Three in-frame N-terminally different proteins are produced from the repressor locus of the Streptomyces bacteriophage phi C31

An Unusual Phage Repressor Encoded by Mycobacteriophage BPs

Temperate bacteriophages express transcription repressors that maintain lysogeny by down-regulating lytic promoters and confer superinfection immunity. Repressor regulation is critical to the outcome of infection—lysogenic or lytic growth—as well as prophage induction into lytic replication. Mycobacteriophage BPs and its relatives use an unusual integration-dependent immunity system in which the phage attachment site (attP) is located within the repressor gene (33) such that site-specific integration leads to synthesis of a prophage-encoded product (gp33¹⁰³) that is 33 residues shorter at its C-terminus than the virally-encoded protein (gp33¹³⁶). However, the shorter form of the repressor (gp33¹⁰³) is stable and active in repression of the early lytic promoter P_R, whereas the longer virally-encoded form (gp33¹³⁶) is inactive due to targeted degradation via a C-terminal ssrA-like tag. We show here that both forms of the repressor bind similarly to the 33–34 intergenic regulatory region, and that BPs gp33¹⁰³ is a tetramer in solution. The BPs gp33¹⁰³ repressor binds to five regulatory regions spanning the BPs genome, and regulates four promoters including the early lytic promoter, P_R. BPs gp33¹⁰³ has a complex pattern of DNA recognition in which a full operator binding site contains two half sites separated by a variable spacer, and BPs gp33¹⁰³ induces a DNA bend at the full operator site but not a half site. The operator site structure is unusual in that one half site corresponds to a 12 bp palindrome identified previously, but the other half site is a highly variable variant of the palindrome.

Evolutionary relationships among actinophages and a putative adaptation for growth in Streptomyces spp

The genome sequences of eight Streptomyces phages are presented, four of which were isolated for this study. Phages R4, TG1, Hau3, and SV1 were isolated previously and have been exploited as tools for understanding and genetically manipulating Streptomyces spp. We also extracted five apparently intact prophages from recent Streptomyces spp. genome projects and, together with six phage genomes in the database, we analyzed all 19 Streptomyces phage genomes with a view to understanding their relationships to each other and to other actinophages, particularly the mycobacteriophages. Fifteen of the Streptomyces phages group into four clusters of related genomes. Although the R4-like phages do not share nucleotide sequence similarity with other phages, they clearly have common ancestry with cluster A mycobacteriophages, sharing many protein homologues, common gene syntenies, and similar repressor-stoperator regulatory systems. The R4-like phage Hau3 and the prophage StrepC.1 (from Streptomyces sp. strain C) appear to have hijacked a unique adaptation of the streptomycetes, i.e., use of the rare UUA codon, to control translation of the essential phage protein, the terminase. The Streptomyces venezuelae generalized transducing phage SV1 was used to predict the presence of other generalized transducing phages for different Streptomyces species.

The complete genome sequence of the Streptomyces temperate phage straight phiC31: evolutionary relationships to other viruses

The completed genome sequence of the temperate Streptomyces phage straight phiC31 is reported. straight phiC31 contains genes that are related by sequence similarities to several other dsDNA phages infecting many diverse bacterial hosts, including Escherichia, Arthrobacter, Mycobacterium, Rhodobacter, Staphylococcus, Bacillus, Streptococcus, Lactobacillus and Lactococcus. These observations provide further evidence that dsDNA phages from diverse bacterial hosts are related and have had access to a common genetic pool. Analysis of the late genes was particularly informative. The sequences of the head assembly proteins (portal, head protease and major capsid) were conserved between straight phiC31, coliphage HK97, staphylococcal phage straight phiPVL, two Rhodobacter capsulatus prophages and two Mycobacterium tuberculosis prophages. These phages and prophages (where non-defective) from evolutionarily diverse hosts are, therefore, likely to share a common head assembly mechanism i.e. that of HK97. The organisation of the tail genes in straight phiC31 is highly reminiscent of tail regions from other phage genomes. The unusual organisation of the putative lysis genes in straight phiC31 is discussed, and speculations are made as to the roles of some inessential early gene products. Similarities between certain phage gene products and eukaryotic dsDNA virus proteins were noted, in particular, the primase/helicases and the terminases (large subunits). Furthermore, the complete sequence clarifies the overall transcription map of the phage during lytic growth and the positions of elements involved in the maintenance of lysogeny.

