Bacteriophage T7 genetics

Analysis of whole genome sequencing for the Escherichia coli O157:H7 typing phages

Background

Shiga toxin producing Escherichia coli O157 can cause severe bloody diarrhea and haemolytic uraemic syndrome. Phage typing of E. coli O157 facilitates public health surveillance and outbreak investigations, certain phage types are more likely to occupy specific niches and are associated with specific age groups and disease severity. The aim of this study was to analyse the genome sequences of 16 (fourteen T4 and two T7) E. coli O157 typing phages and to determine the genes responsible for the subtle differences in phage type profiles.

Results

The typing phages were sequenced using paired-end Illumina sequencing at The Genome Analysis Centre and the Animal Health and Veterinary Laboratories Agency and bioinformatics programs including Velvet, Brig and Easyfig were used to analyse them. A two-way Euclidian cluster analysis highlighted the associations between groups of phage types and typing phages. The analysis showed that the T7 typing phages (9 and 10) differed by only three genes and that the T4 typing phages formed three distinct groups of similar genomic sequences: Group 1 (1, 8, 11, 12 and 15, 16), Group 2 (3, 6, 7 and 13) and Group 3 (2, 4, 5 and 14). The E. coli O157 phage typing scheme exhibited a significantly modular network linked to the genetic similarity of each group showing that these groups are specialised to infect a subset of phage types.

Conclusion

Sequencing the typing phage has enabled us to identify the variable genes within each group and to determine how this corresponds to changes in phage type.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-015-1470-z) contains supplementary material, which is available to authorized users.

Complete genomic sequence of bacteriophage phiEcoM-GJ1, a novel phage that has myovirus morphology and a podovirus-like RNA polymerase

The complete genome of phiEcoM-GJ1, a lytic phage that attacks porcine enterotoxigenic Escherichia coli of serotype O149:H10:F4, was sequenced and analyzed. The morphology of the phage and the identity of the structural proteins were also determined. The genome consisted of 52,975 bp with a G+C content of 44% and was terminally redundant and circularly permuted. Seventy-five potential open reading frames (ORFs) were identified and annotated, but only 29 possessed homologs. The proteins of five ORFs showed homology with proteins of phages of the family Myoviridae, nine with proteins of phages of the family Podoviridae, and six with proteins of phages of the family Siphoviridae. ORF 1 encoded a T7-like single-subunit RNA polymerase and was preceded by a putative E. coli sigma(70)-like promoter. Nine putative phage promoters were detected throughout the genome. The genome included a tRNA gene of 95 bp that had a putative 18-bp intron. The phage morphology was typical of phages of the family Myoviridae, with an icosahedral head, a neck, and a long contractile tail with tail fibers. The analysis shows that phiEcoM-GJ1 is unique, having the morphology of the Myoviridae, a gene for RNA polymerase, which is characteristic of phages of the T7 group of the Podoviridae, and several genes that encode proteins with homology to proteins of phages of the family Siphoviridae.

Evolution of bacteriophage T7 in a growing plaque

The emergence of mutants during the 10(9)-fold amplification of a bacteriophage was spatially resolved in a growing plaque. When wild-type phage T7 was grown on an Escherichia coli host which expressed an essential early enzyme of the phage infection cycle, the T7 RNA polymerase, mutant phage relying on this enzyme appeared in 10(8) phage replications and outgrew the wild type. Spatial resolution of the selection process was achieved by analyzing stab samples taken along a plaque radius. Different mutants were selected at different rates along different radii of the plaque, based on host range and restriction patterns of the isolates. The mutants deleted up to 11% of their genomes, including the gene for their own RNA polymerase. They gained an advantage over the wild type by replicating more efficiently, as determined by one-step growth cultures.

