integrative transformation of Streptomyces coelicolor A3(2): possible relevance to other organisms

Using Streptomyces coelicolor A3(2) protoplasts, the number of transformants obtained by homologous recombination of incoming double-stranded circular DNA with the recipient chromosome was greatly stimulated by simple denaturation of the donor DNA. This procedure was very effective with inserts over a ca. 100-fold size range, the largest tested being ca. 40-kb inserts in cosmids. These observations led to transformation experiments with linearized cloned DNA and randomly sheared genomic DNA. In both cases, DNA denaturation led to significant levels of transformation. Most of the transformants had resulted from the predicted homologous recombination events. A number of genetic manipulations will be made easier or possible by these procedures.

A novel plasmid vector that uses the glucose kinase gene (glkA) for the positive selection of stable gene disruptants in Streptomyces

We describe an Escherichia coli plasmid, pIJ2581, that can be used for the efficient construction of stable gene disruptants and of gene deletions in Streptomyces. Integration of pIJ2581 derivatives carrying chromosomal sequences is achieved by selecting for plasmid-encoded thiostrepton resistance, while plasmid excision is secured by counter-selection of the pIJ2581 glkA gene, which confers sensitivity to 2-deoxyglucose.

The Streptomyces peucetius drrC gene encodes a UvrA-like protein involved in daunorubicin resistance and production

The drrC gene, cloned from the daunorubicin (DNR)- and doxorubicin-producing strain of Streptomyces peucetius ATCC 29050, encodes a 764-amino-acid protein with a strong sequence similarity to the Escherichia coli and Micrococcus luteus UvrA proteins involved in excision repair of DNA. Expression of drrC was correlated with the timing of DNR production in the growth medium tested and was not dependent on the presence of DNR. Since introduction of drrC into Streptomyces lividans imparted a DNR resistance phenotype, this gene is believed to be a DNR resistance gene. The drrC gene could be disrupted in the non-DNR-producing S. peucetius dnrJ mutant but not in the wild-type strain, and the resulting dnrJ drrC double mutant was significantly more sensitive to DNR in efficiency-of-plating experiments. Expression of drrC in an E. coli uvrA strain conferred significant DNR resistance to this highly DNR-sensitive mutant. However, the DrrC protein did not complement the uvrA mutation to protect the mutant from the lethal effects of UV or mitomycin even though it enhanced the UV resistance of a uvrA+ strain. We speculate that the DrrC protein mediates a novel type of DNR resistance, possibly different from the mechanism of DNR resistance governed by the S. peucetius drrAB genes, which are believed to encode a DNR antiporter.

Global negative regulation of Streptomyces coelicolor antibiotic synthesis mediated by an absA-encoded putative signal transduction system

Streptomycete antibiotic synthesis is coupled to morphological differentiation such that antibiotics are produced as a colony sporulates. Streptomyces coelicolor produces several structurally and genetically distinct antibiotics. The S. coelicolor absA locus was defined by four UV-induced mutations that globally blocked antibiotic biosynthesis without blocking morphological differentiation. We show that the absA locus encodes a putative eubacterial two-component sensor kinase-response regulator system. All four mutations lie within a single open reading frame, designated absA1, which is predicted to encode a sensor histidine kinase. A second gene downstream of absA1, absA2, is predicted to encode the cognate response regulator. In marked contrast to the antibiotic-deficient phenotype of the previously described absA mutants, the phenotype caused by disruption mutations in the absA locus is precocious hyperproduction of the antibiotics actinorhodin and undecylprodigiosin. Precocious hyperproduction of these antibiotics is correlated with premature expression of XylE activity in a transcriptional fusion to an actinorhodin biosynthetic gene. We propose that the absA locus encodes a signal transduction mechanism that negatively regulates synthesis of the multiple antibiotics produced by S. coelicolor.

