SCP1, a 356,023 bp linear plasmid adapted to the ecology and developmental biology of its host, Streptomyces coelicolor A3(2).

The sequencing of the entire genetic complement of Streptomyces coelicolor A3(2) has been completed with the determination of the 365,023 bp sequence of the linear plasmid SCP1. Remarkably, the functional distribution of SCP1 genes somewhat resembles that of the chromosome: predicted gene products/functions include ECF sigma factors, antibiotic biosynthesis, a gamma-butyrolactone signalling system, members of the actinomycete-specific Wbl class of regulatory proteins and 14 secreted proteins. Some of these genes are among the 18 that contain a TTA codon, making them targets for the developmentally important tRNA encoded by the bldA gene. RNA analysis and gene fusions showed that one of the TTA-containing genes is part of a large bldA-dependent operon, the gene products of which include three proteins isolated from the spore surface by detergent washing (SapC, D and E), and several probable metabolic enzymes. SCP1 shows much evidence of recombinational interactions with other replicons and transposable elements during its history. For example, it has two sets of partitioning genes (which may explain why an integrated copy of SCP1 partially suppressed the defective partitioning of a parAB-deleted chromosome during sporulation). SCP1 carries a cluster of probable transfer determinants and genes encoding likely DNA polymerase III subunits, but it lacks an obvious candidate gene for the terminal protein associated with its ends. This may be related to atypical features of its end sequences.

A rare leucine codon in adpA is implicated in the morphological defect of bldA mutants of Streptomyces coelicolor.

Streptomycetes are mycelial bacteria that produce sporulating aerial hyphae on solid media. Bald (bld) mutants fail to form aerial mycelium under at least some conditions. bldA encodes the only tRNA species able to read the leucine codon UUA efficiently, implying the involvement of a TTA-containing gene in initiating aerial growth. One candidate for such a gene was bldH, because the bldH109 mutant of Streptomyces coelicolor resembles bldA mutants in some aspects. In the work reported here, adpAc, an S. coelicolor gene similar to the Streptomyces griseus A factor-regulated adpAg, was found to complement the bldH109 mutant partially at both single and multiple copies. The sequence of adpAc from the bldH109 mutant revealed a frameshift. A constructed in frame deletion of adpAc conferred a bald colony phenotype, and the mutant behaved like bldA mutants and bldH109 in its pattern of extracellular signal exchange. Both adpAc and adpAg contain a TTA codon. A TTA-free version of adpAc was engineered by replacing the TTA leucine codon with a cognate TTG leucine codon. The adpA(TTATTG) gene could partially restore aerial mycelium formation to a bldA mutant when it was followed in cis by the gene ornA, as in the natural chromosomal arrangement. This indicated that the UUA codon in adpAc mRNA is the principal target through which bldA influences morphological differentiation. It also implied that translational arrest at the UUA codon in adpAc mRNA caused a polar effect on the downstream ornA, and that the poor translation of both genes contributes extensively to the deficiency of aerial mycelium formation in bldA mutants. Unlike the situation in S. griseus, adpAc transcription does not depend on the host's -butyrolactone signalling system, at least in liquid cultures. In addition, sigma factor BldN, which is the homologue of an S. griseus sigma factor AdsA that is absent from adpAg mutants of S. griseus, was present in the constructed adpAc null mutant of S. coelicolor.

Cloning and engineering of the cinnamycin biosynthetic gene cluster from Streptomyces cinnamoneus cinnamoneus DSM 40005.

Lantibiotics are ribosomally synthesized oligopeptide antibiotics that contain lanthionine bridges derived by the posttranslational modification of amino acid residues. Here, we describe the cinnamycin biosynthetic gene cluster (cin) from Streptomyces cinnamoneus cinnamoneus DSM 40005, the first, to our knowledge, lantibiotic gene cluster from a high G+C bacterium to be cloned and sequenced. The cin cluster contains many genes not found in lantibiotic clusters from low G+C Gram-positive bacteria, including a Streptomyces antibiotic regulatory protein regulatory gene, and lacks others found in such clusters, such as a LanT-type transporter and a LanP-type protease. Transfer of the cin cluster to Streptomyces lividans resulted in heterologous production of cinnamycin. Furthermore, modification of the cinnamycin structural gene (cinA) led to production of two naturally occurring lantibiotics, duramycin and duramycin B, closely resembling cinnamycin, whereas attempts to make a more widely diverged derivative, duramycin C, failed to generate biologically active material. These results provide a basis for future attempts to construct extensive libraries of cinnamycin variants.

