Metagenomic analysis of lysogeny in Tampa Bay: implications for prophage gene expression

Phage integrase genes often play a role in the establishment of lysogeny in temperate phage by catalyzing the integration of the phage into one of the host's replicons. To investigate temperate phage gene expression, an induced viral metagenome from Tampa Bay was sequenced by 454/Pyrosequencing. The sequencing yielded 294,068 reads with 6.6% identifiable. One hundred-three sequences had significant similarity to integrases by BLASTX analysis (e < or =0.001). Four sequences with strongest amino-acid level similarity to integrases were selected and real-time PCR primers and probes were designed. Initial testing with microbial fraction DNA from Tampa Bay revealed 1.9 x 10(7), and 1300 gene copies of Vibrio-like integrase and Oceanicola-like integrase L(-1) respectively. The other two integrases were not detected. The integrase assay was then tested on microbial fraction RNA extracted from 200 ml of Tampa Bay water sampled biweekly over a 12 month time series. Vibrio-like integrase gene expression was detected in three samples, with estimated copy numbers of 2.4-1280 L(-1). Clostridium-like integrase gene expression was detected in 6 samples, with estimated copy numbers of 37 to 265 L(-1). In all cases, detection of integrase gene expression corresponded to the occurrence of lysogeny as detected by prophage induction. Investigation of the environmental distribution of the two expressed integrases in the Global Ocean Survey Database found the Vibrio-like integrase was present in genome equivalents of 3.14% of microbial libraries and all four viral metagenomes. There were two similar genes in the library from British Columbia and one similar gene was detected in both the Gulf of Mexico and Sargasso Sea libraries. In contrast, in the Arctic library eleven similar genes were observed. The Clostridium-like integrase was less prevalent, being found in 0.58% of the microbial and none of the viral libraries. These results underscore the value of metagenomic data in discovering signature genes that play important roles in the environment through their expression, as demonstrated by integrases in lysogeny.     

Genetics of bacteriophage phi 80--a review

The genetic maps of bacteriophage lambda and lambdoid phage phi 80 are compared. The gene organization of phi 80 is very similar to that of lambda, as shown by isolation and characterization of many am, ts and c (clear) mutants of the phage. In general, the essential genes located in the same position on the genetic map of the phages lambda and phi 80 fulfill the same functions. These include the gene clusters coding for the head and tail proteins, genes for DNA synthesis, and the genes controlling lysogeny and late gene expression. The specific regulatory features of phi 80 in relation to the N function of lambda are discussed, but they require further clarification. The two phages differ in immunity specificity, host range, conversion property and temperature sensitivity.     

Dual control of lysogeny by bacteriophage P22: An antirepressor locus and its controlling elements

Two distantly linked clusters of genes on the Salmonella typhimurium phage P22 chromosome are involved in the control of lysogeny and superinfection immunity. One cluster consists of genes c1, c2, and c3, which are primarily responsible for the establishment and maintenance of lysogeny. It has been proposed that the second cluster consists of three loci which are responsible for the synthesis and control of an antirepressor substance which overcomes the repression mediated by the c2 gene product. This paper reports the isolation of mutants in a locus designated “ant” having characteristics expected of antirepressor mutants. Evidence is presented that the other loci in this second immunity region, mnt and virA, control the expression of the ant gene as represser and promoter/operator, respectively. The interactions of these three loci with each other and with the other immunity region are discussed.     

Gene regulation at-a-distance in E. coli: new insights

The number of E. coli genes/operons regulated from sites distant from the gene, though limited, steadily increases. The regulation of the ula genes, in charge of L-ascorbate utilization, as well as the negative autoregulation of the non-related lambdaCI and 186CI repressors, for efficient switching of the corresponding phages from lysogeny to lysis, are recent examples. The interaction between the two GalR dimers, separated by 114 bp, undetectable in vitro, has been genetically mapped. lac repressor-operator loops might insulate a gene and its expression from the genomic environment. The genes in charge of nitrogen assimilation sequentially react to ammonia deprivation, via an increasing intracellular NRI concentration. Other sigma54-dependent genes are activated in response to various stimuli.     

N15: the linear phage-plasmid

The lambdoid phage N15 of Escherichia coli is very unusual among temperate phages in that its prophage is not integrated into chromosome but is a linear plasmid molecule with covalently closed ends. Upon infection the phage DNA circularises via cohesive ends, then phage-encoded enzyme, protelomerase, cuts at an inverted repeat site and forms hairpin ends (telomeres) of the linear plasmid prophage. Replication of the N15 prophage is initiated at an internally located ori site and proceeds bidirectionally resulting in formation of duplicated telomeres. Then the N15 protelomerase cuts duplicated telomeres generating two linear plasmid molecules with hairpin telomeres. Stable inheritance of the plasmid prophage is ensured by partitioning operon similar to the F factor sop operon. Unlike F sop, the N15 centromere consists of four inverted repeats dispersed in the genome. The multiplicity and dispersion of centromeres are required for efficient partitioning of a linear plasmid. The centromeres are located in N15 genome regions involved in phage replication and control of lysogeny, and binding of partition proteins at these sites regulates these processes. Two N15-related lambdoid Siphoviridae phages, φKO2 in Klebsiella oxytoca and pY54 in Yersinia enterocolitica, also lysogenize their hosts as linear plasmids, as well as Myoviridae marine phages VP882 and VP58.5 in Vibrio parahaemolyticus and ΦHAP-1 in Halomonas aquamarina. The genomes of all these phages contain similar protelomerase genes, lysogeny modules and replication genes, as well as plasmid-partitioning genes, suggesting that these phages may belong to a group diverged from a common ancestor.     