A relA/spoT homologous gene from Streptomyces coelicolor A3(2) controls antibiotic biosynthetic genes

A 0.972-kilobase pair DNA fragment from Streptomyces lividans that induces the production of the blue-pigmented antibiotic actinorhodine in S. lividans when cloned on a multicopy plasmid has led to the isolation of a 4-kilobase pair DNA fragment from Streptomyces coelicolor containing homologous sequence. Computer-assisted analysis of the DNA sequence revealed three putative open reading frames (ORFs), ORF1, ORF2, and ORF3. ORF2 extends beyond the sequenced DNA fragment, and its deduced product shares no similarities with any other known proteins in the data bases. ORF3 is also truncated, and its 41-amino acid C-terminal product is identical to the S. coelicolor adenine phosphoribosyltransferase. The 847-amino acid ORF1 protein, with a predicted molecular mass of 94.2 kDa, strongly resembled the relA and spoT gene products from Escherichia coli and the homologs from Vibrio sp. strain S14, Haemophilus influenzae, Streptococcus equisimilis H46A, and Mycoplasma genitalium. Unlike these proteins, the ORF1 amino acid sequence analysis revealed the presence of a putative ATP/GTP-binding domain. A mutant was generated by deleting most of the ORF1 gene that showed an actinorhodine-nonproducing phenotype, while undecylprodigiosin and the calcium-dependent antibiotic were unaffected. The mutant strain grew at a much lower rate than the wild-type strain, and spore formation was delayed. When the gene was propagated on a low copy number vector, not only was actinorhodine production restored, but actinorhodine and undecylprodigiosin production was enhanced in both the mutant and wild-type and morphological differentiation returned to wild-type characteristics. (p)ppGpp synthetase activity was not detected in purified ribosomes from the ORF1-deleted mutant, while it was restored by complementation of this strain.

Two genes involved in the phase-variable phi C31 resistance mechanism of Streptomyces coelicolor A3(2)

The phage growth limitation (Pgl) system of Streptomyces coelicolor confers resistance to phi C31 and its homoimmune phages. The positions of the pgl genes within a 16-kb clone of S. coelicolor DNA were defined by subcloning, insertional inactivation, and deletion mapping. Nucleotide sequencing and functional analysis identified two genes, pglY and pglZ, required for the Pgl+ (phage-resistant) phenotype. pglY and pglZ, which may be translationally coupled, are predicted to encode proteins with M(r)S of 141,000 and 104,000, respectively. Neither protein shows significant similarity to other known proteins, but PglY has a putative ATP/GTP binding motif. The pglY and pglZ genes are cotranscribed from a single promoter which appears to be constitutive and is not induced by phage infection.

Purification of a malonyltransferase from Streptomyces coelicolor A3(2) and analysis of its genetic determinant

Streptomyces coelicolor A3(2) synthesizes each half molecule of the dimeric polyketide antibiotic actinorhodin (Act) from one acetyl and seven malonyl building units, catalyzed by the Act polyketide synthase (PKS). The synthesis is analogous to fatty acid biosynthesis, and there is evident structural similarity between PKSs of Streptomyces spp. and fatty acid synthases (FASs). Each system should depend on a malonyl coenzyme A:acyl carrier protein malonyltransferase, which charges the FAS or PKS with the malonyl units for carbon chain extension. We have purified the Act acyl carrier protein-dependent malonyltransferase from stationary-phase, Act-producing cultures and have determined the N-terminal amino acid sequence and cloned the structural gene. The deduced amino acid sequence resembles those of known malonyltransferases of FASs and PKSs. The gene lies some 2.8 Mb from the rest of the act cluster, adjacent to an open reading frame whose gene product resembles ketoacylsynthase III of Escherichia coli FAS. The malonyltransferase was expressed equally as well during vegetative growth (when other components of the act PKS were not expressed) as in the stationary phase, suggesting that the malonyltransferase may be shared between the FAS and PKS of S. coelicolor. Disruption of the operon containing the malonyltransferase gene proved to be impossible, supporting the idea that the malonyltransferase plays an essential role in fatty acid biosynthesis.

