DNA-dependent ATPase activity associated with phage P22 gene 12 protein

Bacteriophage lambda: Early pioneer and still relevant

Molecular genetic research on bacteriophage lambda carried out during its golden age from the mid-1950s to mid-1980s was critically important in the attainment of our current understanding of the sophisticated and complex mechanisms by which the expression of genes is controlled, of DNA virus assembly and of the molecular nature of lysogeny. The development of molecular cloning techniques, ironically instigated largely by phage lambda researchers, allowed many phage workers to switch their efforts to other biological systems. Nonetheless, since that time the ongoing study of lambda and its relatives has continued to give important new insights. In this review we give some relevant early history and describe recent developments in understanding the molecular biology of lambda's life cycle.

Bacteriophage protein-protein interactions

Bacteriophages T7, λ, P22, and P2/P4 (from Escherichia coli), as well as ϕ29 (from Bacillus subtilis), are among the best-studied bacterial viruses. This chapter summarizes published protein interaction data of intraviral protein interactions, as well as known phage-host protein interactions of these phages retrieved from the literature. We also review the published results of comprehensive protein interaction analyses of Pneumococcus phages Dp-1 and Cp-1, as well as coliphages λ and T7. For example, the ≈55 proteins encoded by the T7 genome are connected by ≈43 interactions with another ≈15 between the phage and its host. The chapter compiles published interactions for the well-studied phages λ (33 intra-phage/22 phage-host), P22 (38/9), P2/P4 (14/3), and ϕ29 (20/2). We discuss whether different interaction patterns reflect different phage lifestyles or whether they may be artifacts of sampling. Phages that infect the same host can interact with different host target proteins, as exemplified by E. coli phage λ and T7. Despite decades of intensive investigation, only a fraction of these phage interactomes are known. Technical limitations and a lack of depth in many studies explain the gaps in our knowledge. Strategies to complete current interactome maps are described. Although limited space precludes detailed overviews of phage molecular biology, this compilation will allow future studies to put interaction data into the context of phage biology.

Bacteriophage replication modules

Bacteriophages (prokaryotic viruses) are favourite model systems to study DNA replication in prokaryotes, and provide examples for every theoretically possible replication mechanism. In addition, the elucidation of the intricate interplay of phage-encoded replication factors with 'host' factors has always advanced the understanding of DNA replication in general. Here we review bacteriophage replication based on the long-standing observation that in most known phage genomes the replication genes are arranged as modules. This allows us to discuss established model systems--f1/fd, phiX174, P2, P4, lambda, SPP1, N15, phi29, T7 and T4--along with those numerous phages that have been sequenced but not studied experimentally. The review of bacteriophage replication mechanisms and modules is accompanied by a compendium of replication origins and replication/recombination proteins (available as supplementary material online).

Prophages and bacterial genomics: what have we learned so far?

Bacterial genome nucleotide sequences are being completed at a rapid and increasing rate. Integrated virus genomes (prophages) are common in such genomes. Fifty-one of the 82 such genomes published to date carry prophages, and these contain 230 recognizable putative prophages. Prophages can constitute as much as 10-20% of a bacterium's genome and are major contributors to differences between individuals within species. Many of these prophages appear to be defective and are in a state of mutational decay. Prophages, including defective ones, can contribute important biological properties to their bacterial hosts. Therefore, if we are to comprehend bacterial genomes fully, it is essential that we are able to recognize accurately and understand their prophages from nucleotide sequence analysis. Analysis of the evolution of prophages can shed light on the evolution of both bacteriophages and their hosts. Comparison of the Rac prophages in the sequenced genomes of three Escherichia coli strains and the Pnm prophages in two Neisseria meningitidis strains suggests that some prophages can lie in residence for very long times, perhaps millions of years, and that recombination events have occurred between related prophages that reside at different locations in a bacterium's genome. In addition, many genes in defective prophages remain functional, so a significant portion of the temperate bacteriophage gene pool resides in prophages.

