Phase variation in the phage growth limitation system of Streptomyces coelicolor A3(2)

The phase-variable phage growth limitation (Pgl) system of Streptomyces coelicolor A3(2) is an unusual bacteriophage resistance mechanism that confers protection against the temperate phage phiC31 and homoimmune relatives. Pgl is subject to phase variation, and data presented here show that this is at least partially due to expansion and contraction of a polyguanine tract present within the putative adenine-specific DNA methyltransferase gene, pglX. Furthermore, the pglX paralogue SC6G9.02, here renamed pglS, was shown to be able to interfere with the Pgl phenotype, suggesting that PglS could provide an alternative activity to that conferred by PglX.     

Control of lytic development in the Streptomyces temperate phage φC31

The repressor gene. c, is required for maintenance of lysogeny in the Streptomyces phage φC31. The c gene expresses three in-frame N-terminally different protein isoforms at least one of which is thought to bind to a 17bp highly conserved inverted repeat (CIR) sequence found at 18 (or more) loci throughout the φC31 genome. Here we present evidence that one of these loci, CIR6, and its interaction with the products of the repressor gene are critical in the control of the lytic pathway in φC31. To the right of CIR6, according to the standard map of φC31, an ‘immediate-early’ promoter. ap1, was discovered after insertion of a fragment containing CIR6 upstream of a promoterless kanamycin-resistance gene. aphll, to form pCIA2. pCIA2 conferred kanamycin resistance upon Streptomyces coelicolor A3(2) but not upon a φC31 lysogen of S. coelicolor. Operator-constitutive (O^c) mutants of pCIA2 were isolated and the mutations lay in CIR6, i.e. CIR6:G14T and CIR6:C2A. Primer extension analysis of RNA prepared from an induced, temperature-sensitive lysogen of S. coelicolor localized a mRNA 5′ endpoint 21 bp to the right of CIR6. The importance of the ap1/CIR6 region in the regulation of lytic growth was demonstrated by the analysis of a virulent mutant, φC31 vir1, capable of forming plaques on an S. coelicolorφC31 lysogen, φC31 vir1 contained a DNA inversion with the breakpoints lying within the integrase gene (which lies approximately 7kbp to the right of CIR6) and in the essential early region between CIR6 and the -10 sequence for ap1. The separation of ap1 from its operator was thought to be the basis for the virulent phenotype in φC31 vir1. Band-shift assays and DNase I footprinting experiments using purified 42kDa repressor isoform confirmed that CIRs 5 and 6 were indeed the targets for binding of this protein. The 42 kDa repressor bound to CIR6 with higher affinity than to CIR5 in spite of their identical core sequences. Repressor bound at CIR6 facilitated binding at CIR5. The high-affinity binding to CIR6 was abolished with the O^c mutant, CIR6:G14T. Hydroxyl radical footprinting and dimethyl sulphate methylation protection of the 42 kDa repressor–CIR6 interaction suggested that the protein bound in the major groove and to one face of the DNA.     

Structural characteristics of the Streptomyces bacteriophage φC31

Abstract Some structural characteristics of the Streptomyces phage φC31 were analyzed. A simpler and at least 50 times more efficient method than those previously described for isolating the phage is reported. The phage is naked, showing a polyhedral head 53 nm wide, a long non-contractile tail 100 × 5 nm, a basal plate 15 nm in diameter with at least one pin, and a prominent knot between the head and the tail. Up to 17 polypeptides had been found in the virion. Four of them, of 51, 38.5, 29.5 and 28 kDa, make up around 84% of the total protein of the particle.     

Genetic analysis of A-factor synthesis in Streptomyces coelicolor A3(2) and Streptomyces griseus

A-factor is a potent pleiotropic effector produced by Streptomyces griseus and is essential for streptomycin production and spore formation in this organism. Its production is widely distributed among various actinomycetes including Streptomyces coelicolor A3(2). Genetic analysis of A-factor production was carried out with S. coelicolor A3(2), and two closely linked loci for A-factor mutations (afsA and B) were identified between cysD and leuB on the chromosomal linkage map. In contrast, genetic crosses of A-factor-negative mutants of S. griseus, using a protoplast fusion technique, failed to give a fixed locus for A-factor gene(s) and suggested involvement of an extrachromosomal or transposable genetic element in A-factor synthesis in this organism.     

Temperature-sensitive mutants of actinophage phi C31 of Streptomyces coelicolor A3(2)]

Temperature-sensitive mutants of phiC31 actinophage were isolated by the treatment with nitrosoquanidine and UV light. 20 cistron which control various stages of intracellular phage growth are identified on the basis of modified complementation tests. The sequence of ts markers and c-region is established and the relative distance between them is estimated according to the results of three factor crosses.     

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.     

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.     

SCP1-dependent Weigle activation of the VP5 phage in Streptomyces coelicolor A3(2)

The kinetics of induction of the UV-irradiated bacteriophage VP5 (Weigle reactivation) in Streptomyces coelicolor A3(2) strains with and without plasmid was investigated. Chloramphenicol (CAF) inhibits Weigle reactivation (WR) in UF strains (SCP1 absent) but not in SCP1+ strains of IF fertility (free plasmid). CAF, moreover, inhibits protein synthesis in non-irradiated UF and IF strains. In UV-irradiated IF strains, on the other hand, protein synthesis takes place irrespective of CAF. Weigle reactivation appears to require protein synthesis: the SCP1 plasmid, by protecting protein synthesis from CAF inhibition in UV-irradiated strains, allows WR. The proteins synthesized after UV induction during the pre-incubation period were investigated and the results suggest that a new UV-induced protein, coded by a gene localized on the plasmid, interacts with the cellular SOS system.     

Genetic mapping of unstable chloramphenicol resistance determinant in Streptomyces coelicolor A3(2)

The results indicative of chromosomal localization of the unstable chloramphenicol resistance determinant in Streptomyces coelicolor A3(2) have been obtained. Independent mutations specifying chloramphenicol sensitivity in different strains of S. coelicolor A3(2), S18 and A617M are localized in the same region flanked by markers argA1 and cysD18 on the genetic map. Mutations restoring chloramphenicol resistance are also localized in this region. Different locations of the genetically unstable determinant of chloramphenicol resistance detected in various laboratories are discussed, in relation to the results showing that transfer to chloramphenicol sensitivity is due to a set of various rearrangements (deletions, amplifications, deamplifications, etc.), differing in separate variants.     

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.