High-frequency homologous plasmid-plasmid recombination coupled with conjugation of plasmid SCP2* in Streptomyces

Non-transmissible derivatives of the Streptomyces multi-copy plasmid plJ101 were mobilized, by cointegrate formation, at frequencies approaching 100% (measured per recipient) by derivatives of the conjugative, low-copy-number Streptomyces coelicolor A3(2) plasmid SCP2*. Efficient co-integrate formation required that the plasmids shared at least 112 bp sequence identity, and it occurred only during conjugation. An SCP2* plasmid gene is involved in the process. Co-integrates were presumably formed in the donor cells and transported to the recipient cells. This is a new phenomenon, not known in other bacteria.

Cloning and analysis of DNA sequences from Streptomyces hygroscopicus encoding geldanamycin biosynthesis

A gene library constructed from large (approximately 20 kb) fragments of total DNA from the geldananmycin-producing strain Streptomyces hygroscopicus 3602 cloned in the plasmid vector pIJ61 were used to transform S. lividans TK24. Three transformants of about 800 tested were found to have acquired the ability to produce an antibiotic lethal to a geldanamycin-sensitive strain of Bacillus subtilis. The plasmids isolated from these transformants, pIA101, pIA102 and pIA103, each contained an insert of approximately 15 kb. A 4.5 kb DNA fragment from the insert in pIA102 hybridised to DNA from S. hygroscopicus 3602 and to DNA encoding part of the erythromycin polyketide synthase but not to S. lividans TK24 DNA. The integration-defective phage vector phi C31 KC515 containing this 4.5 kb fragment was able to lysogenise S. hygroscopicus 3602 to produce lysogens defective in geldanamycin production. Loss of the prophage restored the ability to produce geldanamycin. Extracts of fermentation broth cultures of S. lividans containing pIA101, pIA102 and pIA102 and pIA103 analysed by thin-layer chromatography (TLC) contained compounds identical or very similar to purified geldanamycin, which were not present in S. lividans. These compounds showed a mass spectrum indistinguishable from geldanamycin. The evidence suggests that the clones contain DNA sequences encoding functions required for geldanamycin biosynthesis including components of the polyketide synthase.

Development of a gene cloning system for Streptomyces hygroscopicus subsp. yingchengensis, a producer of three useful antifungal compounds, by elimination of three barriers to DNA transfer

Streptomyces hygroscopicus 10-22 could not be transformed with any of the commonly used Streptomyces plasmid vectors and was resistant to plaque formation by the Streptomyces phages phi C31 and R4. Repeated selection resulted in the isolation of derivatives of S. hygroscopicus 10-22 that could be transformed with pIJ101- and pJV1-derived cloning vectors and of restriction-deficient derivatives that could accept DNA propagated in Streptomyces lividans 66. These new strains, which include three that still produce the original antibiotics, can be used as hosts for gene cloning. Insertion of nonreplicating vectors by homologous recombination and transposition of Tn4560 were demonstrated in S. hygroscopicus 10-22.

Use of new Escherichia coli/Streptomyces conjugative vectors to probe the functions of the two groEL-like genes of Streptomyces albus G by gene disruption

Streptomyces albus G contains two groEL-like genes encoding three related proteins [Guglielmi et al., J. Bacteriol. 173 (1991) 7374-7381; Mazodier et al., J. Bacteriol. 173 (1991) 7382-7386]. Two proteins, HSP58 and HSP18, are synthesized from a single start codon site in groEL1. HSP18 may be a processed form of HSP58 or the result of early termination after frameshifting. The third protein, HSP56 is encoded by groEL2. In order to determine the physiological roles of these different proteins, both groEL genes were mutagenized by using a new approach for obtaining insertions in the streptomycete chromosome. Escherichia coli plasmids containing fragments homologous to groEL1 or groEL2 are unable to replicate in Streptomyces. They were introduced into S. albus by conjugation with E. coli. We then screened for mutants in which groEL1 or groEL2 had been disrupted due to recombination events (single or double crossover) at specific sites. Using this approach, the functionally indispensable domain of HSP58 was localized to within 249 amino acids of the N-terminus. HSP58 was not detected in the mutant generated by the most upstream insertion into the groEL1 coding sequence. However, HSP18 was synthesized in this mutant after heat shock. This groEL1 mutant was not impaired in growth in the 30-41 degrees C temperature range and SDS-PAGE analysis showed its overall pattern of gene expression to be indistinguishable from the parental strain. The inability to generate strains containing groEL2 disruptions strongly suggests that HSP56 is indispensable for growth.(ABSTRACT TRUNCATED AT 250 WORDS)