Bacteriophage lysis: mechanism and regulation

Bacteriophage lysis involves at least two fundamentally different strategies. Most phages elaborate at least two proteins, one of which is a murein hydrolase, or lysin, and the other is a membrane protein, which is given the designation holin in this review. The function of the holin is to create a lesion in the cytoplasmic membrane through which the murein hydrolase passes to gain access to the murein layer. This is necessary because phage-encoded lysins never have secretory signal sequences and are thus incapable of unassisted escape from the cytoplasm. The holins, whose prototype is the lambda S protein, share a common organization in terms of the arrangement of charged and hydrophobic residues, and they may all contain at least two transmembrane helical domains. The available evidence suggests that holins oligomerize to form nonspecific holes and that this hole-forming step is the regulated step in phage lysis. The correct scheduling of the lysis event is as much an essential feature of holin function as is the hole formation itself. In the second strategy of lysis, used by the small single-stranded DNA phage phi X174 and the single-stranded RNA phage MS2, no murein hydrolase activity is synthesized. Instead, there is a single species of small membrane protein, unlike the holins in primary structure, which somehow causes disruption of the envelope. These lysis proteins function by activation of cellular autolysins. A host locus is required for the lytic function of the phi X174 lysis gene E.

Expression of the unassembled capsid protein during infection of Shigella sonnei by bacteriophage T7 results in DNA damage that is repairable by bacteriophage T3, but not T7, DNA ligase

The abortive infection of bacteriophage T7 in Shigella sonnei D2 371-48 is characterized by a premature inhibition of phage DNA replication and nucleolytic breakdown of all phage DNA. Mutations in T7 gene 10 which are recessive to the presence of the wild-type allele can alleviate the restriction of phage growth. Phage T3 productively infects S. sonnei D2 371-48, as does a T7-T3 hybrid phage that contains, in particular, a gene 10 of T7 origin. It is the presence of T3 DNA ligase that allows phage growth on S. sonnei D2 371-48, and this enzyme can also rescue wild-type T7 from the abortive infection. T7+ is therefore functionally ligase deficient during the infection of S. sonnei D2 371-48; this deficiency is a result of the expression of the phage capsid protein, but it is independent of the assembly of the protein into a procapsid or other morphogenetic structure.

Promoter and nonspecific DNA binding by the T7 RNA polymerase

T7 RNA polymerase plays an important role in both the transcription and replication of bacteriophage T7. In this study we have used a nitrocellulose filter binding assay to examine the binding properties of the T7 RNA polymerase with T7 promoters cloned into plasmid DNAs. Promoter-specific binding was shown to be relatively insensitive to variations in the ionic strength of the incubation solution but dependent on the helical structure of the DNA. On the other hand, nonpromoter interior-site binding was independent of the superhelicity of the DNA but extremely sensitive to changes in the ionic strength. These results suggest that nonspecific binding results from ionic interactions between positively charged residues of the polymerase and the polyanionic backbone of the DNA, whereas promoter-specific binding is dependent upon base-specific contacts within the promoter sequence. A comparison between the transcriptional activity and binding strengths of the RNA polymerase to specific promoters indicates little correlation between these two properties. This suggests that differential promoter binding does not represent a major mechanism for regulating transcription in bacteriophage T7. Instead, factors which influence the efficiency or rate of formation of the polymerase-promoter open complex are found to have the major role in determining transcriptional levels in this system.

Selection pressures on codon usage in the complete genome of bacteriophage T7

We searched the complete 39,936 base DNA sequence of bacteriophage T7 for nonrandomness that might be attributed to natural selection. Codon usage in the 50 genes of T7 is nonrandom, both over the whole code and among groups of synonymous codons. There is a great excess of purine- any base-pyrimidine (RNY) codons. Codon usage varies between genes, but from the pooled data for the whole genome (12,145 codons) certain putative selective constraints can be identified. Codon usage appears to be influenced by host tRNA abundance (particularly in highly expressed genes), tRNA-mRNA (one such interaction being perhaps responsible for maintaining the excess of RNY codons) and a lack of short palindromes. This last constraint is probably due to selection against host restriction enzyme recognition sites; this is the first report of an effect of this kind on codon usage. Selection against susceptibility to mutational damage does not appear to have been involved.

Relationship between promoter structure and template specificities exhibited by the bacteriophage T3 and T7 RNA polymerases

