Disruption of a sigma factor gene, sigF, affects an intermediate stage of spore pigment production in Streptomyces aureofaciens

A stable vector for efficient production of heterologous proteins and secondary metabolites in streptomycetes

The bacteria of the genus Streptomyces are important producers of a large number of biologically active natural products. Examination of their genomes has revealed great biosynthetic potential for the production of new products, but many of them are silent under laboratory conditions. One of the promising avenues for harnessing this biosynthetic potential is the refactoring and heterologous expression of relevant biosynthetic gene clusters (BGCs) in suitable optimized chassis strains. Although several Streptomyces strains have been used for this purpose, the efficacy is relatively low, and some BGCs have not been expressed. In this study, we optimized our long-term genetically studied Streptomyces lavendulae subsp. lavendulae CCM 3239 strain as a potential host for heterologous expression along with its stable large linear plasmid pSA3239 as a vector system. Two reporter genes, mCherry and gusA under the control of ermEp* promoter, were successfully integrated into pSA3239. The activity of GUS reporter was four-fold higher in pSA3239 than in a single site in S. lavendulae subsp. lavendulae CCM 3239 chromosome, consistent with a higher copy number of pSA3239 (4 copies per chromosome). In addition, the two Att/Int systems (based on PhiC31 and pSAM2) were able to integrate into the corresponding individual attB sites in the chromosome. The BGC for actinorhodin was successfully integrated into pSA3239. However, the resulting strain produced very low amounts of actinorhodin. Its level increased dramatically after integration of the actII-ORF4 gene for the positive regulator under the control of the kasOp* promoter into this strain using the PhiC31 phage integration system. KEY POINTS: • New Streptomyces chassis for heterologous expression of genes and BGCs • Optimized strategy for insertion of heterologous genes into linear plasmid pSA3239 • Efficient heterologous production of actinorhodin after induction of its regulator.

Complete Genome Sequence of Streptomyces lavendulae subsp. lavendulae CCM 3239 (Formerly "Streptomyces aureofaciens CCM 3239"), a Producer of the Angucycline-Type Antibiotic Auricin

Streptomyces lavendulae subsp. lavendulae CCM 3239 produces the angucycline antibiotic auricin and was thought to be the type strain of Streptomyces aureofaciens. We report the complete genome sequence of this strain, which consists of a linear chromosome and the linear plasmid pSA3239, and demonstrate it to be S. lavendulae subsp. lavendulae.

A sporulation-specific, sigF-dependent protein, SspA, affects septum positioning in Streptomyces coelicolor

The RNA polymerase sigma factor SigF controls late development during sporulation in the filamentous bacterium Streptomyces coelicolor. The only known SigF-dependent gene identified so far, SCO5321, is found in the biosynthetic cluster encoding spore pigment synthesis. Here we identify the first direct target for SigF, the gene sspA, encoding a sporulation-specific protein. Bioinformatic analysis suggests that SspA is a secreted lipoprotein with two PepSY signature domains. The sspA deletion mutant exhibits irregular sporulation septation and altered spore shape, suggesting that SspA plays a role in septum formation and spore maturation. The fluorescent translational fusion protein SspA–mCherry localized first to septum sites, then subsequently around the surface of the spores. Both SspA protein and sspA transcription are absent from the sigF null mutant. Moreover, in vitro transcription assay confirmed that RNA polymerase holoenzyme containing SigF is sufficient for initiation of transcription from a single sspA promoter. In addition, in vivo and in vitro experiments showed that sspA is a direct target of BldD, which functions to repress sporulation genes, including whiG, ftsZ and ssgB, during vegetative growth, co-ordinating their expression during sporulation septation.