Stabilization of Streptomyces lividans by homologous recombinational insertion

We have developed a system for the introduction and maintenance of novel tandem repeats in the chromosome of Streptomyces lividans 66. This was achieved by introducing, via transformation, Escherichia coli "suicide" vectors carrying manipulated S. lividans DNA fragments. Selection for antibiotic resistance markers carried on such plasmids permitted the isolation and maintenance of mutant strains containing novel tandem repeats formed by the integration into the chromosome of the plasmids, via homologous recombination between plasmid-borne chromosomal sequences and identical sequences on the chromosome. When novel repeats were introduced, and maintained, in regions of the chromosome which become deleted in unstable strains of S. lividans, those deletion events were blocked. Surprisingly, such strains were also 10 to 20-fold more stable than the parent even in the absence of selection. In stable regions of the chromosome, the maintenance of novel repeats had no obvious effect on the deletion events. This strategy could be generally applicable to industrial strains of Streptomyces, where instability is a common problem.

Genetic analysis of absB, a Streptomyces coelicolor locus involved in global antibiotic regulation

The filamentous soil bacterium Streptomyces coelicolor is known to produce four antibiotics which are genetically and structurally distinct. An extensive search for antibiotic regulatory mutants led to the discovery of absB mutants, which are antibiotic deficient but sporulation proficient. Genetic analysis of the absB mutants has resulted in definition of the absB locus at 5 o'clock on the genetic map. Multiple cloned copies of the actII-ORF4 gene, an activator of synthesis of the antibiotic actinorhodin, restore actinorhodin biosynthetic capability to the absB mutants. These results are interpreted to mean that the failure of absB mutants to produce antibiotics results from decreased expression of the antibiotic genes. The absB gene is proposed to be involved in global regulation of antibiotic synthesis.

Identification of Streptomyces coelicolor genes involved in regulation of antibiotic synthesis

To define genetic elements that regulate antibiotic synthesis, we screened for mutations that visibly blocked synthesis of Streptomyces coelicolor's two pigmented antibiotics and found mutant strains in which all four antibiotics were blocked. The responsible mutations defined two loci, absA and absB. Two additional approaches to defining genes have been taken: isolation of cloned genes with a dominant negative effect on antibiotic synthesis and isolation of genes which, in multicopy, can compensate for specific mutational blocks. These genes apparently function in a global regulatory pathway (or network) for control of antibiotic synthesis.

Molecular genetic analysis of proline and tryptophan biosynthesis in Streptomyces coelicolor A3(2): interaction between primary and secondary metabolism--a review

We studied the control of proline metabolism and tryptophan biosynthesis in Streptomyces coelicolor A3(2), because proline is involved in secondary metabolism [undecylprodigiosin (Red) biosynthesis] whilst tryptophan, to our knowledge, is not. Proline transport was constitutive in wild-type cells, as were the enzymes of proline catabolism. When we analysed proline biosynthesis, we discovered that growth in the presence of proline stimulated rather than repressed the biosynthetic genes. We isolated proline transport mutants and to our surprise discovered that such strains overproduced Red. As well as losing the ability to transport proline, they had lost, to differing extents, the ability to degrade proline. However, proline biosynthesis appeared to be unaffected. It appears that proline anabolism and catabolism in S. coelicolor A3(2) is in a state of dynamic equilibrium and that if this balance is disturbed, Red biosynthesis can act as a sink for excess proline. We cloned the trpD and the trpCBA clusters of S. coelicolor A3(2) and identified a promoter within the latter cluster. This promoter appeared not to be regulated by the presence or absence of exogenous tryptophan, but rather by the growth phase and/or the growth rate of the culture. It appears, therefore, that an amino acid biosynthetic pathway that is apparently not involved in secondary metabolism in the streptomycete is regulated at the genetic level--not by feedback repression, but rather by the overall physiological state of the cell.