To explore the basis for the template specificities of the bacteriophage T3 and T7 RNA polymerases (EC 2.7.7.6), we determined the nucleotide sequences of six promoters recognized by the T3 RNA polymerase and compared them with the previously determined promoter sequences recognized by the bacteriophage T7 RNA polymerase. Recombinant plasmids containing random Hpa II and Taq I fragments of T3 DNA were screened for T3 promoter activity in vitro in a transcription assay using purified T3 RNA polymerase. Five promoters for the T3 RNA polymerase were identified in this manner and their sequences were determined; the sequence of an additional promoter was determined directly from a genomic DNA fragment. In five of the T3 promoters an identical 16-base-pair sequence (A-C-C-C-T-C-A-C-T-A-A-A-G-G-G-A) extends from -12 to +4 (initiation occurring with GTP at +1); this sequence is preceded by a 6-base-pair A + T region. The remaining promoter contains an inserted C at position -1 and an A at the +1 position. The sequence of the 5' end of the RNA transcript from the latter promoter confirms that transcription is initiated with ATP at the +1 position. Previously, late T3 or T7 transcripts had not been found to initiate with ATP. The highly conserved T3 promoter sequence was compared to the T7 promoter consensus sequence. The fundamental difference between the two kinds of phage promoters is the occurrence of G-A at positions -11 and -10 in the T7 promoter, whereas there is a single C at position -10 in the T3 promoter.

Asymmetric repair of bacteriophage T7 heteroduplex DNA

Heteroduplex DNA molecules were prepared in vitro using one strand of DNA carrying a point mutation and one strand of the corresponding wild-type DNA. The heteroduplex DNA was transfected into competent bacteria and the progeny genotypes in the resulting infective centers were determined. From the results we conclude that about 80% of all transfected DNA molecules are repaired before DNA replication starts. This fraction of repaired DNA is independent of the location of the mismatched nucleotide pair. However, mismatch correction occurs preferentially on the H strand of the heteroduplex DNA. The repair does not depend on a known phage coded function but requires the active bacterial genes mutU, mutH, mutS and probably mutL.

Mapping of promoter sites utilized by T3 RNA polymerase on T3 DNA

Promoter locations for the T3 RNA polymerase on the physical map of T3 DNa have been determined. Through the use of conditions favoring the synthesis of RNA from the class II region, an agarose-formaldehyde gel system which improves the resolution of high molecular weight RNAs, and template DNA that was cut by one of several restriction endonucleases prior to transcription, seventeen promoter locations for the T3 RNA polymerase have been mapped. Ten promoters have been identified in the class II region and one promotor has been identified in the class II region and one promotor has been identified in the early (class I) region. The locations of previously mapped class III promoters and the internal termination signal for the T3 RNA polymerase have been mapped more precisely than in previous reports. The resulting transcription map demonstrates a striking similarity to the transcription map of bacteriophage T7.

Adenosine 5'-triphosphate leakage does not cause abortive infection of bacteriophage T7 in male Escherichia coli

galU and rpsL mutations restore plating efficiency of bacteriophage T7 in male Escherichia coli without suppressing leakage of adenosine 5'-triphosphate pools.

Derivation of a restriction map of bacteriophage T3 DNA and comparison with the map of bacteriophage T7 DNA

The DNA of bacteriophage T3 was characterized by cleavage with seven restriction endonucleases. AvaI, XbaI, BglII, and HindIII each cut T3 DNA at 1 site, KpnI cleaved it at 2 sites, MboI cleaved it at 9 sites, and HpaI cleaved it at 17 sites. The sizes of the fragments produced by digestion with these enzymes were determined by using restriction fragments of T7 DNA as molecular weight standards. As a result of this analysis, the size of T3 DNA was estimated to be 38.74 kilobases. The fragments were ordered with respect to each other and to the genetic map to produce a restriction map of T3 DNA. The location and occurrence of the restriction sites in T3 DNA are compared with those in the DNA of the closely related bacteriophage T7.

Physical map of Caulobacter crescentus bacteriophage phi Cd1 DNA

A restriction map of the Caulobacter crescentus bacteriophage phi Cd1 genome was constructed by using the restriction endonucleases HindIII and HpaI. A total of 12 fragments, ranging in molecular weight from 7.7 X 10(6) to 0.25 X 10(6), were produced by HindIII, and 7 fragments, ranging in molecular weight from 9.0 X 10(6) to 0.24 X 10(6), were generated by HpaI. The molecular weight of the genome was estimated to be approximately 28.8 X 10(6) on the basis of the relative electrophoretic mobilities of the restriction fragments. The relative order of the cleavage fragments was determined by specific cleavage of isolated restriction fragments, terminal labeling of both the whole genome and isolated fragments, and hybridization of isolated fragments to restriction fragments generated by other restriction enzymes. The genome of phi Cd1 was found to be terminally repetitive, and analysis of previously determined in vivo and in vitro RNA transcripts showed that the restriction map could be oriented such that transcription began on the left and proceeded to the right end of the genome.