Oligomeric properties and DNA binding specificities of repressor isoforms from the Streptomyces bacteriophage phiC31

Three protein isoforms (74, 54 and 42 kDa) are expressed from repressor gene c in the Streptomyces temperate bacteriophage phiC31. Because expression of the two smaller isoforms, 54 and 42 kDa, is sufficient for superinfection immunity, the interaction between these isoforms was studied. The native 42 kDa repressor (Nat42) and an N-terminally 6x histidine-tagged 54 kDa isoform (His54) were shown by co-purification on a Ni-NTA column to interact in Streptomyces lividans . In vitro three repressor preparations, containing Nat42, His54 and the native 54 and 42 kDa isoforms expressed together (Nat54&42), were subjected to chemical crosslinking and gel filtration analysis. Homo- and hetero-tetramers were observed. Previous work showed that the smallest isoform bound to 17 bp operators containing aconservedinvertedrepeat (CIR) and that the CIRs were located at 16 loci throughout the phiC31 genome. One of the CIRs (CIR6) is believed to be critical for regulating the lytic pathway. The DNA binding activities of the three repressor preparations were studied using fragments containing CIRs (CIR3-CIR6) from the essential early region as templates for DNase I footprinting. Whereas Nat42 bound to CIR6, poorly to CIR5 but undetectably to CIR3 or CIR4, the Nat54&42 preparation could bind to all CIRs tested, albeit poorly to CIR3 and CIR4. The His54 isoform bound all CIRs tested. Isoforms expressed from the phiC31 repressor gene, like those which are expressed from many eukaryotic transcription factor genes, apparently have different binding specificities.

In vitro site-specific integration of bacteriophage DNA catalyzed by a recombinase of the resolvase/invertase family

The genome of the broad host range Streptomyces temperate phage, phiC31, is known to integrate into the host chromosome via an enzyme that is a member of the resolvase/invertase family of site-specific recombinases. The recombination properties of this novel integrase on the phage and Streptomyces ambofaciens attachment sites, attP and attB, respectively, were investigated in the heterologous host, Escherichia coli, and in an in vitro assay by using purified integrase. The products of attP/B recombination, i.e., attL and attR, were identical to those obtained after integration of the prophage in S. ambofaciens. In the in vitro assay only buffer, purified integrase, and DNAs encoding attP and attB were required. Recombination occurred irrespective of whether the substrates were supercoiled or linear. A mutant integrase containing an S12F mutation was completely defective in recombination both in E. coli and in vitro. No recombination was observed between attB/attB, attP/attP, attL/R, or any combination of attB or attP with attL or attR, suggesting that excision of the prophage (attL/R recombination) requires an additional phage- or Streptomyces-encoded factor. Recombination could occur intramolecularly to cause deletion between appropriately orientated attP and attB sites. The results show that directionality in phiC31 integrase is strictly controlled by nonidentical recombination sites with no requirement to form the topologically defined structures that are more typical of the resolvases/invertases.

Isolation and sequencing of the rho gene from Streptomyces lividans ZX7 and characterization of the RNA-dependent NTPase activity of the overexpressed protein