The evolutionary role of secondary metabolites--a review

It is argued that organisms have evolved the ability to biosynthesise secondary metabolites ('natural products') due to the selectional advantages they obtain as a result of the functions of the compounds. Pleiotropic switching, the simultaneous expression of sporulation and antibiotic biosynthesis genes in Streptomyces, is interpreted in terms of the defense roles of antibiotics. The clustering together of antibiotic biosynthesis, regulation, and resistance genes, and in particular the staggering complexity shown in the case of the gene cluster for erythromycin A biosynthesis, implies that these genes have been selected as a group and that the antibiotics function in antagonistic capacities in nature.

abaA, a new pleiotropic regulatory locus for antibiotic production in Streptomyces coelicolor

Production of the blue-pigmented antibiotic actinorhodin is greatly enhanced in Streptomyces lividans and Streptomyces coelicolor by transformation with a 2.7-kb DNA fragment from the S. coelicolor chromosome cloned on a multicopy plasmid. Southern analysis, restriction map comparisons, and map locations of the cloned genes revealed that these genes were different from other known S. coelicolor genes concerned with actinorhodin biosynthesis or its pleiotropic regulation. Computer analysis of the DNA sequence showed five putative open reading frames (ORFs), which were named ORFA, ORFB, and ORFC (transcribed in one direction) and ORFD and ORFE (transcribed in the opposite direction). Subcloning experiments revealed that ORFB together with 137 bp downstream of it is responsible for antibiotic overproduction in S. lividans. Insertion of a phi C31 prophage into ORFB by homologous recombination gave rise to a mutant phenotype in which the production of actinorhodin, undecylprodigiosin, and the calcium-dependent antibiotic (but not methylenomycin) was reduced or abolished. The nonproducing mutants were not affected in the timing or vigor or sporulation. A possible involvement of ORFA in antibiotic production in S. coelicolor is not excluded. abaA constitutes a new locus which, like the afs and abs genes previously described, pleiotropically regulates antibiotic production. DNA sequences that hybridize with the cloned DNA are present in several different Streptomyces species.

An integrated approach to studying regulation of production of the antibiotic methylenomycin by Streptomyces coelicolor A3(2)

A physiological and molecular biological study was made of the control of methylenomycin biosynthesis by Streptomyces coelicolor A3(2). A simple and reliable assay for this antibiotic was developed. Conditions that permit the synthesis of methylenomycin by S. coelicolor cultures grown in defined medium were elucidated: a readily assimilated carbon and nitrogen source is required. Under these conditions methylenomycin is produced late in the growth phase, at the time of transition from exponential to linear growth. Provided that the phosphate concentration in the medium is kept high, there is synthesis of methylenomycin but not of the other secondary metabolites that this strain can produce. These conditions were used to study the transcription of the methylenomycin gene cluster during the transition from primary to secondary metabolism. The biosynthetic genes of at least one of the mmy transcription units appear to be transcribed before the mmr resistance determinant. The possibility that methylenomycin induces the transcription of mmr is discussed.

Review of the Streptomyces lividans/vector pIJ702 system for gene cloning

Interest in the biology of the Streptomyces and application of these soil bacteria to production of commercial antibiotics and enzymes has stimulated the development of efficient cloning techniques and a variety of streptomycete plasmid and phage vectors. Streptomyces lividans is routinely employed as a host for gene cloning, largely because this species recognizes a large number of promoters and appears to lack a restriction system. Vector pIJ702 was constructed from a variant of a larger autonomous plasmid and is often used as a cloning vehicle in conjunction with S. lividans. The host range of vector pIJ702 extends beyond Streptomyces spp., and its high copy number has been exploited for the overproduction of cloned gene products. This combination of host and vector has been used successfully to investigate antibiotic biosynthesis, gene structure and expression, and to map various Streptomyces mutants.