Sequence of the genome of Salmonella bacteriophage P22

The sequence of the nonredundant region of the Salmonella enterica serovar Typhimurium temperate, serotype-converting bacteriophage P22 has been completed. The genome is 41,724 bp with an overall moles percent GC content of 47.1%. Numerous examples of potential integration host factor and C1-binding sites were identified in the sequence. In addition, five potential rho-independent terminators were discovered. Sixty-five genes were identified and annotated. While many of these had been described previously, we have added several new ones, including the genes involved in serotype conversion and late control. Two of the serotype conversion gene products show considerable sequence relatedness to GtrA and -B from Shigella phages SfII, SfV, and SfX. We have cloned the serotype-converting cassette (gtrABC) and demonstrated that it results in Salmonella serovar Typhimurium LT2 cells which express antigen O1. Many of the putative proteins show sequence relatedness to proteins from a great variety of other phages, supporting the hypothesis that this phage has evolved through the recombinational exchange of genetic information with other viruses.

The complete nucleotide sequence and functional organization of Bacillus subtilis bacteriophage SPP1

The complete nucleotide sequence of the B. subtilis bacteriophage SPP1 is described. The genome is 44,007 bp in size and has a base composition of 43.7% dG + dC. Only 32.2 kb are essential for phage amplification under laboratory conditions. Transcription using only the 'heavy strand' is asymmetric. Eighty-one orfs organized in five early and four late operons were identified. Experiments have shown that 25 orfs are essential. Of the remaining orfs, functions could be predicted for the products of five of the orfs on the basis of comparison of the deduced amino acid sequence to known proteins. Intergenic regions include most of the 5 PE and the 4 PL promoters. Transcripts are polycistronic. Transcription from the PE promoters is mediated by host RP, whereas recognition of the PL promoters requires an additional unidentified phage-encoded product. Translation of mRNA transcribed from most of the orfs seems to be initiated independently, each from its own ribosomal binding and initiation site, although a few cases of coupled translation have been reported. The organization of SPP1 genes involved in the replication, DNA packaging and phage assembly proteins resembles the organization of genes of equivalent regions of different E. coli double-stranded DNA phages. Absence of aa sequence similarity between analogous proteins of different phages suggested that the conserved gene organization is representative of a primordial bacteriophage.

Analysis of cis and trans acting elements required for the initiation of DNA replication in the Bacillus subtilis bacteriophage SPP1

The development of SPP1 has been studied in several B. subtilis mutants conditionally defective in initiation of DNA replication. Initiation of SPP1 replication is independent of the host DnaA (replisome organizer), DnaB, DnaC and DnaI products, but requires the DnaG (DNA primase) and the DNA gyrase. Furthermore, SPP1 replication is independent of the DnaK (heat shock) protein. The phage-encoded products required for initiation of SPP1 replication have been genetically characterized. Analysis of the nucleotide sequence (3.292 kilobases) of the region where SPP1 initiation replication mutants map, revealed five open reading frames (orf). We have assigned genes 38, 39 and 40 to three of these orfs, which have the successive order gene 38-gene 39-orf39,1-gene 40-orf41. The direction of transcription of the reading frames, the lengths of the mRNAs as well as the transcription start point, upstream of gene 38 (PE2), were identified. Proteins of 29.9, 14.6 and 46.6 kDa were anticipated from translation of gene 38, gene 39 and gene 40, respectively. The purified G38P and G39P have estimated molecular masses of 31 and 15 kDa. G38P and G39P do not share significant identity with primary protein sequences currently available in protein databases, whereas G40P shares substantial homology with a family of DNA primase-associated DNA helicases. G38P binds specifically to two discrete SPP1 DNA restriction fragments (EcoRI-4 and EcoRI-3). The G38P binding site on EcoRI-4 was localized on a 393 bp DNA segment, which lies within the coding sequence of gene 38. The putative binding site on EcoRI-3 was inferred by DNA sequence homology, it maps in a non-coding segment. G39P, which does not bind to DNA, is able to form a complex with G38P. The organization of the SPP1 genes in the gene 38 to gene 40 interval resembles that one found in the replication origin regions of different Escherichia coli double-stranded DNA phages (lambda, phi 80 and P22). We propose that the conserved gene organization is representative of the replication origin region of a primordial phage.