Role of an FtsK-like protein in genetic stability in Streptomyces coelicolor A3(2)

Streptomyces coelicolor A3(2) does not have a canonical cell division cycle during most of its complex life cycle, yet it contains a gene (ftsK(SC)) encoding a protein similar to FtsK, which couples the completion of cell division and chromosome segregation in unicellular bacteria such as Escherichia coli. Here, we show that various constructed ftsK(SC) mutants all grew apparently normally and sporulated but upon restreaking gave rise to many aberrant colonies and to high frequencies of chloramphenicol-sensitive mutants, a phenotype previously associated with large terminal deletions from the linear chromosome. Indeed, most of the aberrant colonies had lost large fragments near one or both chromosomal termini, as if chromosome ends had failed to reach their prespore destination before the closure of sporulation septa. A constructed FtsK(SC)-enhanced green fluorescent protein fusion protein was particularly abundant in aerial hyphae, forming distinctive complexes before localizing to each sporulation septum, suggesting a role for FtsK(SC) in chromosome segregation during sporulation. Use of a fluorescent reporter showed that when ftsK(SC) was deleted, several spore compartments in most spore chains failed to express the late-sporulation-specific sigma factor gene sigF, even though they contained chromosomal DNA. This suggested that sigF expression is autonomously activated in each spore compartment in response to completion of chromosome transfer, which would be a previously unknown checkpoint for late-sporulation-specific gene expression. These results provide new insight into the genetic instability prevalent among streptomycetes, including those used in the industrial production of antibiotics.

Cascade of sigma factors in streptomycetes: identification of a new extracytoplasmic function sigma factor sigmaJ that is under the control of the stress-response sigma factor sigmaH in Streptomyces coelicolor A3(2)

By using the previously established Escherichia coli two-plasmid system, we identified a promoter recognized by the Streptomyces coelicolor A3(2) stress-response sigma factor sigmaH. The promoter directed expression of the sigJ gene encoding an extracytoplasmic function (ECF) sigma factor. S1-nuclease mapping using RNA prepared from E. coli containing the two-plasmid system, and S. coelicolor A3(2) from various developmental stages identified an identical transcription start point in both strains, corresponding to the sigJp promoter. The sigJp promoter was induced during sporulation of aerial hyphae. The level of the transcript from sigJp was dramatically reduced in a S. coelicolor A3(2) sigH mutant and unaffected in a sigF mutant. The S. coelicolor A3(2) core RNA polymerase, after complementation with sigmaH, was able to recognize the sigJp promoter in vitro. A sigJ mutation had no obvious effect on growth, stress response, differentiation, and production of antibiotics. The results suggested that the S. coelicolor A3(2) sigJ gene is under the control of stress-response sigmaH, thus indicating a cascade of sigma factors in Streptomyces stress response and development. Considering the expression of sigJ and its direct dependence upon developmentally-regulated sigmaH, we assume that sigmaJ may play a role in the later stages of development of S. coelicolor A3(2).

Characterization of the polyketide spore pigment cluster whiESa in Streptomyces aureofaciens CCM3239

A spore pigment polyketide gene cluster, whiESa, was cloned from Streptomyces aureofaciens CCM3239 using a probe from the S. coelicolor A3(2) whiE gene cluster. Sequence analysis of a 4,657-bp DNA fragment revealed five open reading frames with the highest similarity to the S. coelicolor A3(2) whiE locus responsible for spore pigment biosynthesis, with conservation of the size and position of the genes. The whiESa gene cluster was disrupted by a homologous recombination in S. aureofaciens CCM3239, replacing the most important whiESaIII gene encoding ketosynthase with a thiostrepton resistance gene. The mutation affected spore pigmentation. In contrast to wild-type grey-pink spore pigmentation, the mutant produced white spores, although overall spore morphology was not affected. Transcriptional analysis of whiESa revealed two divergently oriented promoters, whiESap1 and whiESap2, upstream of the whiESaI and whiESaVIII genes, respectively. Both promoters were developmentally regulated in S. aureofaciens CCM3239. They were induced at the late stages of differentiation, during sporulation of aerial hyphae and were dependent upon early sporulation-specific sigma factor sigma(RpoZ) and putative transcription factor WhiB. The level of the transcript originating from the whiESap2 promoter was substantially reduced in a sigF mutant of S. aureofaciens CCM3239, indicating its dependence upon the late sporulation sigma factor sigma(F). Comparison of the whiE promoters in three different spore pigment polyketide clusters revealed a highly conserved region upstream of the -35 promoter region that may bind a transcriptional regulator.

