Your search keyword '"Munk, A. Christine"' showing total 5 results

1. Chapter 12: Bacillus anthracis.

Author

CHALLACOMBE, JEAN F., OKINAKA, RICHARD T., MUNK, A. CHRISTINE, BRETTIN, THOMAS S., and KEIM, PAUL

Published

2011

2. Temperature regulation of virulence factors in the pathogen Vibrio coralliilyticus.

Author

Kimes, Nikole E, Grim, Christopher J, Johnson, Wesley R, Hasan, Nur A, Tall, Ben D, Kothary, Mahendra H, Kiss, Hajnalka, Munk, A Christine, Tapia, Roxanne, Green, Lance, Detter, Chris, Bruce, David C, Brettin, Thomas S, Colwell, Rita R, and Morris, Pamela J

Subjects

VIBRIO, OCEAN temperature, MICROBIAL virulence, CORAL declines, BIOLOGICAL assay, BIOLUMINESCENCE, HEMOLYSIS & hemolysins

Abstract

Sea surface temperatures (SST) are rising because of global climate change. As a result, pathogenic Vibrio species that infect humans and marine organisms during warmer summer months are of growing concern. Coral reefs, in particular, are already experiencing unprecedented degradation worldwide due in part to infectious disease outbreaks and bleaching episodes that are exacerbated by increasing SST. For example, Vibrio coralliilyticus, a globally distributed bacterium associated with multiple coral diseases, infects corals at temperatures above 27 °C. The mechanisms underlying this temperature-dependent pathogenicity, however, are unknown. In this study, we identify potential virulence mechanisms using whole genome sequencing of V. coralliilyticus ATCC (American Type Culture Collection) BAA-450. Furthermore, we demonstrate direct temperature regulation of numerous virulence factors using proteomic analysis and bioassays. Virulence factors involved in motility, host degradation, secretion, antimicrobial resistance and transcriptional regulation are upregulated at the higher virulent temperature of 27 °C, concurrent with phenotypic changes in motility, antibiotic resistance, hemolysis, cytotoxicity and bioluminescence. These results provide evidence that temperature regulates multiple virulence mechanisms in V. coralliilyticus, independent of abundance. The ecological and biological significance of this temperature-dependent virulence response is reinforced by climate change models that predict tropical SST to consistently exceed 27 °C during the spring, summer and fall seasons. We propose V. coralliilyticus as a model Gram-negative bacterium to study temperature-dependent pathogenicity in Vibrio-related diseases. [ABSTRACT FROM AUTHOR]

Published

2012

3. Comparative genomics of clinical and environmental Vibrio mimicus.

Author

Hasan, Nur A., Grim, Christopher J., Haley, Bradd J., Jongsik Chun, Alam, Munirul, Taviani, Elisa, Hoq, Mozammel, Munk, A. Christine, Saunders, Elizabeth, Brettin, Thomas S., Bruce, David C., Challacombe, Jean F., Detter, J. Chris, Han, Cliff S., Xie, Gary, Nair, G. Balakrish, Huq, Anwar, and Colwell, Rita R.

Subjects

VIBRIO, GENOMICS, TAXONOMY, GENES, BIOLOGICAL evolution

Abstract

Whether Vibrio mimicus is a variant of Vibrio cholerae or a separate species has been the subject of taxonomic controversy. A genomic analysis was undertaken to resolve the issue. The genomes of V. mimicus MB451, a clinical isolate, and VM223, an environmental isolate, comprise ca. 4,347,971 and 4,313,453 bp and encode 3,802 and 3,290 ORFs, respectively. As in other vibrios, chromosome I (C-I) predominantly contains genes necessary for growth and viability, whereas chromosome II (C-II) bears genes for adaptation to environmental change. C-I harbors many virulence genes, including some not previously reported in V. mimicus, such as mannose-sensitive hemagglutinin (MSHA), and enterotoxigenic hemolysin (HlyA); C-II encodes a variant of Vibrio pathogenicity island 2 (VPI-2), and Vibrio seventh pandemic island II (VSP-II) cluster of genes. Extensive genomic rearrangement in C-II indicates it is a hot spot for evolution and genesis of speciation for the genus Vibrio. The number of virulence regions discovered in this study (VSP-II, MSHA, HIyA, type IV pilin, PilE, and integron integrase, Intl4) with no notable difference in potential virulence genes between clinical and environmental strains suggests these genes also may play a role in the environment and that pathogenic strains may arise in the environment. Significant genome synteny with prototypic pre-seventh pandemic strains of V. cholerae was observed, and the results of phylogenetic analysis support the hypothesis that, in the course of evolution, V. mimicus and V. cholerae diverged from a common ancestor with a prototypic sixth pandemic genomic backbone. [ABSTRACT FROM AUTHOR]

