Cloning of whiG, a gene critical for sporulation of Streptomyces coelicolor A3(2).

In whiG mutants of Streptomyces coelicolor A3(2), aerial hyphae do not show any sign of sporulation. A library of S. coelicolor DNA was prepared in a phi C31 temperate phage vector (KC516), and one recombinant phage (KC750) that could restore the wild-type phenotype to a collection of whiG mutants when integrated into their genomes was found. Subcloning experiments with low- and high-copy-number Streptomyces plasmid vectors allowed partial localization of whiG in the cloned DNA and revealed that hypersporulation was associated with the presence of extra copies of whiG.     

Glycosylation of the phosphate binding protein, PstS, in Streptomyces coelicolor by a pathway that resembles protein O-mannosylation in eukaryotes

Previously mutations in a putative protein O -mannosyltransferase (SCO3154, Pmt) and a polyprenol phosphate mannose synthase (SCO1423, Ppm1) were found to cause resistance to phage, φC31, in the antibiotic producing bacteria Streptomyces coelicolor A3(2). It was proposed that these two enzymes were part of a protein O-glycosylation pathway that was necessary for synthesis of the phage receptor. Here we provide the evidence that Pmt and Ppm1 are indeed both required for protein O-glycosylation. The phosphate binding protein PstS was found to be glycosylated with a trihexose in the S. coelicolor parent strain, J1929, but not in the pmt ⁻ derivative, DT1025. Ppm1 was necessary for the transfer of mannose to endogenous polyprenol phosphate in membrane preparations of S. coelicolor . A mutation in ppm1 that conferred an E218V substitution in Ppm1 abolished mannose transfer and glycosylation of PstS. Mass spectrometry analysis of extracted lipids showed the presence of a glycosylated polyprenol phosphate (PP) containing nine repeated isoprenyl units (C₄₅-PP). S. coelicolor membranes were also able to catalyse the transfer of mannose to peptides derived from PstS, indicating that these could be targets for Pmt in vivo .     

Genetic characteristics and genome structure of Streptomyces coelicolor actinophages]

Actinophage phi C31 of Streptomyces coelicolor A3 (2) and two novel temperate actinophages phi C43 and phi C62 isolated from strains of blue actinomycetes group are homoimmune, serologically and functionally related. DNA molecules of phages phi C31, phi C43 and phi C62 have cohesive ends; sizes of DNAs of these phages and some mutants have been determined. The extent of homology between the DNAs of three phages is 93-96% as shown by heteroduplex analysis. The regions of non-homology are of a deletion-insertion type and of approximately 1500 base pairs in the length. Location of deletions in DNAs of mutant phages phi C31 vd and phi C31 c5 has been shown. Structural modifications in phage dnas have been found only to occur in the right part of molecules. Heteroduplex maps have been constructed for all phages studied.     

Characterization of Temperate Actinophage φC31 Isolated from Streptomyces coelicolor A3(2)

Actinophage phiC31 isolated from Streptomyces coelicolor A3(2), the only strain among actinomycetes for which a genetic map had been constructed, appears to be a typical temperate phage. After phiC31 infection, true lysogenic cultures arose which liberated phage and were immune to infection with homologous phage after repeated single-colony isolations and treatment with phage-specific antiserum. Clear-plaque (c) mutants were derived from phiC31 phage which failed to lysogenize sensitive cultures. Actinophage phiC31 has a temperature-sensitive stage of reproduction. A phage which reproduces with the same effectiveness at high (37 C) and low (28 C) temperatures has also been obtained. Heat-inducible (ct) mutants were isolated from this phage which were able to lysogenize sensitive cultures at 28 C but failed to do so at 37 C. Properties of ct mutants suggest that ct mutations involve a gene controlling maintenance of the lysogenic state in actinomycetes and synthesizing repressor, which may become heat-sensitive as a result of mutation.     

A gene encoding a homologue of dolichol phosphate-beta-D-mannose synthase is required for infection of Streptomyces coelicolor A3(2) by phage (phi)C31

We have shown previously that a gene encoding a homologue to the eukaryotic dolichol-phosphate-D-mannose, protein O-D-mannosyltransferase, was required for (phi)C31 infection of Streptomyces coelicolor. Here we show that a gene encoding the homologue to dolichol-phosphate-mannose synthase is also essential for phage sensitivity. These data confirm the role of glycosylation in the phage receptor for (phi)C31 in S. coelicolor.     

Dispensable sequences and packaging constraints of DNA from the Streptomyces temperate phage phi C31

Deletion mutants of the temperate Streptomyces phage phi C31 were selected by two methods: resistance to the chelating agent sodium pyrophosphate, and plating of a phi C31::pBR322 hybrid phage on Streptomyces albus G to obtain large plaque mutants. The deletions defined a 7.7 kilobase (kb) segment of the phi C31 genome which is inessential for plaque formation, in addition to a shorter segment including the repressor gene. Analysis of deletions and insertions suggested that the minimum size of the phi C31 genome allowing plaque formation is 37.5 kb (91% of the wild-type length of 41.2 kb), and the maximum is at least 42.4 kb (103%). These results indicate that it should be possible to introduce up to 10 kb of foreign DNA into a suitably developed phi C31 vector.     