Primary and secondary metabolism, and post-translational protein modifications, as portrayed by proteomic analysis of Streptomyces coelicolor.

The newly sequenced genome of Streptomyces coelicolor is estimated to encode 7825 theoretical proteins. We have mapped approximately 10% of the theoretical proteome experimentally using two-dimensional gel electrophoresis and matrix-assisted laser desorption ionization time-of-flight (MALDI-TOF) mass spectrometry. Products from 770 different genes were identified, and the types of proteins represented are discussed in terms of their annotated functional classes. An average of 1.2 proteins per gene was observed, indicating extensive post-translational regulation. Examples of modification by N-acetylation, adenylylation and proteolytic processing were characterized using mass spectrometry. Proteins from both primary and certain secondary metabolic pathways are strongly represented on the map, and a number of these enzymes were identified at more than one two-dimensional gel location. Post-translational modification mechanisms may therefore play a significant role in the regulation of these pathways. Unexpectedly, one of the enzymes for synthesis of the actinorhodin polyketide antibiotic appears to be located outside the cytoplasmic compartment, within the cell wall matrix. Of 20 gene clusters encoding enzymes characteristic of secondary metabolism, eight are represented on the proteome map, including three that specify the production of novel metabolites. This information will be valuable in the characterization of the new metabolites.

Complete genome sequence of the model actinomycete Streptomyces coelicolor A3(2).

Streptomyces coelicolor is a representative of the group of soil-dwelling, filamentous bacteria responsible for producing most natural antibiotics used in human and veterinary medicine. Here we report the 8,667,507 base pair linear chromosome of this organism, containing the largest number of genes so far discovered in a bacterium. The 7,825 predicted genes include more than 20 clusters coding for known or predicted secondary metabolites. The genome contains an unprecedented proportion of regulatory genes, predominantly those likely to be involved in responses to external stimuli and stresses, and many duplicated gene sets that may represent 'tissue-specific' isoforms operating in different phases of colonial development, a unique situation for a bacterium. An ancient synteny was revealed between the central 'core' of the chromosome and the whole chromosome of pathogens Mycobacterium tuberculosis and Corynebacterium diphtheriae. The genome sequence will greatly increase our understanding of microbial life in the soil as well as aiding the generation of new drug candidates by genetic engineering.

Regulation of sporulation in Streptomyces coelicolor A3(2): a checkpoint multiplex?

By complementing developmental mutants of Streptomyces coelicolor A3(2), at least 15 regulatory genes for sporulation have been identified and studied at the molecular level, and some of their intracellular interactions have been characterised. Extensive interplay of the regulatory cascade with metabolic, morphological, homeostatic and stress-related checkpoints is emerging.

Generation of a non-sporulating strain of Streptomyces coelicolor A3(2) by the manipulation of a developmentally controlled ftsZ promoter.

The differentiation of Streptomyces aerial hyphae into chains of unigenomic spores occurs through the synchronous formation of multiple FtsZ rings, leading to sporulation septa. We show here that developmental control of ftsZ transcription is required for sporulation in Streptomyces coelicolor A3(2). Three putative ftsZ promoters were detected in the ftsQ-ftsZ intergenic region. In addition, some readthrough from upstream promoter(s) contributed to ftsZ transcription. S1 nuclease protection assays and transcriptional fusions of the ftsZ promoter region to the egfp gene (for green fluorescent protein) provided evidence that ftsZ2p is a developmentally controlled promoter that is specifically upregulated in sporulating aerial hyphae. This upregulation required all the six early regulatory sporulation genes that were tested: whiA, B, G, H, I and J. The DNA sequence of the promoter indicated that it is not part of the developmental regulon that is controlled by the RNA polymerase sigma factor sigma(WhiG). A strain in which the ftsZ2p promoter was inactivated grew normally during vegetative growth and formed aerial mycelium, but was deficient in sporulation septation. Thus, ftsZ2p was dispensable for vegetative growth, but was required for the strain to make sufficient FtsZ to support developmentally controlled multiple cell divisions in aerial hyphae.