The isolation and characterization of antibiotic biosynthesis genes

Antibiotic biosynthesis pathways are found in a broad range of Gram positive prokaryotes, a smaller range of Gram negative prokaryotes and a limited range of eukaryotes. A variety of techniques can be used to identify the genes involved in the biosynthesis of these compounds ranging from genetic complementation and interspecific gene transfer to polymerase chain reaction amplification and transposon mutagenesis. The dissection of these cloned pathways and the understanding of their structure and regulation has led to insights into the structure and function of antibiotic biosynthesis genes. With new knowledge of the structural similarities and relationships between related antibiotic biosynthesis pathways, the possibility of directed manipulation of specific genes to allow synthesis of novel antibiotics is now possible.

The act cluster contains regulatory and antibiotic export genes, direct targets for translational control by the bldA tRNA gene of Streptomyces

The actII region, flanked by biosynthetic genes in the 25 kb act cluster of S. coelicolor, consists of four open reading frames, including a transcriptional activator for the biosynthetic genes, and genes controlling antibiotic export. A TTA codon (extremely rare in Streptomyces) is present both in actII-ORF2 (encoding a putative transmembrane export protein) and actII-ORF4 (the transcriptional activator gene). Change of the TTA in ORF4 to TTG reverses the normal interruption of actinorhodin synthesis caused by mutation in the pleiotropic regulatory gene bldA (which encodes the cell's tRNA(Leu)(UUA)). We conclude that initiation of actinorhodin synthesis via the actII-ORF4 product, and the final step in production, antibiotic export, are twin targets via which bldA exerts developmental control of actinorhodin production.

Tn4563 transposition in Streptomyces coelicolor and its application to isolation of new morphological mutants

The Tn3-like transposon Tn4556 (and its derivatives Tn4560 and Tn4563) has been used for insertion mapping of genetic loci cloned on plasmids, but it has been difficult to obtain chromosomal insertions, largely because of the lack of a strong selection against transposon donor molecules. In this communication, we report two efficient selection techniques for transposition and their use in the isolation of chromosomal insertion mutations. A number of independent Streptomyces coelicolor morphological mutants (bld and whi) were obtained. Two of the bld mutations were mapped to locations on the chromosome by SCP1-mediated conjugation; at least one mutation, bld-5m1, appears to define a novel locus involved in control of S. coelicolor morphogenesis and antibiotic production.

Manipulation of Corynebacterium glutamicum by gene disruption and replacement

We have developed a system for the genetic manipulation of the amino acid-producing Corynebacterium glutamicum. Gene disruption and replacement were achieved by introducing, via conjugation, Escherichia coli vector plasmids carrying manipulated C. glutamicum DNA fragments. We obtained stable mutants in which the chromosomal lysA gene, encoding meso-diaminopimelate decarboxylase, was interrupted by a chloramphenicol resistance cartridge, or in which an essential internal part of the lysA gene was deleted. The deletion mutants retain neither antibiotic resistance markers nor vector sequences. This strategy is generally applicable to the construction of industrial strains to be used in fermentation processes.

Phage Vectors that Allow Monitoring of Transcription of Secondary Metabolism Genes in Streptomyces

We describe a bacteriophage phi C31-based system that permits the transcriptional fusion of the convenient reporter gene xylE to chromosomally located promoters in Streptomyces hosts. Applicability of the system to genes for secondary metabolism is demonstrated in an experiment showing that transcription of genes for actinorhodin production in Streptomyces coelicolor A3(2) depends on a transfer RNA gene (bldA) for the rare UUA codon. Two other phi C31::xylE vectors are described that allow detection of promoter activity away from their natural location, either at single copy in a prophage or during lytic infections in plaques.