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.     

A Streptomyces coelicolor Antibiotic Regulatory Gene, absB, Encodes an RNase III Homolog

Streptomyces coelicolor produces four genetically and structurally distinct antibiotics in a growth-phase-dependent manner. S. coelicolor mutants globally deficient in antibiotic production (Abs(-) phenotype) have previously been isolated, and some of these were found to define the absB locus. In this study, we isolated absB-complementing DNA and show that it encodes the S. coelicolor homolog of RNase III (rnc). Several lines of evidence indicate that the absB mutant global defect in antibiotic synthesis is due to a deficiency in RNase III. In marker exchange experiments, the S. coelicolor rnc gene rescued absB mutants, restoring antibiotic production. Sequencing the DNA of absB mutants confirmed that the absB mutations lay in the rnc open reading frame. Constructed disruptions of rnc in both S. coelicolor 1501 and Streptomyces lividans 1326 caused an Abs(-) phenotype. An absB mutation caused accumulation of 30S rRNA precursors, as had previously been reported for E. coli rnc mutants. The absB gene is widely conserved in streptomycetes. We speculate on why an RNase III deficiency could globally affect the synthesis of antibiotics.     

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.     

Genetic evidence for possible interaction between a ribonucleic acid polymerase subunit and the spo0C gene product of Bacillus subtilis.

Spontaneous rifampin-resistant mutants (9V Rifr) were isolated from a mutant strain of Bacillus subtilis, 9V, which has a spo0C mutation. Whereas 90% of the 9V Rifr double mutants maintained the Spo0C phenotype (Spo- Abs +/-), the remaining 10% had the Spo0A phenotype (Spo- Abs-). The latter mutants, termed 9V Rifr Spo- Abs-, were revealed to have other Spo0A characters, such as reduced transformability, higher sensitivity to phage phi 2, and reduced frequency of lysogenization by phage phi 105. The rif mutation of these 9V Rifr Spo- Abs- strains was mapped near the cysA locus. The phenotype of the Rifr transformants of strain 9V by deoxyribonucleic acid derived from these 9V Rifr Spo- Abs- strains was Spo0A, and that of the Rifr transformants of strain 168 was Spo+ Abs+. The ribonucleic acid polymerase of the 9V Rifr Spo- Abs- strains was shown to be resistant to rifampin.     

Identification of the restriction and modification systems in Streptomyces strains]

Host range of actinophage phi C31, VP5 and Pg81 in respect to 109 strains of Streptomyces genus and hybrid strain Rcg2 from the cross S. coelicolor A3(2)XS. griseus Kr was studied. The existence of RM-systems in strains S. griseus Kr15, S. griseus Kr20, Rcg2, S. griseofovillus 43 was shown using phage Pg81. Mutants of Pg81 were observed which to some extent lost snesitivity to RM-system in the strain Rcg2. The presence of RM-system in S. lividans 67 was demonstrated by the phage VP5.     

Phi SC623, a temperate actinophage of Streptomyces coelicolor Müller, and its relatives phi SC347 and phi SC681

Three species-specific, temperate actinophages of Streptomyces coelicolor Müller, phi SC623, phi SC347 and phi SC681, were compared with respect to host range, virion structure, antiserum cross-inactivation, DNA-restriction pattern, DNA hybridization, and DNA base composition. The restriction map of phi SC623 (57 kb) was established with eight restriction enzymes; the homologies of this phage with phi SC347 and phi SC681 suggested that it might be a hybrid phage composed of approximately equal parts homologous to one of the other two phages. No homology was detected between phi SC623 and R4, a temperate, wide-host-range phage which can also lysogenize S. coelicolor Müller.     

Phage-mediated cloning of bldA, a region involved in Streptomyces coelicolor morphological development, and its analysis by genetic complementation.

Streptomyces coelicolor bald (bld) mutants form colonies of vegetative substrate mycelium, but do not develop aerial hyphae or spore chains. The bldA strains form none of the four antibiotics known to be produced by the parent strain. With a vector derived from the temperate bacteriophage phi C31, a 5.6-kilobase fragment of wildtype DNA was cloned which restored sporulation to five independent bldA mutants when lysogenized with the recombinant phage. The cloned gene(s) was dominant over the mutant alleles. Phage integration by recombination of the cloned bldA+ DNA with the bldA region of each mutant produced mainly sporulating colonies, presumably heterozygous bldA+/bldA partial diploids for the insert DNA. However, a minority of these primary transductants were bald and were apparently homozygous bldA/bldA mutant partial diploids, formed by some homogenetization process. The phages released from the bald lysogens carried bldA mutations and were used to show that bldA+ sequences had been cloned and that fine mapping of the region could be performed.     