H2O2-sensitive fur-like repressor CatR regulating the major catalase gene in Streptomyces coelicolor.

Streptomyces coelicolor produces three distinct catalases to cope with oxidative and osmotic stresses and allow proper growth and differentiation. The major vegetative catalase A (CatA) is induced by H(2)O(2) and is required for efficient aerobic growth. In order to investigate the H(2)O(2)-dependent regulatory mechanism, an H(2)O(2)-resistant mutant (HR40) overproducing CatA was isolated from S. coelicolor A3(2). Based on the genetic map location of the mutated locus in HR40, the wild type catR gene was isolated from the ordered cosmid library of S. coelicolor by screening for its ability to suppress the HR40 phenotype. catR encodes a protein of 138 amino acids (15319 Da), with sequence homology to ferric uptake regulator (Fur)-like proteins. Disruption of catR caused CatA overproduction as observed in the HR40 mutant, confirming the role of CatR as a negative regulator of catA expression. The levels of catA and catR transcripts were higher in HR40 than in the wild type, implying that CatR represses transcription of these genes. Transcripts from the catA and catR genes were induced within 10 min of H(2)O(2) treatment, suggesting that the repressor activity of CatR may be directly modulated by H(2)O(2). A putative CatR-binding site containing an inverted repeat of 23 base pairs was localized upstream of the catA and catR gene, on the basis of sequence comparison and deletion analysis. CatR protein purified in the presence of dithiothreitol bound to this region, whereas oxidized CatR, treated with H(2)O(2) or diamide, did not. The redox shift of CatR involved thiol-disulfide exchange as judged by modification of free thiols with 4-acetamido-4'-maleimidylstilbene-2,2'-disulfonate. From these results we propose that CatR regulates its downstream target genes as a repressor whose DNA binding ability is directly modulated by redox changes in the cell.

WhiA, a protein of unknown function conserved among gram-positive bacteria, is essential for sporulation in Streptomyces coelicolor A3(2).

The whiA sporulation gene of Streptomyces coelicolor A3(2), which plays a key role in switching aerial hyphae away from continued extension growth and toward sporulation septation, was cloned by complementation of whiA mutants. DNA sequencing of the wild-type allele and five whiA mutations verified that whiA is a gene encoding a protein with homologues in all gram-positive bacteria whose genome sequence is known, whether of high or low G+C content. No function has been attributed to any of these WhiA-like proteins. In most cases, as in S. coelicolor, the whiA-like gene is downstream of other conserved genes in an operon-like cluster. Phenotypic analysis of a constructed disruption mutant confirmed that whiA is essential for sporulation. whiA is transcribed from at least two promoters, the most downstream of which is located within the preceding gene and is strongly up-regulated when colonies are undergoing sporulation. The up-regulation depends on a functional whiA gene, suggesting positive autoregulation, although it is not known whether this is direct or indirect. Unlike the promoters of some other sporulation-regulatory genes, the whiA promoter does not depend on the sporulation-specific sigma factor encoded by whiG.

Duplicated gene clusters suggest an interplay of glycogen and trehalose metabolism during sequential stages of aerial mycelium development in Streptomyces coelicolor A3(2).