Bidirectional promoter and terminator regions bracket mmr, a resistance gene embedded in the Streptomyces coelicolor A3(2) gene cluster encoding methylenomycin production

Low- and high-resolution nuclease mapping of in vivo transcripts, and in vitro transcription reactions using purified RNA polymerase, were used to analyse transcription of and around the mmr gene, which specifies resistance of Streptomyces coelicolor A3(2) to methylenomycin (Mm) and is located in the middle of a cluster of Mm-production-encoding genes. Transcription of mmr is from a single major start point (tsp) which is separated by only 81 bp from a divergent tsp. A pattern of direct and inverted repeats in the nucleotide sequence in this region may play a part in regulation of these promoters. The 3' end of the mmr transcript overlaps by 20-30 bp the 3' end of an RNA molecule involved in Mm production. The converging transcripts both terminate at the same large inverted repeat in the DNA. Purified RNA polymerase terminated transcription at this sequence in vitro (albeit only in one orientation).

Gene disruption and gene replacement in Streptomyces via single stranded DNA transformation of integration vectors

For the isolation of single stranded plasmid DNA, various E. coli and E. coli-Streptomyces shuttle plasmids were equipped with the phage f1 replication origin. The transformation of some representative Streptomyces species with plasmid vectors occurred irrespective of whether single or double stranded DNA was used. In contrast, the transformation of Streptomyces was 10 to 100 times more efficient when an integration vector was in the single stranded form as opposed to the double stranded form. Streptomyces viridochromogenes was transformed by single stranded DNA integration vectors in order to replace the pat by the tsr gene and generate mutants unable to synthesize phosphinothricin-tripeptide (PTT).

The level of a transcript required for production of a Streptomyces coelicolor antibiotic is conditionally dependent on a tRNA gene

In Streptomyces coelicolor A3(2), bldA mutants are conditionally defective in aerial mycelium formation and fail to synthesize all four antibiotics produced by bldA+ strains. Previous studies showed that bldA specifies the tRNA for the rarely used leucine codon UUA. Here we describe experiments examining the abundance in a bldA mutant of a transcript involved in antibiotic production. With use of a bacteriophage-based integrative vector, a promotorless xylE reporter gene was inserted into a previously undescribed gene for an early step in biosynthesis of the red antibiotic undecylprodigiosin, located in the red gene cluster. With this transcriptional fusion present at unit copy number in the chromosome, xylE expression in a bldA+ strain was maximal late in growth in a liquid production medium and was virtually absent in a bldA mutant. On plates of a different medium, the bldA mutant was able to produce undecylprodigiosin and to express the red::xylE fusion, but both abilities were repressed by increasing the concentration of phosphate in the medium. These experiments showed that the undecylprodigiosin deficiency of bldA mutants cannot be accounted for by the presence of TTA codons in the red structural genes, but rather that bldA influences red gene mRNA abundance. In low-phosphate conditions, an alternative regulatory pathway can lead to red gene expression.

Spore colour in Streptomyces coelicolor A3(2) involves the developmentally regulated synthesis of a compound biosynthetically related to polyketide antibiotics

Streptomyces coelicolor produces spores whose development of a grey colour requires the activity of the whiE locus. The cloned whiE locus was identified after mobilization into a whiE mutant of a library of S. coelicolor DNA inserted into a transmissible plasmid vector. The whiE region of the cloned DNA was localized both by subcloning and by mutagenesis of the cloned DNA with the Streptomyces transposon Tn4560. Nucleotide sequencing of this region revealed seven open reading frames, of which six show homology at the level of deduced gene products with genes involved in the synthesis of polyketide antibiotics. A previously described S. coelicolor DNA segment encoding biosynthesis of a brown pigment (Horinouchi and Beppu, 1985) corresponds to the cloned whiE DNA. It is proposed that whiE is normally expressed only in the aerial hyphae, where the biosynthetic product is responsible for spore colour.