Bacteriophages are the most abundant organisms in the biosphere and play major roles in the ecological balance of microbial life. The genomic sequences of ten newly isolated mycobacteriophages suggest that the bacteriophage population as a whole is amazingly diverse and may represent the largest unexplored reservoir of sequence information in the biosphere. Genomic comparison of these mycobacteriophages contributes to our understanding of the mechanisms of viral evolution and provides compelling evidence for the role of illegitimate recombination in horizontal genetic exchange. The promiscuity of these recombination events results in the inclusion of many unexpected genes including those implicated in mycobacterial latency, the cellular and immune responses to mycobacterial infections, and autoimmune diseases such as human lupus. While the role of phages as vehicles of toxin genes is well established, these observations suggest a much broader involvement of phages in bacterial virulence and the host response to bacterial infections.
Bacteriophages are the most abundant forms of life in the biosphere and carry genomes characterized by high genetic diversity and mosaic architectures. The complete sequences of 30 mycobacteriophage genomes show them collectively to encode 101 tRNAs, three tmRNAs, and 3,357 proteins belonging to 1,536 “phamilies” of related sequences, and a statistical analysis predicts that these represent approximately 50% of the total number of phamilies in the mycobacteriophage population. These phamilies contain 2.19 proteins on average; more than half (774) of them contain just a single protein sequence. Only six phamilies have representatives in more than half of the 30 genomes, and only three—encoding tape-measure proteins, lysins, and minor tail proteins—are present in all 30 phages, although these phamilies are themselves highly modular, such that no single amino acid sequence element is present in all 30 mycobacteriophage genomes. Of the 1,536 phamilies, only 230 (15%) have amino acid sequence similarity to previously reported proteins, reflecting the enormous genetic diversity of the entire phage population. The abundance and diversity of phages, the simplicity of phage isolation, and the relatively small size of phage genomes support bacteriophage isolation and comparative genomic analysis as a highly suitable platform for discovery-based education.
Cyanobacteriophage Syn9 is a large, contractile-tailed bacteriophage infecting the widespread, numerically dominant marine cyanobacteria of the genera Prochlorococcus and Synechococcus. Its 177,300 bp genome sequence encodes 226 putative proteins and six tRNAs. Experimental and computational analyses identified genes likely involved in virion formation, nucleotide synthesis, and DNA replication and repair. Syn9 shows significant mosaicism when compared with related cyanophages S-PM2, P-SSM2 and P-SSM4, although shared genes show strong purifying selection and evidence for large population sizes relative to other phages. Related to coliphage T4 - which shares 19% of Syn9's genes - Syn9 shows evidence for different patterns of DNA replication and uses homologous proteins to assemble capsids with a different overall structure that shares topology with phage SPO1 and herpes virus. Noteworthy bacteria-related sequences in the Syn9 genome potentially encode subunits of the photosynthetic reaction centre, electron transport proteins, three pentose pathway enzymes and two tryptophan halogenases. These genes suggest that Syn9 is well adapted to the physiology of its photosynthetic hosts and may affect the evolution of these sequences within marine cyanobacteria.
The Generalized TransducingSalmonellaBacteriophage ES18: Complete Genome Sequence and DNA Packaging Strategy
The generalized transducing double-stranded DNA bacteriophage ES18 has an icosahedral head and a long noncontractile tail, and it infects both rough and smooth Salmonella enterica strains. We report here the complete 46,900-bp genome nucleotide sequence and provide an analysis of the sequence. Its 79 genes and their organization clearly show that ES18 is a member of the lambda-like (lambdoid) phage group; however, it contains a novel set of genes that program assembly of the virion head. Most of its integration-excision, immunity, Nin region, and lysis genes are nearly identical to those of the short-tailed Salmonella phage P22, while other early genes are nearly identical to Escherichia coli phages and HK97, S. enterica phage ST64T, or a Shigella flexneri prophage. Some of the ES18 late genes are novel, while others are most closely related to phages HK97, lambda, or N15. Thus, the ES18 genome is mosaically related to other lambdoid phages, as is typical for all group members. Analysis of virion DNA showed that it is circularly permuted and about 10% terminally redundant and that initiation of DNA packaging series occurs across an approximately 1-kbp region rather than at a precise location on the genome. This supports a model in which ES18 terminase can move substantial distances along the DNA between recognition and cleavage of DNA destined to be packaged. Bioinformatic analysis of large terminase subunits shows that the different functional classes of phage-encoded terminases can usually be predicted from their amino acid sequence.Generalized transducing bacteriophages are valuable members of the arsenal of tools for the genetic study of bacteria. ES18 is a temperate, generalized transducing double-stranded DNA (dsDNA) phage that naturally infects Salmonella enterica serovar Typhimurium (48), as well as some serovar Enteriditis, Dublin, Pullorum, Gallinarum, and Paratyphi B strains (52,76). In addition, it can infect Escherichia coli if it displays the Salmonella surface receptor (47). ES18, which has also been called typing phage A18, was originally isolated in about 1953 after its release from Salmonella sp. strain BA19, in which it apparently resided as a prophage (8,75). It has an estimated genome size of about 46,000 bp (74). It is of technical interest because, unlike the well-characterized Salmonella transducing phage P22, it can infect rough strains that do not produce full-length O-antigen, for which no other transducing phages have been studied (48). Yamamoto (98) showed that ES18 is able to recombine to form viable hybrid phages with both the short-tailed phage P22 and the long-tailed phage Fels-1, both of which are now considered to be lambdoid phages (34). Thus, ES18 was also thought to be a lambdoid phage. This was tentatively confirmed in studies by Schmieger and colleagues (74), which found that the ES18 prophage repressor and lysis regions are very similar to those of the short-tailed phage P22 in both sequence and genome location. It has been reported (without publication of the data) that ...
We report the genome sequence of Bacillus subtilis phage SPO1. The unique genome sequence is 132,562 bp, and DNA packaged in the virion (the chromosome) has a 13,185 bp terminal redundancy, giving a total of 145,747 bp. We predict 204 protein coding genes and five tRNA genes, and we correlate these findings with the extensive body of investigations of SPO1, including studies of the functions of the 61 previously defined genes and studies of the virion structure. 69% of the encoded proteins show no similarity to any previously known protein.We identify 107 probable transcription promoters; most are members of the promoter classes identified in earlier studies, but we also see a new class that has the same sequence as the host sigma K promoters. We find three genes encoding potential new transcription factors, one of which is a distant homologue of the host sigma factor K. We also identify 75 probable transcription terminator structures. Promoters and terminators are generally located between genes and together with earlier data give what appears to be a rather complete picture of how phage transcription is regulated.There are complete genome sequences available for five additional phages of Gram-positive hosts that are similar to SPO1 in genome size and in composition and organization of genes. Comparative analysis of SPO1 in the context of these other phages yields insights about both SPO1 and the other phages that would not be apparent from the analysis of any one phage alone. These include assigning identities and probable functions for several specific genes, and inferring evolutionary events in the phages' histories. The comparative analysis also allows us to put SPO1 into a phylogenetic context. We see a pattern similar to what has been noted in phage T4 and its relatives, in which there is minimal successful horizontal exchange of genes among a "core" set of genes that includes most of the virion structural genes and some genes of DNA metabolism, but there is extensive horizontal transfer of genes over the remainder of the genome. There is a correlation between genes in rapid evolutionary flux through these genomes and genes that are small.
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