DNA sequencing and operon disruption experiments indicate that the genes glgBI and glgBII, which code for the two developmentally specific glycogen branching enzymes of Streptomyces coelicolor A3(2) each form part of larger duplicated operons consisting of at least four genes in the order pep1-treS-pep2-glgB. The sequences of the TreS proteins are 73% identical (93% similar) to that of an enzyme that converts maltose into trehalose in Pinmelobacter, a distantly related actinomycete; and the Pep1 proteins show relatedness to the alpha-amylase superfamily. Disruptions of each operon have spatially specific effects on the nature of glycogen deposits, as assessed by electron microscopy. Upstream of the glgBI operon, and diverging from it, is a gene (glgP) that encodes a protein resembling glycogen phosphorylase from Thermatoga maritima and a homologue in Mycobacterium tuberculosis. These three proteins form a distinctive subgroup compared with glycogen phosphorylases from most other bacteria, which more closely resemble the enzymes from eukaryotes. Diverging from the glgBII operon, and separated from the pep1 gene by two very small ORFs, is a gene (glgX) encoding a probable glycogen debranching enzyme. It is suggested that most of these gene products participate in the developmentally modulated interconversion of immobile, inert glycogen reservoirs, and diffusible forms of carbon, both metabolically active (e.g. glucose-1-phosphate generated by glycogen phosphorylase) and metabolically inert but physiologically significant (trehalose).

Multiple paralogous genes related to the Streptomyces coelicolor developmental regulatory gene whiB are present in Streptomyces and other actinomycetes.

The whiB sporulation gene of Streptomyces coelicolor was shown [Davis, N. K. & Chater, K. F. (1992). Mol Gen Genet 232, 351-358] to encode a small, cysteine-rich putative transcription factor unlike any that had been described previously. The large database of DNA sequences of mycobacteria (like Streptomyces, members of the Actinomycetales) has revealed a family of genes encoding proteins related to WhiB. Mycobacterium tuberculosis contains at least six such genes (whiB homologues in mycobacteria: whmA-F) and a likely seventh, whmG. Using conserved features of Whm proteins, a PCR-based approach led to the discovery that S. coelicolor A3(2) contains several similar genes. Cloning and sequencing of these whiB-like (wbI) genes revealed likely orthologues of four of the whm genes of M. tuberculosis. In all, S. coelicolor contains at least five wbI genes in addition to whiB itself. All five were shown by RT-PCR to be transcribed. A Southern blotting survey using each wbI gene as a probe showed that nearly all of a series of representatives of ten actinomycete genera (including morphologically simple organisms) contain close homologues of several wbI genes, suggesting that the ancient progenitor of all these organisms already contained a family of such genes, which have not been found in any other organisms.

Partitioning of the linear chromosome during sporulation of Streptomyces coelicolor A3(2) involves an oriC-linked parAB locus.

Candidate partitioning genes (parA and parB) for the linear chromosome of Streptomyces coelicolor were identified by DNA sequencing in a series of seven genes located between rnpA and trxA near the chromosomal replication origin. The most likely translation start point of parB overlapped the parA stop codon, suggestive of coregulation, and transcription analysis suggested that the two genes formed an operon. Deletion of part of parB had no effect on the growth or appearance of colonies but caused a deficiency in DNA partitioning during the multiple septation events involved in converting aerial hyphae into long chains of spores. At least 13% of spore compartments failed to inherit the normal DNA allocation. The same phenotype was obtained with a deletion removing a segment of DNA from both parA and parB. Reinforcing the idea of a special role for the par locus during sporulation, the stronger of two parAB promoters was greatly upregulated at about the time when sporulation septation was maximal in colonies. Three copies of a 14-bp inverted repeat (GTTTCACGTGAAAC) were found in or near the parAB genes, and at least 12 more identical copies were identified within 100 kb of oriC from the growing genome sequence database. Only one perfect copy of the 14-bp sequence was present in approximately 5 Mb of sequence available from the rest of the genome. The 14-bp sequence was similar to sequences identified as binding sites for Spo0J, a ParB homologue from Bacillus subtilis believed to be important for DNA partitioning (D. C.-H. Lin and A. D. Grossman, Cell 92:675-685, 1998). One of these sites encompassed the transcription start point of the stronger parA promoter.

The function of a regulatory gene, scrX related to differentiation in Streptomyces coelicolor.

