A single amino acid substitution in region 1.2 of the principal sigma factor of Streptomyces coelicolor A3(2) results in pleiotropic loss of antibiotic production.

Antibiotic production in streptomycetes generally occurs in a growth phase-dependent and developmentally co-ordinated manner, and is subject to pathway-specific and pleiotropic control. Streptomyces coelicolor A3(2) produces at least four chemically distinct antibiotics, including actinorhodin (Act) and undecylprodigiosin (Red). afsB mutants of S. coelicolor are deficient in the production of both compounds and in the synthesis of a diffusible gamma-butyrolactone, SCB1, that can elicit precocious Act and Red production. Clones encoding the principal and essential sigma factor (sigmaHrdB) of S. coelicolor restored Act and Red production in the afsB mutant BH5. A highly conserved glycine (G) at position 243 of sigmaHrdB was shown to be replaced by aspartate (D) in BH5. Replacement of G243 by D in the afsB+ strain M145 reproduced the afsB phenotype. The antibiotic deficiency correlated with reduced transcription of actII-ORF4 and redD, pathway-specific regulatory genes for Act and Red production respectively. Exogenous addition of SCB1 to the G-243D mutants failed to restore Act and Red synthesis, indicating that loss of antibiotic production was not a result of the deficiency in SCB1 synthesis. The G-243D substitution, which lies in the highly conserved 1.2 region of undefined function, had no effect on growth rate or morphological differentiation, and appears specifically to affect antibiotic production.

Characterization of two Streptomyces ambofaciens recA mutants: identification of the RecA protein by immunoblotting.

The recA gene was isolated from Streptomyces ambofaciens DSM40697. Its nucleotide sequence predicted a protein of 372 residues. Two recA mutants, NSAR1001 and NSAR57, obtained by gene disruption encoded a RecA protein lacking respectively 30 and at least 62 amino acids from the C-terminal end. NSAR1001 showed a wild-type sensitivity to UV light and oxolinic acid. In contrast, NSAR57 was highly sensitive to these agents and the loss of the inserted DNA restored the wild-type phenotype. Western blot analysis using antiserum to Escherichia coli RecA showed that overproduction of RecA was correlated with overtranscription of recA in an S. ambofaciens amplified mutant derived from genetic instability.

Expression of the Streptomyces coelicolor A3(2) ptpA gene encoding a phosphotyrosine protein phosphatase leads to overproduction of secondary metabolites in S. lividans.

A DNA fragment that caused pigment production in Streptomyces lividans was isolated from a gene library of PstI-digested chromosomal fragments of S. coelicolor A3(2). Subcloning and nucleotide sequencing proved the identity of the cloned gene to ptpA encoding a low-molecular-mass phosphotyrosine protein phosphatase. The S. lividans transformant containing ptpA on pIJ41 with a copy number of 3 4 per genome produced large amounts of undecylprodigiosin and A-factor, in addition to the pigmented antibiotic actinorhodin, whereas the transformant containing ptpA on an SCP2* derivative with a copy number of 1-2 did not. The PtpA protein produced as a fusion to the maltose binding protein in Escherichia coli showed phosphatase activity toward o-phosphotyrosine, but not toward o-phosphoserine or a-threonine. Introduction of a mutant ptpA gene encoding an inactive protein with serine instead of the 9th cysteine caused no pigmentation. Disruption of the chromosomal ptpA gene of S. coelicolor A3(2), however, appeared to cause no detectable effect on the production of the pigmented antibiotics or A-factor and the ptpA disruptants developed aerial mycelium and spores normally.

An amplifiable and deletable locus of Streptomyces ambofaciens RP181110 contains a very large gene homologous to polyketide synthase genes.

Streptomyces ambofaciens RP181110 produces the macrolide polyketide spiramycin. Like many other Streptomyces species, the RP181110 strain is prone to genetic instability involving genomic rearrangements (deletions and/or amplifications) in the large unstable region of the genome. It has previously been demonstrated that the amplification of a particular locus (AUD205) affects spiramycin biosynthesis and, conversely, the loss of this amplification is correlated with the restoration of antibiotic production. This report focuses on a 0.93 kb reiterated fragment specific for the AUD205 locus. Sequencing of 3596 bp including this reiteration revealed the presence of an ORF (orfPS) whose potential product was highly homologous to the EryA and Raps proteins, responsible for the biosynthesis of erythromycin in Saccharopolyspora erythraea and rapamycin in Streptomyces hygroscopicus, respectively. orfPS encodes a protein with at least four successive domains: ketoacyl synthase, acyltransferase, ketoreductase and acyl carrier protein. This organization is very similar to most eryA and rap modules. The reiterated sequence corresponds to the acyltransferase domain. orfPS was transcribed during rapid growth and stationary phase in RP181110 and overtranscribed in the amplified mutant. Both these results suggest that the gene encodes a type I polyketide synthase and its reorganization is responsible for the loss of spiramycin production in the amplified strains.

Analysis of genome instability in Streptomyces ambofaciens.

Genetic instability in Streptomyces ambofaciens DSM 40697 is correlated with genomic instability characterized by multiple rearrangements (deletions and/or amplifications) occurring in a large unstable region. We have focused on one of the two amplifiable DNA loci which were mapped in this region: the amplifiable unit of DNA locus 6 (AUD6). The nucleotide sequence of one AUD6 fragment of 1.9 kb reveals the presence of two open reading frames (ORF1 and ORF2) on the basis of the typical Streptomyces base composition at each of the three positions within codons. ORF1 shows some similarity with a gene encoding a regulatory protein. The presence of potential genes in this unstable locus was unexpected because deletions occurred with high frequency within this region in the genetic instability-derived mutant strains. However, transcription analyses by S1 nuclease protection experiments on the wild-type strain showed transcription of both ORF1 and ORF2. Moreover, the amplified strain reveals increased transcription of ORF1 but no transcription of ORF2. The amplification therefore results in a switch in transcription. The unstable region of S. ambofaciens DSM 40697 therefore is not a 'silent' region because at least some loci are transcribed.