Physical mapping of primary and secondary origins of bacteriophage T7 DNA replication

Deletion mutants of bacteriophage T7 have been used to identify and to map, by electron microscopy, the origins of T7 DNA replication. The primary origin of phage T7 DNA replication lies within a 100-base-pair region located 14.75-15.0% of the distance from the genetic left end of the DNA molecule. T7 phage whose DNA contains a deletion of this region initiate replication at secondary origins, the predominant one of which is located at a distance approximately 4% from the left end of the molecule.

Length determination of the terminal redundant regions in the DNA of phage T7

The length of the terminal redundant regions in T7 DNA has been determined by two methods. One involved the specific labeling and isolation of the redundant DNA fragment and determination of the molecular weight by polyacrylamide gel electrophoresis. A value of 150 +/- 10 nucleotide pairs was obtained. The other determination based on a correlation of the melting temperature of the redundant region to that of whole T7 DNA confirmed the result obtained by the first method.

In vitro recombination of bacteriophage T7 DNA damaged by UV radiation

A system capable of in vitro packaging of exogenous bacteriophage T7 DNA has been used to monitor the biological activity of DNA replicated in vitro. This system has been used to follow the effects of UV radiation on in vitro replication and recombination. During the in vitro replication process, a considerable exchange of genetic information occurs between T7 DNA molecules present in the reaction mixture. This in vitro recombination is reflected in the genotype of the T7 phage produced after in vitro encapsulation; depending on the genetic markers selected, recombinants can comprise nearly 20% of the total phage production. When UV-irradiated DNA is incubated in this system, the amount of in vitro synthesis is reduced and the total amount of viable phage produced after in vitro packaging is diminished. In vitro recombination rates are also lower when the participating DNA molecules have been exposed to UV. However, biochemical and genetic measurements confirmed that there is little or no transfer of pyrimidine dimers from irradiated DNA into undamaged molecules.

In vitro packaging of bacteriophate T7 DNA synthesized in vitro

An in vitro DNA packaging system was used to encapsulate T7 DNA that had been synthesized by extracts prepared from gently lysed Escherchia coli infected with bacteriophage T7 carrying amber mutations in gene 3 or in both genes 3 and 6. Isopycnic centrifugation of density-labeled wild-type DNA was employed in an effort to separate product from template; suppressor-free indicator bacteria were used to eliminate contributions from endogenous DNA or contaminating phage. Additional controls indicated that fragmented DNA is packaged in vitro only with very low efficiency and that the frequency of recombination during packaging is too low to affect interpretation of these experiments. T7 DNA replicated by extracts prepared using T7 mutants deficient in both genes 3 and 6 could be packaged in vitro with an efficiency comparable to that found when highly purified virion T7 DNA was used. When T7 deficient in the gene 3 endonuclease but with normal levels of the gene 6 exonuclease was used, fast-sedimentingconcatemer-like DNA structures were formed during in vitro DNA synthesis. Electron microscopy revealed many branched and highly complex DNA structures formed during this reaction. This concatemer-like DNA was encapsulated in vitro with an efficiency significantly greater than that found for DNA the length of a single T7 genome.

Role of bacteriophage T7 DNA primase in the initiation of DNA strand synthesis

Bacteriophage T7 DNA primase (gene-4 protein, 66,000 daltons) enables T7 DNA polymerase to initiate the synthesis of DNA chains on single-stranded templates. An initial step in the process of chain initiation is the formation of an oligoribonucleotide primer by T7 primase. The enzyme, in the presence of natural SS DNA, Mg++ (or Mn++), ATP and CTP (or a mixture of all 4 rNTPs), catalyzes the synthesis of di-, tri-, and tetraribonucleotides all starting at the 5' terminus with pppA. In a subsequent step requiring both T7 DNA polymerase and primase, the short oligoribonucleotides (predominantly pppA-C-C-AOH) are extended by covalent addition of deoxyribonucleotides. With the aid of primase, T7 DNA polymerase can also utilize efficiently a variety of synthetic tri-, tetra-, or pentanucleotides as chain initiators. T7 primase apparently plays an active role in primer extension by stabilizing the short primer segments in a duplex state on the template DNA.