A new gene, scrX from Streptomyces coelicolor was cloned and sequenced. It consists of 660 base pair, encoding a peptide of 220 amino acids. There are three rare codons in scrX which are AAA, AAA and ATA. scrX gene may be a typical differentiation regulator which was strictly controlled at translational level. The comparison of amino acids also revealed that ScrX belonged to Ic1R family which acted in transcriptional regulation of prokaryote. Studies on gene function by gene disruption and complementation indicated that scrX may play a positive regulation role in spore formation of Streptomyces coelicolor.

A response regulator-like protein that functions at an intermediate stage of sporulation in Streptomyces coelicolor A3(2).

whiI is one of several loci originally described as essential for sporulation in Streptomyces coelicolor A3(2). We have characterized whiI at the molecular level. It encodes an atypical member of the response regulator family of proteins, lacking at least two of the residues strongly conserved in the conventional phosphorylation pocket. It is not adjacent to a potential sensor kinase gene. Fifteen mutant alleles of whiI were sequenced, revealing, among others, six mutations affecting conserved amino acids, several frameshift mutations and one mutation in the promoter. The whiI promoter is specifically transcribed by the sporulation-specific sigmaWhiG-containing form of RNA polymerase. Transcription of whiI is temporally controlled, reaching a maximum level coincident with the formation of spores. Further transcriptional studies suggested that WhiI is involved directly or indirectly in repressing its own expression and that of another sigmaWhiG-dependent sporulation-specific regulatory gene, whiH.

New sporulation loci in Streptomyces coelicolor A3(2).

Sporulation mutants of Streptomyces coelicolor appear white because they are defective in the synthesis of the grey polyketide spore pigment, and such white (whi) mutants had been used to define eight sporulation loci, whiA, whiB, whiD, whiE, whiG, whiH, whiI, and whiJ (K. F. Chater, J. Gen. Microbiol. 72:9-28, 1972; N. J. Ryding, Ph.D. thesis, University of East Anglia, 1995). In an attempt to identify new whi loci, we mutagenized S. coelicolor M145 spores with nitrosoguanidine and identified 770 mutants with colonies ranging from white to medium grey. After excluding unstable strains, we examined the isolates by phase-contrast microscopy and chose 115 whi mutants with clear morphological phenotypes for further study. To exclude mutants representing cloned whi genes, self-transmissible SCP2*-derived plasmids carrying whiA, whiB, whiG, whiH, or whiJ (but not whiD, whiE, or whiI) were introduced into each mutant by conjugation, and strains in which the wild-type phenotype was restored either partially or completely by any of these plasmids were excluded from further analysis. In an attempt to complement some of the remaining 31 whi mutants, an SCP2* library of wild-type S. coelicolor chromosomal DNA was introduced into 19 of the mutants by conjugation. Clones restoring the wild-type phenotype to 12 of the 19 strains were isolated and found to represent five distinct loci, designated whiK, whiL, whiM, whiN, and whiO. Each of the five loci was located on the ordered cosmid library: whiL, whiM, whiN, and whiO occupied positions distinct from previously cloned whi genes; whiK was located on the same cosmid overlap as whiD, but the two loci were shown by complementation to be distinct. The phenotypes resulting from mutations at each of these new loci are described.

Bacterial transcription factors involved in global regulation.

The presence of intricate global cell regulation mechanisms may be one reason for the exceptional environmental and evolutionary success of microbes. Promoters, the cis-acting signals, are responsive to several stimuli related to growth, stress and substrate specificity. Their response is mediated by a wide variety of trans-acting regulators that sense the environment and the physiological state of the cell and adjust the transcription of specific genes. One of the main transcriptional regulation webs operates in the transition from affluent to barren conditions, with sigmaS being the chief actor in a company of players that stage a competition for the sparsely available RNA polymerase molecules. In this role, sigmaS may be assisted by several factors, including nucleoid-related proteins and metabolites. In addition, the levels of sigmaS itself are regulated by mechanisms that include inactivation and degradation. Several transcription factors, belonging to different regulatory pathways, may operate in the same promoter. In such a case, the final transcriptional output depends both on the interplay of effectors and on the properties of the recruitment of the effector-RNA polymerase complex to the promoter. RNA polymerase itself is also capable of establishing selective interactions with activators and specific promoter regions through the carboxy-terminal domain of its alpha subunit (alphaCTD). Transcriptional regulation controls pervade such crucial events in the life of bacterial cells as Escherichia coli cell division, Bacillus subtilis sporulation and Caulobacter crescentus differentiation. These examples suggest that bacteria have been particularly inventive in adapting gene expression regulation to survive under a diversity of environments and have done so by exploiting the malleable molecular mechanisms involved in transcription, developing complexities that may match those found in eukaryotic cells.