The gene for transcription termination factor Rho was isolated from Streptomyces lividans ZX7. It encoded a 77-kDa polypeptide (Rho 77) with considerable homology to known Rho factors. An atypical hydrophilic region of 228 residues was found within the N-terminal RNA-binding domain. Only Rho from Micrococcus luteus and Mycobacterium leprae (closely related GC-rich Gram-positive bacteria) had an analogous sequence. Rho 77 was overexpressed in Escherichia coli and purified using an N-terminal hexahistidine-tag. Rho 77 displayed a broad RNA-dependent ATPase activity, with poly(C) RNA being no more than 4-fold more effective than poly(A). This contrasts with the ATPase activity of Rho from E. coli which is stimulated primarily by poly(C) RNA. Rho 77 was a general RNA-dependent NTPase, apparent Km values for NTPs were: GTP 0.13 mM, ATP 0.17 mM, UTP 1.1 mM, and CTP >2 mM. Rho 77 poly(C)-dependent ATPase activity was inhibited by heparin, unlike the E. coli Rho. The antibiotic bicyclomycin inhibited the in vitro RNA-dependent ATPase activity of Rho 77, did not inhibit growth of streptomycetes but delayed the development of aerial mycelia. N-terminal deletion analysis to express a truncated form of Rho (Rho 72, 72 kDa) indicated that the first 42 residues of Rho 77 were not essential for RNA-dependent NTPase activity and were not the targets of inhibition by heparin or bicyclomycin.

Gene expression in the cos region of the Streptomyces temperate actinophage phi C31

A transcription map of a 5.12 kb region containing the cos ends of actinophage phi C31 was determined using RNA prepared from induced and uninduced cultures of the temperature-sensitive lysogen, Streptomyces coelicolor A3(2) (phi C31cts1). In induced cultures, RNA synthesis was detected only late in the lytic cycle. A late operon initiated downstream of the int gene on the right-hand end of the genome traversed the cos ends and extended at least 3.6 kb along the left-hand end. Shorter, possibly processed, mRNAs were also present. The map was superimposed on the DNA sequence of 2.8 kb of the region, part of which had been determined previously and part of which is presented here. The late-expressed transcripts contained a tRNA(Thr)-like gene and four ORFs (1, 2, 3 and 5) detected on the basis of codon bias. Analysis of the putative protein products showed that one of the ORFs could encode a lysis protein and at least one may be involved in DNA maturation. Transcription mapping of RNA from uninduced cultures demonstrated a 620 nt transcript, xRNA1, of ORF6. So far this is the only gene in phi C31 found to be expressed right to left with respect to the standard map of phi C31; its function during lysogenic growth could not be deduced from database searches.

Characterization of a late promoter from the Streptomyces temperate phage phi C31

An operon expressed late in the lytic cycle of the Streptomyces temperate phage phi C31 was shown to be transcribed from an inducible promoter, phi lp (phage late promoter), which resembled the previously reported early promoters. mRNAs initiated at phi lp were processed at the 3' end (and possibly also the 5' end) of a tRNA(Thr)-like sequence, resulting in leaderless polycistronic mRNAs.

Control of lytic development in the Streptomyces temperate phage phi C31

The repressor gene, c, is required for maintenance of lysogeny in the Streptomyces phage phi C31. 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 phi C31 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 phi C31. To the right of CIR6, according to the standard map of phi C31, an 'immediate-early' promoter, ap1, was discovered after insertion of a fragment containing CIR6 upstream of a promoterless kanamycin-resistance gene, aphII, to form pCIA2. pCIA2 conferred kanamycin resistance upon Streptomyces coelicolor A3(2) but not upon a phi C31 lysogen of S. coelicolor. Operator-constitutive (Oc) 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, phi C31 vir1, capable of forming plaques on an S. coelicolor phi C31 lysogen. phi C31vir1 contained a DNA inversion with the breakpoints lying within the integrase gene (which lies approximately 7 kbp 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 phi C31 vir1. Band-shift assays and DNase I footprinting experiments using purified 42 kDa 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 Oc 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.

Advances in heterologous gene expression by Streptomyces

During the past year, noteworthy advances have been made in our ability to express foreign genes in Streptomyces. These advances were due, in part, to a detailed examination of the critical parameters that limit expression by Streptomyces of soluble forms of the human T-cell receptor CD4. Significant progress has also been made in our understanding of transcriptional regulation and protease gene expression. Application of this knowledge to expression vector design and the construction of alternative expression hosts should improve our ability to easily and routinely express foreign genes in Streptomyces.