Published

2010

4. The genomic basis of trophic strategy in marine bacteria.

Author

Lauro, Federico M., McDougald, Diane, Thomas, Torsten, Williams, Timothy J., Egan, Suhelen, Rice, Scott, DeMaere, Matthew Z., Ting, Lily, Ertan, Haluk, Johnson, Justin, Ferriera, Steven, Lapidus, Alla, Anderso, Iain, Kyrpides, Nikos, Munk, A. Christine, Detter, Chris, Hang, Cliff S., Brown, Mark V., Robb, Frank T., and Kjelleberg, Staffan

Subjects

MARINE bacteria, BIOLOGICAL evolution, GENOMES, NUCLEOTIDE sequence, PHOTOBACTERIUM

Abstract

Many marine bacteria have evolved to grow optimally at either high (copiotrophic) or low (oligotrophic) nutrient concentrations, enabling different species to colonize distinct trophic habitats in the oceans. Here, we compare the genome sequences of two bacteria, Photobacterium angustum S14 and Sphingopyxis alaskensis RB2256, that serve as useful model organisms for copi- otrophic and oligotrophic modes of life and specifically relate the genomic features to trophic strategy for these organisms and define their molecular mechanisms of adaptation. We developed a model for predicting trophic lifestyle from genome sequence data and tested >400,000 proteins representing >500 million nucleotides of sequence data from 126 genome sequences with metagenome data of whole environmental samples. When applied to available oceanic metagenome data (e.g., the Global Ocean Survey data) the model demonstrated that oligotrophs, and not the more readily isolatable copiotrophs, dominate the ocean's free-living microbial populations. Using our model, it is now possible to define the types of bacteria that specific ocean niches are capable of sustaining. [ABSTRACT FROM AUTHOR]

Published

2009

5. Comparative genomics reveals mechanism for short-term and long-term clonal transitions in pandemic Vibrio cholerae.

Author

Jongsik Chun, Grim, Christopher J., Hasan, Nur A., Je Hee Lee, Seon Young Choi, Haley, Bradd J., Taviani, Elisa, Yoon-Seong Jeon, Dong Wook Kim, Jae-Hak Lee, Brettin, Thomas S., Bruce, David C., ChaIIacombe, Jean F., Detter, J. Chris, Han, Cliff S., Munk, A. Christine, Chertkov, Olga, Meincke, Linda, Saunders, Elizabeth, and Walters, Ronald A.

Subjects

VIBRIO cholerae, GENOMICS, PHYLOGENY, PANDEMICS, GENETIC recombination, GENETIC transformation

Abstract

Vibrio cho!erae, the causative agent of cholera, is a bacterium autochthonous to the aquatic environment, and a serious public health threat. V. cholerae serogroup 01 is responsible for the previous two cholera pandemics, in which classical and El Tor biotypes were dominant in the sixth and the current seventh pandemics, respectively. Cholera researchers continually face newly emerging and reemerging pathogenic clones carrying diverse combinations of phenotypic and genotypic properties, which significantly hampered control of the disease. To elucidate evolutionary mechanisms governing genetic diversity of pandemic V. cholerae, we compared the genome sequences of 23 V. cho!erae strains isolated from a variety of sources over the past 98 years. The genome-based phylogeny revealed 12 distinct V. cholerae lineages, of which one comprises both 01 classical and El Tor biotypes. All seventh pandemic clones share nearly identical gene content. Using analogy to influenza virology, we define the transition from sixth to seventh pandemic strains as a "shift" between pathogenic clones belonging to the same 01 serogroup, but from significantly different phyletic lineages. In contrast, transition among clones during the present pandemic period is characterized as a "drift" between clones, differentiated mainly by varying composition of laterally transferred genomic islands, resulting in emergence of variants, exemplified by V. cholerae 0139 and V. cholerae 01 El br hybrid clones. Based on the comparative genomics it is concluded that V. cholerae undergoes extensive genetic recombination via lateral gene transfer, and, therefore, genome assortment, not serogroup, should be used to define pathogenic V. cholerae clones. [ABSTRACT FROM AUTHOR]

Published

2009