Cloning and characterization of a polyketide synthase gene cluster involved in biosynthesis of a proposed angucycline-like polyketide auricin in Streptomyces aureofaciens CCM 3239

A new polyketide gene cluster, aur1, was identified in Streptomyces aureofaciens CCM3239 by using genes for the spore-pigment polyketide synthase of the Streptomyces coelicolor whiE operon as a probe. Sequence analysis of three overlapping DNA fragments (encompassing 15,100 bp) revealed 15 open reading frames, the majority of which showed high similarity to the previously characterized type II polyketide synthase genes. The highest similarity was to three Streptomyces polyketide gene clusters involved in biosynthesis of angucycline antibiotics, jadomycin, urdamycin and landomycin. The proposed S. aureofaciens ketosynthase (Aur1D) was phylogenetically more related to all known ketosynthases for polyketide antibiotics in Streptomyces than to spore-pigment ketosynthases. Interestingly, the aur1 gene cluster contained a gene encoding a proposed malonyl-CoA:ACP transacylase that has not been identified in any of the previously characterized type II polyketide synthase cluster. Transcriptional analysis of aur1 revealed a single promoter upstream the first open reading frame (the aur1A gene) that was active in all stages of differentiation with increased activity at the time of aerial mycelium formation. The aur1 gene cluster was disrupted by a homologous recombination, replacing the three genes (aur1B,C,D) including ketosynthase, with antibiotic resistance marker gene in S. aureofaciens chromosome. Disruption did not affect growth and differentiation; disrupted strain produced spores with wild-type gray-pink pigmentation. The biochromatographic analysis of the culture extracts from S. aureofaciens wild-type and aur1-disrupted strains revealed an antibacterial compound that was missing in the mutant. The results indicated a role of the S. aureofaciens aur1 gene cluster in biosynthesis of a polyketide secondary metabolite (which we named auricin), and not in the spore pigment biosynthesis.

Streptomyces aureofaciens sporulation-specific sigma factor sigma(rpoZ) directs expression of a gene encoding protein similar to hydrolases involved in degradation of the lignin-related biphenyl compounds

A previously established method for the identification of promoters recognized by a heterologous RNA polymerase holoenzyme containing a particular sigma factor was used to identify promoters dependent upon a sporulation specific sigma factor, sigma(RpoZ), of Streptomyces aureofaciens. Three new positive DNA fragments were identified, and these putative rpoZ-dependent promoters, P(ren24), P(ren57), and P(ren71), contained sequences similar to the consensus sequence of flagellar and chemotaxis promoters. However, only P(ren71) was active in S. aureofaciens. The promoter was induced at the time of aerial mycelium formation, and was inactive in an S. aureofaciens strain with an rpoZ-disrupted gene. The results suggest that the P(ren71) promoter is recognized by an RNA polymerase holoenzyme containing sigma(RpoZ) in S. aureofaciens. Sequence analysis of the region directed by P(ren71) revealed a gene, ren71, encoding a protein of 358 amino acids with an Mr 37,770. The deduced protein product showed end-to-end sequence similarity to the meta-cleavage compound hydrolase of Sphingomonas paucimobilis.

Identification of DNA-binding proteins involved in regulation of expression of the Streptomyces aureofaciens whiH gene encoding a sporulation transcription factor

Using the gel mobility-shift assay with protein fractions from different developmental stages of solid-grown Streptomyces aureofaciens, we identified two different proteins specifically bound to the whiH promoter region. Only one protein (RwhA) was detected in young substrate mycelium cultivated in liquid medium. On comparing the mobility of the resulting complexes, one of the bound proteins present in substrate mycelium and in early stages of aerial mycelium seemed to be identical with the RwhA. The other detected protein with a higher mobility (RwhB) was present in all developmental stages except for mature spores. DNA footprinting analysis localized the binding site of RwhB to nucleotides -23 to +40 relative to the transcription start point of the PwhiH promoter. RwhA from young substrate mycelium protected the DNA fragment from -106 to -77 in coding strand and -126 to -82 in noncoding strand. WhiH has homology to a large family of metabolism-related repressors and seems to regulate negatively its own expression. These observations (and the results of transcription analysis of the whiH gene obtained earlier) suggest that two different proteins influence the expression of whiH gene in S. aureofaciens. The putative repressor-like RwhA protein protects expression of whiH in substrate mycelium either in liquid medium or during differentiation. The other detected protein, RwhB, which binds to the whiH promoter region during differentiation, may represent two forms of WhiH, one with a repressor role at the beginning of differentiation and second with the role of activator at the time of sporulation.