Sequence of the essential early region of phi C31, a temperate phage of Streptomyces spp. with unusual features in its lytic development

The temperate phage phi C31 is the most studied bacteriophage infecting Streptomyces spp., and has been used to develop an extensive and widely used series of cloning vectors. The sequence of 10 kb of phi C31 DNA containing most or all of the essential early genes was determined. Among the ORFs, 14 (perhaps 15) appear to be protein-coding, and these have been designated ORF1 to ORF14 and ORFX. Previously mapped transcripts appear to initiate upstream from ORFs 1, 8, 11 and 12, and within ORF3 and ORF12, in each case close to one example of the unusual ('21-mer') sequences that appear to serve as a recognition site for RNA polymerase early in the phi C31 lytic cycle [Ingham et al., Mol. Microbiol. 9 (1993) 1267-1274]. Further copies of the 21-mer are upstream from ORF2 and ORF13. There are four recognisable examples of a conserved inverted repeat sequence motif (CIR) thought to bind phi C31 repressor [Smith and Owen, Mol. Microbiol. 5 (1991) 2833-2844]. Only one CIR is closely associated with a 21-mer sequence, though three are located between known transcription units. Of all 14 ORFs, only one (ORF11) would encode a protein unmistakably resembling other known proteins; its product appears to be a DNA polymerase. Strikingly, two codons, TTA (Leu) and AGG (Arg), are absent from the 14 ORFs.

An operator associated with autoregulation of the repressor gene in actinophage phiC31 is found in highly conserved copies in intergenic regions in the phage genome

Previous reports have suggested that the repressor gene, c, of phiC31 is autoregulated and that likely operators are conserved inverted repeat sequences (CIRs1&2) located just upstream of the promoters, cp1 and cp2. Evidence is now presented that the CIRs 1&2 are indeed binding sites for one of the three inframe, N-terminally different protein isoforms of 42, 54 and 74 kDa produced by the c gene. A cp1-aphII fusion was repressed in a Streptomyces coelicolor A3(2) phiC31 lysogen and characterisation of an operator-constitutive (Oc) mutant showed a single mutation in CIR-1. CIR-1 containing fragments were retarded in electrophoresis gels by the 42 kDa repressor protein isoform and this retardation was inhibited by the addition of competing DNA fragments containing either CIR-1 or CIR-2. Using a combination of Southern blotting and analysis of available DNA sequence we also show that at least 18 copies of the CIRs are present throughout the phiC31 genome. Alignment of 9 CIR sequences showed that 8 contained a perfectly conserved 17 bp core whilst the exception had a single mismatch. The core includes a 16 bp inverted repeat (IR), and is usually part of a more extensive and less highly conserved palindrome. When superimposed on a previously derived transcription map of the early region, the CIRs lie in intergenic regions associated with transcription initiation and/or termination.

Multiple novel promoters from the early region in the Streptomyces temperate phage phi C31 are activated during lytic development

Evidence is presented that transcription of most of the early genes in the Streptomyces coelicolor A3(2) phage phi C31 is from a series of unusual promoters that depend on a function expressed early in the phi C31 lytic cycle. Primer extension analysis on the 5' ends of three early mRNAs, from samples prepared 10 min after induction of a thermosensitive phi C31 lysogen, showed that the 5' ends all mapped close to highly similar sequences, which are proposed to be an important part of phage-specific promoters. In a shotgun cloning experiment, a fragment containing one of these sequences strongly activated transcription of the xyIE reporter gene in plaques of a phi C31-derived promoter-probe vector. Another of the sequences was inserted into a xyIE-containing promoter-probe plasmid vector, and promoted xyIE expression only when the host was supporting the lytic cycle of phi C31. This suggested that a transcription factor needed for activity of the promoters was present only in phi C31-infected cells. Examination of published and unpublished phi C31 sequence data revealed several more sequences that closely resemble the conserved region of the characterized promoters. Most of these are found in positions close to apparent transcription start sites mapped previously by low-resolution S1 mapping. An overall consensus sequence for the conserved region suggests a general organization (though not a primary sequence) resembling that of promoters recognized in other bacteria by the sigma 54 form of RNA polymerase.

