The Burkholderia thailandensis Phages ΦE058 and ΦE067 Represent Distinct Prototypes of a New Subgroup of Temperate Burkholderia Myoviruses.

Burkholderia mallei and B. pseudomallei are highly pathogenic species which are closely related, but diverse regarding their prophage content. While temperate phages have not yet been isolated from B. mallei, several phages of B. pseudomallei, and its non-pathogenic relative B. thailandensis have been described. In this study we isolated two phages from B. pseudomallei and three phages from B. thailandensis and determined their morphology, host range, and relationship. All five phages belong to the family Myoviridae, but some of them revealed different host specificities. DNA-DNA hybridization experiments indicated that the phages belong to two groups. One group, composed of ΦE058 (44,121 bp) and ΦE067 (43,649 bp), represents a new subgroup of Burkholderia myoviruses that is not related to known phages. The genomes of ΦE058 and ΦE067 are similar but also show some striking differences. Repressor proteins differ clearly allowing the phages to form plaques on hosts containing the respective other phage. The tail fiber proteins exhibited some minor deviations in the C-terminal region, which may account for the ability of ΦE058, but not ΦE067, to lyse B. mallei, B. pseudomallei, and B. thailandensis. In addition, the integrases and attachment sites of the phages are not related. While ΦE058 integrates into the Burkholderia chromosome within an intergenic region, the ΦE067 prophage resides in the selC tRNA gene for selenocysteine. Experiments on the structure of phage DNA isolated from particles suggest that the ΦE058 and ΦE067 genomes have a circular conformation.

Genetic and functional properties of the self-transmissible Yersinia enterocolitica plasmid pYE854, which mobilizes the virulence plasmid pYV.

Yersinia strains frequently harbor plasmids, of which the virulence plasmid pYV, indigenous in pathogenic strains, has been thoroughly characterized during the last decades. Yet, it has been unknown whether the nonconjugative pYV can be transferred by helper plasmids naturally occurring in this genus. We have isolated the conjugative plasmids pYE854 (95.5 kb) and pYE966 (70 kb) from a nonpathogenic and a pathogenic Yersinia enterocolitica strain, respectively, and demonstrate that both plasmids are able to mobilize pYV. The complete sequence of pYE854 has been determined. The transfer proteins and oriT of the plasmid reveal similarities to the F factor. However, the pYE854 replicon does not belong to the IncF group and is more closely related to a plasmid of gram-positive bacteria. Plasmid pYE966 is very similar to pYE854 but lacks two DNA regions of the larger plasmid that are dispensable for conjugation.

Interplay between the temperate phages PY54 and N15, linear plasmid prophages with covalently closed ends.

The objective of this study was to determine whether the temperate Yersinia enterocolitica phage PY54 may interact with the related Escherichia coli phage N15 during both the lysogenic and the lytic cycle in the same cell. The PY54 and N15 prophages are linear plasmids which have been shown to be compatible and stably replicating in E. coli and Yersinia. In E. coli, the PY54 prophage does not restrict N15 propagation. In contrast, N15 reduces by use of its cor gene the susceptibility of Yersinia strains to PY54. Doubly lysogenic E. coli strains release PY54 virions, some of which apparently contain the N15 genome. Further experiments with replicative miniplasmid derivatives of PY54, N15, and the related Klebsiella oxytoca phage phiKO2 demonstrated that the phiKO2 and N15 plasmid prophages belong to the same incompatibility group.

Sequence analysis of the genome of the temperate Yersinia enterocolitica phage PY54.

The temperate Yersinia phage PY54 belongs to the unusual group of phages that replicate as linear plasmids with covalently closed ends. Besides Escherichia coli phage N15, PY54 is the only member of this group to be identified. We have determined the complete sequence (46,339 bp) of the PY54 genome. Bioinformatic analyses revealed 67 open reading frames (ORFs) with good coding potential located on both DNA strands. The comparison of the deduced PY54 gene products with known proteins encoded by other phages and bacteria along with functional studies have enabled us to assign the possible functions of 25 ORFs. In the left arm of the PY54 genome, we identified a number of ORFs that obviously code for head and tail proteins. Furthermore, this part of the phage genome contains genes probably involved in plasmid partitioning. Regarding the predicted gene functions and gene order, the PY54 and N15 left arms are similar. However, there are only weak DNA homologies and, in contrast to N15, the Yersinia phage harbours only a few ORFs related to genes found in lambdoid phages. The PY54 right arm comprises mainly regulatory genes as well as genes important for plasmid replication, DNA methylation, and host cell lysis. Out of 36 deduced products of the right arm, 13 revealed strongest database homologies to N15 proteins, of which the protelomerase and the Rep protein are exclusively homologous to their N15 counterparts. A number of PY54 genes essential for the lytic or lysogenic cycle were identified by functional analysis and characterization of phage mutants. In order to study transcription during the lytic and lysogenic stage, we analysed 34 PY54 ORFs by reverse transcriptase (RT)-PCR. The phage transcription patterns in lysogenic bacteria and at the late lytic stage of infection are nearly identical. The reasons for this finding are spontaneous release of phages during lysogeny and a high rate of phages that lysogenize their Yersinia host upon infection.

PY54, a linear plasmid prophage of Yersinia enterocolitica with covalently closed ends.

PY54 is a temperate phage isolated from Yersinia enterocolitica. Lysogenic Yersinia strains harbour the PY54 prophage as a plasmid (pY54). The plasmid has the same size (46 kb) as the PY54 genome isolated from phage particles. By electron microscopy, restriction analysis and DNA sequencing, it was demonstrated that the phage and the plasmid DNAs are linear, circularly permuted molecules. Unusually for phages of Gram-negative bacteria, the phage genome has 3'-protruding ends. The linear plasmid pY54 has covalently closed ends forming telomere-like hairpins. The equivalent DNA sequence of the phage genome is a 42 bp perfect palindrome. Downstream from the palindrome, an open reading frame (ORF) was identified that revealed strong DNA homology to the telN gene of Escherichia coli phage N15 encoding a protelomerase. Similar to PY54, the N15 prophage is a linear plasmid with telomeres. The N15 protelomerase has cleaving/joining activity generating the telomeres by processing a 56 bp palindrome (telomere resolution site tel RL). To study the activity of the PY54 protein, the telN-like gene was cloned and expressed in E. coli. A 77 kDa protein was obtained and partially purified. The protein was found to process recombinant plasmids containing the 42 bp palindrome. Telomere resolution of plasmids under in vivo conditions was also investigated in Yersinia infected with PY54. Processing required a plasmid containing the palindrome as well as adjacent DNA sequences from the phage including an additional inverted repeat. Regions on the phage genome important for plasmid maintenance were defined by the construction of linear and circular miniplasmid derivatives of pY54, of which the smallest miniplasmid comprises a 4.5 kb DNA fragment of the plasmid prophage.