Organization and evolution of bacterial and bacteriophage primase-helicase systems

Amino acid sequences of primases and associated helicases involved in the DNA replication of eubacteria and bacteriophages T7, T3, T4, P4, and P22 were compared by computer-assisted methods. There are two types of such systems, the first one represented by distinct helicase and primase proteins (e.g., DnaB and DnaG proteins of Escherichia coli), and the second one by single polypeptides comprising both activities (gp4 of bacteriophages T7 and T3, and alpha protein of bacteriophage P4). Pronounced sequence similarity was revealed between approximately 250 amino acid residue N-terminal domains of stand-alone primases and the primase-helicase proteins of T7(T3) and P4. All these domains contain, close to their N-termini, a conserved Zn-finger pattern that may be implicated in template DNA recognition by the primases. In addition, they encompass five other conserved motifs some of which may be involved in substrate (NTP) binding. Significant similarity was also observed between the primase-associated helicases (DnaB, gp12 and P22 and gp41 of T4) and the C-terminal domain of T7(T3) gp4. On the other hand the C-terminal domain of P-alpha of P4 is related to another group of DNA and RNA helicases. Tentative phylogenetic trees generated for the primases and the associated helicases showed no grouping of the phage proteins, with the exception of the primase domains of bacteriophages T4 and P4. This may indicate a common origin for one-component primase-helicase systems. Two scenarios for the evolution of primase-helicase systems are discussed.(ABSTRACT TRUNCATED AT 250 WORDS)

Dominant lethal mutations in the dnaB helicase gene of Salmonella typhimurium

A class of dominant lethal mutations in the dnaB (replicative helicase) gene of Salmonella typhimurium is described. The mutated genes, when present on multicopy plasmids, interfered with colony formation by Escherichia coli host strains with a functional chromosomal dnaB gene. The lethal phenotype was expressed specifically in supE (glutamine-inserting) host strains and not in Sup+ strains, because the mutant genes, by design, also possessed an amber mutation derived from a glutamine codon. Mutations located at 11 sites by deletion mapping and DNA sequence analysis varied in the temperature dependence and severity of their lethal effects. None of the mutations complemented a dnaB(Ts) host strain at high temperature (42 degrees C). Therefore, these nonfunctional DnaB proteins must engage some component(s) of the DNA replication machinery and inhibit replication. These mutations are predicted to confer limited, specific defects in either the catalytic activity of DnaB or the ability of DnaB to interact with one of its ligands such as DNA, nucleotide, or another replication protein. The variety of mutant sites and detailed phenotypes represented in this group of mutations may indicate the operation of more than one specific mechanism of lethality.

Sequence of the dnaB gene of Salmonella typhimurium

The dnaB gene of Escherichia coli encodes a helicase that operates at replication forks of the bacterium and certain of its bacteriophages to produce separated strands suitable for subsequent use by primase and DNA polymerase III. Here, we present the sequence of the dnaB gene of Salmonella typhimurium, a functionally interchangeable analog of the E. coli dnaB gene. The DnaB proteins of these two organisms, inferred from the DNA sequences, are identical in length and in 93% of amino acid residues. Extended portions of the DnaB proteins are also similar to two phage-encoded DNA replication proteins: the gene 4 helicase-primase of coliphage T7 and, as reported previously (H. Backhaus and J. B. Petri, Gene 32: 289-303, 1984), the gene 12 protein of Salmonella phage P22. In contrast, little similarity was found between DnaB and either the UvrD repair helicase or transcription termination factor Rho (an RNA-DNA helicase). These results identify S. typhimurium DnaB as a member of the DnaB family of proteins by structural, as well as functional, criteria and provide the basis for the eventual identification, by mutational studies, of residues in DnaB critical for its function.