Identification of DNA-binding proteins involved in regulation of expression of the Streptomyces aureofaciens sigF gene, which encodes sporulation sigma factor sigma(F)

Expression of the sigF gene encoding a sporulation-specific sigma factor, sigma(F), in Streptomyces aureofaciens is restricted only to sporulation. Gel mobility-shift assays using protein fractions from different developmental stages of S. aureofaciens revealed two different putative proteins specifically bound to the sigF promoter region: a protein (designated RsfA) present in young substrate mycelium, and a protein (designated RsfB) present in the course of sporulation. Based on the characteristic profiles of their appearance during differentiation, RsfA might be a repressor and RsfB an activator of sigF expression. The location of a specific binding site of the repressor-like protein (RsfA) was determined by gel mobility-shift assays of promoter deletion fragments and by DNase I footprinting analysis. The binding site mapped from nucleotides -87 to -25 relative to the transcription start point of the sigF promoter, and overlapped the -35 promoter region. Given the dependence of sigF expression upon whiH, the putative sporulation transcription factor WhiH was overproduced in Escherichia coli and used in the mobility-shift assays with the sigF promoter. However, no specific binding was detected, indicating an indirect dependence of sigF upon whiH.

The Streptomyces aureofaciens homologue of the sporulation gene whiH is dependent on rpoZ-encoded sigma factor

Using the method for the identification of promoters recognized by a sporulation specific sigma factor RpoZ, we identified a promoter in Streptomyces aureofaciens, directing expression of a gene having high sequence similarity (83% amino acid identity) to sporulation transcription factor WhiH of Streptomyces coelicolor. High-resolution S1-nuclease mapping using RNA prepared from S. aureofaciens from various developmental stages showed high similarity of PwhiH promoter to the consensus sequence of flagellar and chemotaxis promoters. The promoter was induced at the time of aerial mycelium formation, and was off in S. aureofaciens strain with rpoZ-disrupted gene. The results suggest that the PwhiH promoter is recognized by sigma factor RpoZ in S. aureofaciens.

Developmental regulation of transcription of whiE, a locus specifying the polyketide spore pigment in Streptomyces coelicolor A3 (2)

whiE is a complex locus that specifies the polyketide spore pigment in Streptomyces coelicolor A3(2). Two divergently oriented promoters, whiEP1 and whiEP2, were identified in the whiE gene cluster, and their activities were analyzed during colony development in wild-type and sporulation-deficient strains. Both promoters were developmentally regulated; whiEP1 and whiEP2 transcripts were detected transiently at approximately the time when sporulation septa were observed in the aerial hyphae, and transcription from both promoters depended on each of the six known "early" whi genes required for sporulation septum formation (whiA, -B, -G, -H, -I, and -J). Mutation of the late sporulation-specific sigma factor gene, sigF, had no effect on the activity of whiEP1 but blocked transcription from whiEP2. However, sigmaF-containing holoenzyme was not sufficient to direct transcription of whiEP2 in vitro. The whiEP2 promoter controls expression of whiE ORFVIII, encoding a putative flavin adenine dinucleotide-dependent hydroxylase that catalyzes a late tailoring step in the spore pigment biosynthetic pathway. Disruption of whiE ORFVIII causes a change in spore color, from grey to greenish (T.-W. Yu and D. A. Hopwood, Microbiology 141:2779-2791, 1995). Consistent with these observations, construction of a sigF null mutant of S. coelicolor M145 caused the same change in spore color, showing that disruption of sigF in S. coelicolor changes the nature of the spore pigment rather than preventing its synthesis altogether.