ORCID Profile
0000-0001-7435-4897
Current Organisations
Universidade Nova de Lisboa
,
Institut für angewandte Systemtechnik Bremen GmbH
,
University of Galway
,
University of Delaware
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Publisher: Microbiology Society
Date: 12-2004
Abstract: Vibrio cholerae is the aetiological agent of the deadly diarrhoeal disease cholera. In this study the 7.5 kb Vibrio seventh pandemic island-II (VSP-II) that is unique to V. cholerae El Tor and O139 serogroups was analysed and it was found to be part of a novel 26.9 kb genomic island (GEI) encompassing VC0490-VC0516. The low-GC-content VSP-II encompassed 24 predicted ORFs, including DNA repair and methyl-accepting chemotaxis proteins, a group of hypothetical proteins and a bacteriophage-like integrase adjacent to a tRNA gene. Interestingly, V. cholerae ORFs VC0493-VC0498, VC0504-VC0510 and VC0516, which encodes an integrase, were homologous to Vibrio vulnificus strain YJ016 ORFs VV0510-VV0516, VV0518-VV0525 and VV0560, which also encodes an integrase, respectively. Some ORFs showed amino acid identities greater than 90 % between the two species in these regions. In V. vulnificus strain YJ016, a 43.4 kb low-GC-content (43 %) GEI encompassing ORFs VV0509-VV0560 was identified and named V. vulnificus island-I (VVI-I). The 52 ORFs of VVI-I included a phosphotransferase system gene cluster, genes required for sugar metabolism and transposase genes. There was synteny and homology between the 5' region of V. cholerae VSP-II and the 5' region of V. vulnificus VVI-I however, VVI-I contained an additional 31.5 kb of DNA between VV0526 and VV0560 in strain YJ016. A second V. vulnificus strain, CMCP6, did not contain the 43.4 kb VVI-I in this strain two ORFs were found between the 5' and 3' flanking genes VV10636 and VV10632, showing 100 % identity to VV0508 and VV0561, respectively, which flank VVI-I.
Publisher: American Society for Microbiology
Date: 04-2009
DOI: 10.1128/AEM.02052-08
Abstract: Pseudomonas fluorescens is of agricultural and economic importance as a biological control agent largely because of its plant association and production of secondary metabolites, in particular 2,4-diacetylphloroglucinol (2,4-DAPG). This polyketide, which is encoded by the eight-gene phl cluster, has antimicrobial effects on phytopathogens, promotes amino acid exudation from plant roots, and induces systemic resistance in plants. Despite its importance, 2,4-DAPG production is limited to a subset of P. fluorescens strains. Determination of the evolution of the phl cluster and understanding the selective pressures promoting its retention or loss in lineages of P. fluorescens will help in the development of P. fluorescens as a viable and effective inoculant for application in agriculture. In this study, genomic and sequence-based approaches were integrated to reconstruct the phylogeny of P. fluorescens and the phl cluster. It was determined that 2,4-DAPG production is an ancestral trait in the species P. fluorescens but that most lineages have lost this capacity through evolution. Furthermore, intragenomic recombination has relocated the phl cluster within the P. fluorescens genome at least three times, but the integrity of the cluster has always been maintained. The possible evolutionary and functional implications for retention of the phl cluster and 2,4-DAPG production in some lineages of P. fluorescens are discussed.
Publisher: American Society for Microbiology
Date: 12-2004
DOI: 10.1128/JCM.42.12.5783-5792.2004
Abstract: Pseudomonas aeruginosa is a gram-negative rod that is ubiquitous in nature. P. aeruginosa is also the quintessential opportunistic pathogen, causing a wide variety of infections in compromised hosts. In cystic fibrosis patients, P. aeruginosa is the leading cause of death. In this study, the evolutionary genetic relationships among 17 P. aeruginosa isolates were examined by comparative sequence analysis of the housekeeping gene encoding malate dehydrogenase and the chaperone groEL . The P. aeruginosa isolates examined included the sequenced strain PAO1, 11 strains recovered from cystic fibrosis patients in Ireland, 4 environmental isolates recovered from a hospital environment, and 1 isolate recovered from a plant rhizosphere. Phylogenetically, clinical and environmental isolates clustered together with one another on the mdh gene tree. At the groEL locus, among the 17 isolates examined, only two polymorphic sites were observed, highlighting the close genetic relationship between isolates from these different environments. Phenotypic analysis of 12 traits among our isolates, however, found that only clinical isolates produced phenazines and elastase. Furthermore, molecular analysis of the distribution of 15 regions associated with virulence showed that two of the environmental isolates examined lacked the majority of regions. Among the clinical isolates examined, the 15 virulence regions were variably present. The distribution of two prophages (Bacto1, Pf1) was also determined, with most isolates encoding both these regions. Of the four genomic islands (the flagellum island and PAGI - 1, -2, and -3) examined, only two isolates contained the flagellum island, and PAGI - 1, -2, and -3 were absent from all isolates tested. Our data demonstrate the significant role horizontal gene transfer and recombination, together with gene loss, play in the evolution of this important human pathogen.