Tomoyuki Shinomiya

The R‐type pyocin of Pseudomonas aeruginosa is related to P2 phage, and the F‐type is related to lambda phage

Pseudomonas aeruginosa produces three types of bacteriocins: R‐, F‐ and S‐type pyocins. The S‐type pyocin is a colicin‐like protein, whereas the R‐type pyocin resembles a contractile but non‐flexible tail structure of bacteriophage, and the F‐type a flexible but non‐contractile one. As genetically related phages exist for each type, these pyocins have been thought to be variations of defective phage. In the present study, the nucleotide sequence of R2 pyocin genes, along with those for F2 pyocin, which are located downstream of the R2 gene cluster on the chromosome of P. aeruginosa PAO1, was analysed in order to elucidate the relationship between the pyocins and bacteriophages. The results clearly demonstrated that the R‐type pyocin is derived from a common ancestral origin with P2 phage and the F‐type from λ phage. This notion was supported by identification of a lysis gene cassette similar to those for bacteriophages. The gene organization of the R2 and F2 pyocin gene cluster, however, suggested that both pyocins are not simple defective phages, but are phage tails that have been evolutionarily specialized as bacteriocins. A systematic polymerase chain reaction (PCR) analysis of P. aeruginosa strains that produce various subtypes of R and F pyocins revealed that the genes for every subtype are located between trpE and trpG in the same or very similar gene organization as for R2 and F2 pyocins, but with alterations in genes that determine the receptor specificity.

SPECIFICATION OF REGIONS OF DNA REPLICATION INITIATION DURING EMBRYOGENESIS IN THE 65-KILOBASE DNAPOLALPHA -DE2F LOCUS OF DROSOPHILA MELANOGASTER

ABSTRACT In the early stage of Drosophila embryogenesis, DNA replication initiates at unspecified sites in the chromosome. In contrast, DNA replication initiates in specified regions in cultured cells. We investigated when and where the initiation regions are specified during embryogenesis and compared them with those observed in cultured cells by two-dimensional gel methods. In the DNA polymerase α gene (DNApolα) locus, where an initiation region,oriDα, had been identified in cultured Kc cells, repression of origin activity in the coding region was detected after formation of cellular blastoderms, and the range of the initiation region had become confined by 5 h after fertilization. During this work we identified other initiation regions between oriDα and the Drosophila E2F gene (dE2F) downstream of DNApolα. At least four initiation regions showing replication bubbles were identified in the 65-kbDNApolα-dE2F locus in 5-h embryos, but only two were observed in Kc cells. These results suggest that the specification levels of origin usage in 5-h embryos are in the intermediate state compared to those in more differentiated cells. Further, we found a spatial correlation between the active promoter regions fordE2F and the active initiation zones of replication. In 5-h embryos, two known transcripts differing in their first exons were expressed, and two regions close to the respective promoter regions for both transcripts functioned as replication origins. In Kc cells, only one transcript was expressed and functional replication origins were observed only in the region including the promoter region for this transcript.

Mapping an initiation region of DNA replication at a single-copy chromosomal locus in Drosophila melanogaster cells by two-dimensional gel methods and PCR-mediated nascent-strand analysis: multiple replication origins in a broad zone.

We have mapped an initiation region of DNA replication at a single-copy chromosomal locus in exponentially proliferating Drosophila tissue culture cells, using two-dimensional (2D) gel replicon mapping methods and PCR-mediated analysis of nascent strands. The initiation region was first localized downstream of the DNA polymerase alpha gene by determining direction of replication forks with the neutral/alkaline 2D gel method. Distribution of replication origins in the initiation region was further analyzed by using two types of 2D gel methods (neutral/neutral and neutral/alkaline) and PCR-mediated nascent-strand analysis. Results obtained by three independent methods were essentially consistent with each other and indicated that multiple replication origins are distributed in a broad zone of approximately 10 kb. The nucleotide sequence of an approximately 20-kb region that encompasses the initiation region was determined and searched for sequence elements potentially related to function of replication origins.

Genetic determinant of pyocin R2 in Pseudomonas aeruginosa PAO. II. Physical characterization of pyocin R2 genes using R-prime plasmids constructed from R68.45.

SummaryThe chromosome segment which contains the genes responsible for production of pyocin R2 in P. aeruginosa PAO was defined physically using R-prime plasmids constructed in vivo from R68.45. The previous conclusion from genetic mapping that the cluster of pyocin R2 genes is located in between trpC and trpE genes was confirmed by deletion mapping of various R prime plasmids bearing the trpC gene. The pyocin R2 gene cluster was further localized on two contiguous HinDIII fragments of 16 kb and 8.0 kb. PML14 strain, in which R-type pyocin genes were completely deleted, had only one 11 kb HindIII fragment instead. Heteroduplexes between this 11 kb fragment with the two HindIII fragments of PAO revealed that the cluster of pyocin R2 genes was an insertion 13 kb long.

Genetic determinant of pyocin R2 in Pseudomonas aeruginosa PAO

SummaryThirty-seven mutants defective in pyocin R2 production in the P. aeruginosa PAO strain were subjected to fine mapping of pyocin R2 genes by transduction with phage F116L. Sixteen complementation groups (designated prtA through prtP) involved in pyocin R2 production were tentatively identified by complementation tests using phage F116L. Their linkages to trpC and trpE markers and fine mapping by three point crosses demonstrated that most of the mutations (prtA through prtN) were located in between trpC and trpE, and that the prtP mutation was localized outside this major prt cluster but in the proximity of the rifA and strA region.