Your search keyword '"Bacteria, Pathogenic -- Natural history"' showing total 4 results

1. The hunt for microbial 'Trojan horses': should we beware of tiny marine life bearing pathogens?

Author

Carter, Andrea

Subjects

Woods Hole Oceanographic Institution -- Officials and employees, Bacteria, Pathogenic -- Natural history, Protista -- Properties -- Food and nutrition, Host-bacteria relationships -- Research, Bacteria -- Motility, Environmental issues, Earth sciences, Practice, Research, Properties, Officials and employees, Natural history, Food and nutrition

Abstract

In summer, Wood Neck Beach in Woods Hole, Mass., teems with tourists, but only a few seagulls kept Matt First company as he walked through the brown-gold marsh grass last [...]

Published

2009

2. Oxygen-limiting conditions enrich for fimbriate cells of uropathogenic Proteus mirabilis and Escherichia coli

Author

Lane, M. Chelsea, Li, Xin, Pearson, Melanie M., Simms, Amy N., and Moblev, Harry L.T.

Subjects

Enterobacter -- Natural history, Enterobacter -- Properties, Enterobacteriaceae -- Natural history, Enterobacteriaceae -- Properties, Bacteria, Pathogenic -- Properties, Bacteria, Pathogenic -- Natural history, Population regulation (Biology) -- Evaluation, Biological sciences

Abstract

MR/P fimbriae of uropathogenic Proteus mirabilis undergo invertible element-mediated phase variation whereby an individual bacterium switches between expressing fimbriae (phase ON) and not expressing fimbriae (phase OFF). Under different conditions, the percentage of fimbriate bacteria within a population varies and could be dictated by either selection (growth advantage of one phase) or signaling (preferentially converting one phase to the other in response to external signals). Expression of MR/P fimbriae increases in a cell-density dependent manner in vitro and in vivo. However, rather than the increased cell density itself, this increase in fimbrial expression is due to an enrichment of fimbriate bacteria under oxygen limitation resulting from increased cell density. Our data also indicate that the persistence of MR/P fimbriate bacteria under oxygen-limiting conditions is a result of both selection (of MR/P fimbrial phase variants) and signaling (via modulation of expression of the MrpI recombinase). Furthermore, the mrpJ transcriptional regulator encoded within the mrp operon contributes to phase switching. Type 1 fimbriae of Escherichia coli, which are likewise subject to phase variation via an invertible element, also increase in expression during reduced oxygenation. These findings provide evidence to support a mechanism for persistence of fimbriate bacteria under oxygen limitation, which is relevant to disease progression within the oxygen-restricted urinary tract.

Published

2009

3. Ancient, recurrent phage attacks and recombination shaped dynamic sequence-variable mosaics at the root of phytoplasma genome evolution

Author

Wei, Wei, Davis, Robert E., Jomantiene, Rasa, and Zhao, Yan

Subjects

Host-bacteria relationships -- Genetic aspects, Bacteria, Pathogenic -- Genetic aspects, Bacteria, Pathogenic -- Natural history, Bacteria, Pathogenic -- Physiological aspects, Genomes -- Natural history, Evolution -- Research, Phylogeny -- Research, Science and technology

Abstract

Mobile genetic elements have impacted biological evolution across all studied organisms, but evidence for a role in evolutionary emergence of an entire phylogenetic clade has not been forthcoming. We suggest that mobile element predation played a formative role in emergence of the phytoplasma clade. Phytoplasmas are cell wall-less bacteria that cause numerous diseases in plants. Phylogenetic analyses indicate that these transkingdom parasites descended from Gram-positive walled bacteria, but events giving rise to the first phytoplasma have remained unknown. Previously we discovered a unique feature of phytoplasmal genome architecture, genes clustered in sequence-variable mosaics (SVMs), and suggested that such structures formed through recurrent, targeted attacks by mobile elements. In the present study, we discovered that cryptic prophage remnants, originating from phages in the order Caudovirales, formed SVMs and comprised exceptionally large percentages of the chromosomes of 'Candidatus Phytoplasma asteris'-related strains OYM and AYWB, occupying nearly all major nonsyntenic sections, and accounting for most of the size difference between the two genomes. The clustered phage remnants formed genomic islands exhibiting distinct DNA physical signatures, such as dinucleotide relative abundance and codon position GC values. Phytoplasma strain-specific genes identified as phage morons were located in hypervariable regions within individual SVMs, indicating that prophage remnants played important roles in generating phytoplasma genetic diversity. Because no SVM-like structures could be identified in genomes of ancestral relatives including Acholeplasma spp., we hypothesize that ancient phage attacks leading to SVM formation occurred after divergence of phytoplasmas from acholeplasmas, triggering evolution of the phytoplasma clade. host-restricted bacteria | mobile gene cassette | pathogenicity island | phytopathogenic bacteria | clade emergence

Published

2008

4. Deep-sea vent [epsilon]-proteobacterial genomes provide insights into emergence of pathogens

Author

Nakagawa, Satoshi, Takaki, Yoshihiro, Shimamura, Shigeru, Reysenbach, Anna-Louise, Takai, Ken, and Horikoshi, Koki

Subjects

Abyssal zone -- Evaluation, Hydrothermal vent ecology -- Evaluation, Marine bacteria -- Genetic aspects, Marine bacteria -- Health aspects, Marine bacteria -- Natural history, Bacteria, Pathogenic -- Genetic aspects, Bacteria, Pathogenic -- Natural history, Host-bacteria relationships -- Evaluation, Bacterial infections -- Evaluation, Science and technology

Abstract

Deep-sea vents are the light-independent, highly productive ecosystems driven primarily by chemolithoautotrophic microorganisms, in particular by [epsilon]-Proteobacteria phylogenetically related to important pathogens. We analyzed genomes of two deep-sea vent [epsilon]-Proteobacteria strains, Sulfurovum sp. NBC37-1 and Nitratiruptor sp. SB155-2, which provide insights not only into their unusual niche on the seafloor, but also into the origins of virulence in their pathogenic relatives, Helicobacter and Campylobacter species. The deep-sea vent [epsilon]-proteobacterial genomes encode for multiple systems for respiration, sensing and responding to environment, and detoxifying heavy metals, reflecting their adaptation to the deep-sea vent environment. Although they are nonpathogenic, both deep-sea vent [epsilon]-Proteobacteria share many virulence genes with pathogenic [epsilon]-Proteobacteria, including genes for virulence factor MviN, hemolysin, invasion antigen CiaB, and the N-linked glycosylation gene cluster. In addition, some virulence determinants (such as the [H.sub.2]-uptake hydrogenase) and genomic plasticity of the pathogenic descendants appear to have roots in deep-sea vent [epsilon]-Proteobacteria. These provide ecological advantages for hydrothermal vent [epsilon]-Proteobacteria who thrive in their deep-sea habitat and are essential for both the efficient colonization and persistent infections of their pathogenic relatives. Our comparative genomic analysis suggests that there are previously unrecognized evolutionary links between important human/animal pathogens and their nonpathogenic, symbiotic, chemolithoautotrophic deepsea relatives. [epsilon]-Proteobacteria | comparative microbial genomics | deep-sea hydrothermal vent | pathogenesis | symbiosis

Published

2007