The Streptomyces coelicolor A3(2) bldB region contains at least two genes involved in morphological development

Streptomyces coelicolor A3(2) bldB mutants are blocked in the formation of aerial hyphae. A phage library of wild-type S. coelicolor DNA was used to isolate recombinant phages which restore wild-type morphological development to several bldB mutants. Of several mutations, one, bld-28, previously mapped at bldB was not complemented by the cloned region, indicating that the bldB locus is composed of at least two distinct genes. Partial localization of bldB-complementing activity showed that a 1.5 kb fragment is sufficient for complementation of the bld-15 mutation whereas bld-17 requires the same region as well as additional sequences. Under stringent conditions, genomic DNA hybridizing to the cloned sequences was absent from other Streptomyces species, including the closely related Streptomyces lividans 66. DNA sequences causing marked plasmid structural instability in S. coelicolor, but not in S. lividans, are also located in this region.     

Plasmid cloning vectors that integrate site-specifically in Streptomyces spp

Cloning vectors based on the Streptomyces ambofaciens plasmid pSAM2 and the streptomycete phage phi C31 were developed for use in Streptomyces spp. These vectors replicate in Escherichia coli but integrate by site-specific recombination in Streptomyces spp. Both pSAM2-based and phi C31-based vectors transformed a number of different Streptomyces spp; however, the phi C31-based vectors consistently transformed at higher frequencies than pSAM2-based vectors. Southern analysis indicated that the phi C31-based vectors integrated at a unique site in the S. ambofaciens chromosome, while the pSAM2-based vectors gave complex patterns which could indicate structural instability or use of multiple loci. Both types of vectors utilize the apramycin (Am)-resistance gene which can be selected in E. coli and Streptomyces spp. with either Am or the commercially available antibiotic Geneticin (G418).     

The expression of Streptomyces and Escherichia coli drug-resistance determinants cloned into the Streptomyces phage phi C31

Lysogens obtained by infecting Streptomyces albus G with a phi C31-pBR322 chimaeric prophage or its delta W12 deletion derivative had increased tetracycline resistance. The ability of the delta W12 derivative to transduce tetracycline resistance was inactivated by inserting a viomycin resistance determinant (vph) into the BamHI site of the pBR322 tet gene, and restored by excising the vph gene. Another deletion mutant (delta W17) of the chimaera, carrying an intact tet gene, was normally unable to transduce tetracycline resistance. This inability was correlated with the finding, by Southern hybridisation analysis, that the att site required for insertion of phi C31 prophage into the host chromosome was located within the delta W17 deletion. Use of phi C31 lysogenic recipient permitted the integration of the att-deleted phage, presumably by homologous recombination, giving tetracycline-resistant double lysogens. This technique was extended to S. coelicolor A3(2) in the detection of derivatives of the att-deleted phage into which a thiostrepton-resistance determinant (tsr) had been inserted in vitro. Phage released from double lysogens were mainly recombinants. One such recombinant is a PstI vector for DNA cloning, able to accommodate up to 6 kb of introduced DNA.     

New derivatives of the Streptomyces temperate phage phi C31 useful for the cloning and functional analysis of Streptomyces DNA

The thiostrepton resistance gene (tsr) of Streptomyces azureus, and a synthetic oligonucleotide adapter sequence, were introduced into the DNA of attP-site-deleted phage phi C31-based cloning vectors. The DNA of two of the new derivatives, KC515 and KC516, contains single sites for the enzymes BamHI, BglII, PstI, PvuII, SstI (two sites close together) and XhoI, available for the insertion of DNA of up to 4 kb. The two vectors also contain a cloned, promoterless viomycin phosphotransferase gene (vph) from Streptomyces vinaceus. When an internal segment of the Streptomyces coelicolor glycerol (gyl) operon was inserted at the appropriate position and in the correct orientation next to vph, it could bring about in vivo recombination leading to fusion of vph of the chromosomally located gyl operon, resulting in glycerol-regulated expression of viomycin resistance. Two other new phi C31 derivatives, KC505 and KC518, are PstI and BamHI replacement vectors, respectively, for 2-8-kb DNA fragments, and allow simple screening for the presence of inserted DNA.     

Genetic mapping and characteristics of the actinophage phi C31 deletion mutants of Streptomyces coelicolor A3(2) incapable of lysogenization

Actinophage phi C31 deletion c mutants with impaired ability to make repressor were genetically studied. Genetic crosses indicate that the c28 deletion mutant is situated with the c-region of the phi C31 genetic map. Based on the results of a qualitive test for recombination between several c mutants, a scheme of their order relative to deletion mutants was presented. The approximate distances between eight c mutants have been represented in units of the physical DNA map estimation. Genetic studies of actinophage lyg deletion mutants which cannot lysogenize sensitive cultures were carried out. Mutants failed to lysogenize upon mixed infection with lyg+ phages. The absence of the effect of lyg+ gene in trans suggests that lyg deletions cause a structural defect in an integration site of the phage. Preliminary data on alignment of lyg positions on physical and genetic maps of phi C31 phage have been obtained. According to evidence from genetic crosses, lyg mutation has been located in the right half of the phi C31 genome.