Sop proteins can cause transcriptional silencing of genes located close to the centromere sites of linear plasmid N15

Stable inheritance of bacterial chromosomes and low copy number plasmids is ensured by accurate partitioning of replicated molecules between the daughter cells at division. Partitioning of the prophage of the temperate bacteriophage N15, which exists as a linear plasmid molecule with covalently closed ends, depends on the sop locus, comprising genes sopA and sopB, as well as four centromere sites in different regions of the N15 genome essential for replication and the control of lysogeny. We found that binding of SopB to the centromere could silence centromere-proximal promoters, presumably due to subsequent polymerization of SopB along the DNA. Close to the IR4 centromere site we identified a promoter, P59, which was able to drive the expression of phage late genes encoding structural proteins of virion. We found that, following binding to IR4, the N15 Sop proteins could induce repression of this promoter. The repression depended on SopB and was enhanced in the presence of SopA. Sop-dependent silencing of centromere-proximal promoters may control gene expression in phage N15, particularly preventing undesired expression of late genes in the N15 prophage. Thus, the phage N15 sop system not only ensures plasmid partitioning but is also involved in the genetic network controlling prophage replication and the maintenance of lysogeny.     

Control of bacteriophage lambda CII activity by bacteriophage and host functions

We have studied the regulation of the lambda cII gene in vivo using cloned lambda fragments. Lambda N protein stimulated cII expression. Surprisingly, although very high cII protein levels were detected by gel electrophoresis, little cII protein activity, measured as stimulation of the lambda pI and pE promoters, was observed. The half-life of cII protein depended critically on its initial level. At low concentrations its half-life was as short as 1.5 min, whereas at high cII protein levels, it could be as long as 22 min. The Escherichia coli mutant ER437 directs lambda towards lysogeny; cII protein was more stable in this strain than in the wild type. On the other hand, although cyclic AMP is required for efficient lysogeny, it did not appear to influence the synthesis, stability, or activity of cII protein.     

Bacteriophage P22 tail protein gene expression.

We have found that mutations which block bacteriophage P22 head assembly at or before the DNA packaging stage (1-, 2-, 3-, 5-, and 8-) cause up to a 20-fold increase in the amount of tail (gene 9) protein made during infection. This correlation seems strong enough to warrant consideration of a control mechanism in which the failure to package DNA per se causes a large increase in the synthesis of tail protein. Our results indicate that one of the repressors required for maintenance of lysogeny, the mnt gene product, may be partially responsible for this phenomenon.     

Mycobacteriophage Fruitloop gp52 inactivates Wag31 (DivIVA) to prevent heterotypic superinfection

Bacteriophages engage in complex dynamic interactions with their bacterial hosts and with each other. Bacteria have numerous mechanisms to resist phage infection, and phages must co‐evolve by overcoming bacterial resistance or by choosing an alternative host. Phages also compete with each other, both during lysogeny by prophage‐mediated defense against viral attack and by superinfection exclusion during lytic replication. Phages are enormously diverse genetically and are replete with small genes of unknown function, many of which are not required for lytic growth, but which may modulate these bacteria–phage and phage–phage dynamics. Using cellular toxicity of phage gene overexpression as an assay, we identified the 93‐residue protein gp52 encoded by Cluster F mycobacteriophage Fruitloop. The toxicity of Fruitloop gp52 overexpression results from interaction with and inactivation of Wag31 (DivIVA), an essential Mycobacterium smegmatis protein organizing cell wall biosynthesis at the growing cellular poles. Fruitloop gene 52 is expressed early in lytic growth and is not required for normal Fruitloop lytic replication but interferes with Subcluster B2 phages such as Hedgerow and Rosebush. We conclude that Hedgerow and Rosebush are Wag31‐dependent phages and that Fruitloop gp52 confers heterotypic superinfection exclusion by inactivating Wag31.     

Diversity,evolution and life strategies of CbK-like phages

Caulobacter phage CbK has been extensively studied as a model system in virology and bacteriology. Lysogeny-related genes have been found in each CbK-like isolate, suggesting a life strategy of both lytic and lysogenic cycles. However, whether CbK-related phages can enter lysogeny is still undetermined. This study identified new CbK-like sequences and expanded the collection of CbK-related phages. A common ancestry with a temperate lifestyle was predicted for the group, however, which subsequently evolved into two clades of different genome sizes and host associations. Through the examination of phage recombinase genes, alignment of attachment sites on the phage and bacterial genomes (attP–attB pairing), and the experimental validation, different lifestyles were found among the different members. A majority of clade II members retain a lysogenic lifestyle, whereas all clade I members have evolved into an obligate lytic lifestyle via a loss of the gene encoding Cre-like recombinase and the coupled attP fragment. We postulated that the loss of lysogeny may be a by-product of the increase in phage genome size, and vice versa. Clade I is likely to overcome the costs through maintaining more auxiliary metabolic genes (AMGs), particularly for those involved in protein metabolism, to strengthen host takeover and further benefit virion production.