A novel gene: sawD related to the differentiation of streptomyces ansochromogenes.

A 1.3 kb DNA fragment was cloned from a total DNA library of Streptomyces ansochromogenes using Southern hybridization. Nucleotide sequencing analysis indicated that the 1320 bp DNA fragment contained a complete open reading frame (ORF). In search of databases, the deduced product of ORF containing 213 amino acids is homologous to the serine protease of Caulobacter cresceatus, and a conserved serine-catalytic active site (GPSAG) exists. The gene was designated as sawD. The function of this gene was studied with the strategy of gene disruption, and the result showed that the sawD may be related to sporulation and especially to the spore septation in Streptomyces ansochromogenes. The preliminary result indicated that sawD mutant could produce abundant pigment in contrast with the wild type, it seems that sawD gene may be involved in pigment biosynthesis, and this gene is also dispensable for biosynthesis of nikkomycin in Streptomyces ansochromogenes.

A novel gene-samfR involved in early stage of Streptomyces ansochromogenes differentiation.

A 4.6 kb DNA fragment was cloned from the DNA library of Streptomyces ansochromogenes using a partial DNA fragment located in the downstream of promoter-P(TH4) as probe. The experiments revealed that this DNA fragment consists of saw D gene and a 1.4 kb Pvu II fragment which can accelerate mycelium formation o fS. ansochromogenes. The nucleotide sequence of 1.4 kb DNA fragment was determined and analysed; the result indicated that the fragment contains one complete open reading frame (ORF) which encodes a protein with 213 amino acids, and this gene was designated as samfR. The deduced protein has 36% amino acid identities and 52% amino acid similarities in comparison with that encoded by hppR gene, which is involved in the regulation of catabolism for 3-(3-hydroxyphenyl) propionate (3HPP) in Rhodococcus globerulus. The function of samfR gene was studied using strategy of gene disruption, and the resulting samfR mutant failed to form aerial hyphae and spores, its development and differentiation stopped at the stage of substrate mycelium in contrast with wild type strain. The results showed that the samfR gene is closely related to S. ansochromogenes differentiation.

A developmentally regulated gene encoding a repressor-like protein is essential for sporulation in Streptomyces coelicolor A3(2).

whiH is one of several known loci specifically needed for the orderly multiple sporulation septation of aerial hyphae of Streptomyces coelicolor A3(2) and for the expression of at least some late sporulation genes. DNA complementing whiH mutants was located immediately upstream on hrdB, which encodes the principal sigma factor of S. coelicolor. Sequencing revealed a gene whose disruption gave rise to a typical whiH mutant phenotype. Four whiH mutants contained base changes or a frameshift in this gene. The deduced product of whiH related to a large family of bacterial regulatory proteins, the most similar being several repressors (such as GntR of Bacillus subtilis) responsive to carboxylate-containing intermediates in carbon metabolism. Transcription of whiH was initiated at a single promoter, PwhiH. Levels of whiH mRNA were developmentally regulated, increasing sharply when aerial mycelium was present, and reaching a maximum approximately when spores were first detectable. Transcript levels were markedly increased in a whiH mutant, indicating the possible involvement of WhiH in negative regulation of its own production. PwhiH was directly dependent on the sigma factor encoded by another sporulation gene, whiG, as shown by in vivo and in vitro transcription analysis.