Differential expression of principal sigma factor homologues of Streptomyces aureofaciens correlates with the developmental stage

In previous experiments, Streptomyces aureofaciens has been shown to contain four genes hrdA, hrdB, hrdD, and hrdE, encoding polypeptides very similar to principal sigma factors of RNA polymerase. Two apparent tandem promoters were identified for each of the hrdA, hrdB and hrdD genes by S1 nuclease mapping using RNA prepared of S. aureofaciens in various developmental stages. Under all the conditions studied, tandem promoters of each gene differed significantly in their respective strengths. Transcription from the hrd promoters depended on developmental stage. While hrdB is transcribed from both promoters in all developmental stages, both tandem promoters of the hrdD gene are active only in vegetative stage and transcription of the hrdA tandem promoters temporally correlates with the aerial mycelium formation. In addition to a promoter, hrdB-P2, which lies upstream of the open reading frame, the hrdB gene, proposed to encode functional principal factor, appeared to contain at least one internal promoter, hrdB-P1. Activity of all promoters was consistent with S1 mapping experiments after insertion of promoter-bearing DNA fragments to promoter-probe vectors pIJ486 and pARC1. The results implicate temporally different expression of the hrd genes during the differentiation of S. aureofaciens.

Transcription map of the early region of the Streptomyces bacteriophage phi C31

Streptomyces coelicolor A3(2), lysogenised by the temperature-sensitive cts1 mutant of phi C31, can be synchronously induced into the lytic cycle by heat treatment. A transcription map of 10 kb of the phi C31 early gene cluster was deduced using low-resolution S1 nuclease mapping of RNA prepared 10 min after induction. At least nine early transcripts, early (e)RNAs 1-9, were localised reading exclusively rightwards with respect to the standard physical map of phi C31. The mRNAs were extensively overlapping, frequently initiating at the same place but terminating at different sites, and vice versa. Gene expression during the lytic cycle was tightly regulated; no transcription was observed before induction. Transcription was maximal at 10 min post-induction, and at 20 min, eRNAs 5 and 6 persisted whilst eRNAs 7-9 were severely reduced or absent. The pattern of transcription of the early region is consistent with the simultaneous activation of a large number of promoters and differential termination efficiency.

Gene expression in the Streptomyces temperate phage phi C31

The repressor gene, c, of the temperate Streptomyces phage, phi C31 was previously cloned and sequenced, and predicted to encode a 74-kDa protein. The c gene actually produces three in-frame, N-terminally different, C-terminally identical proteins of 74, 54 and 42 kDa. The repressor proteins are translated from a corresponding nest of transcripts. Genetic and biochemical evidence suggests that the transcription of the c locus is autoregulated possibly by the 42-kDa protein binding to a highly conserved 16-bp perfect inverted repeat. The 16-bp sequence is present at at least twelve loci throughout the phi C31 genome. Transcription of the 'early' region is complex, possibly involving phage-specific promoters. The phi C31 terminators display sequence conservation and may be regulated. The phi C31 gene 'k' may encode a nucleotide kinase-encoding gene.

Compilation and analysis of DNA sequences associated with apparent streptomycete promoters

The DNA sequences associated with 139 apparent streptomycete transcriptional start sites are compiled and compared. Of these, 29 promoters appeared to belong to a group which are similar to those recognized by eubacterial RNA polymerases containing sigma 70-like subunits. The other 110 putative promoter regions contain a wide diversity of sequences; several of these promoters have obvious sequence similarities in the -10 and/or -35 regions. The apparent Shine-Dalgarno regions of 44 streptomycete genes are also examined and compared. These were found to have a wide range of degree of complementarity to the 3' end of streptomycete 16S rRNA. Eleven streptomycete genes are described and compared in which transcription and translation are proposed to be initiated from the same or nearby nucleotide. An updated consensus sequence for the E sigma 70-like promoters is proposed and a potential group of promoter sequences containing guanine-rich -35 regions also is identified.