The psychrophilic lifestyle as revealed by the genome sequence of <i>Colwellia psychrerythraea</i> 34H through genomic and proteomic analyses

Barbara A. Methé; Karen E. Nelson; Jody W. Deming; Bahram Momen; Eugene Melamud; Xijun Zhang; John Moult; Ramana Madupu; William Nelson; Robert J. Dodson; Lauren Brinkac; Sean C. Daugherty; Anthony S. Durkin; Robert T. DeBoy; James F. Kolonay; Steven A. Sullivan; Liwei Zhou; Tanja M. Davidsen; Martin Wu; Adrienne L. Huston; Matthew R. Lewis; Bruce Weaver; Janice F. Weidman; Hoda Khouri; Terry Utterback; Tamara V. Feldblyum; Claire M. Fraser

doi:10.1073/pnas.0504766102

The psychrophilic lifestyle as revealed by the genome sequence of <i>Colwellia psychrerythraea</i> 34H through genomic and proteomic analyses

Barbara A. Methé(University of Maryland, College Park), Karen E. Nelson(Pennsylvania State University), Jody W. Deming(University of Maryland, College Park), Bahram Momen(University of Maryland, College Park), Eugene Melamud(University of Washington), Xijun Zhang(University of Washington), John Moult(University of Washington), Ramana Madupu(Pennsylvania State University), William Nelson(Pennsylvania State University), Robert J. Dodson(Pennsylvania State University), Lauren Brinkac(Pennsylvania State University), Sean C. Daugherty(Pennsylvania State University), Anthony S. Durkin(Pennsylvania State University), Robert T. DeBoy(Pennsylvania State University), James F. Kolonay(Pennsylvania State University), Steven A. Sullivan(Pennsylvania State University), Liwei Zhou(Pennsylvania State University), Tanja M. Davidsen(Pennsylvania State University), Martin Wu(Pennsylvania State University), Adrienne L. Huston(University of Washington), Matthew R. Lewis(Pennsylvania State University), Bruce Weaver(Pennsylvania State University), Janice F. Weidman(Pennsylvania State University), Hoda Khouri(Pennsylvania State University), Terry Utterback(Pennsylvania State University), Tamara V. Feldblyum(Pennsylvania State University), Claire M. Fraser(Pennsylvania State University)

Proceedings of the National Academy of Sciences

July 25, 2005

10.1073/pnas.0504766102

Cited by 558Open Access

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Abstract

The completion of the 5,373,180-bp genome sequence of the marine psychrophilic bacterium Colwellia psychrerythraea 34H, a model for the study of life in permanently cold environments, reveals capabilities important to carbon and nutrient cycling, bioremediation, production of secondary metabolites, and cold-adapted enzymes. From a genomic perspective, cold adaptation is suggested in several broad categories involving changes to the cell membrane fluidity, uptake and synthesis of compounds conferring cryotolerance, and strategies to overcome temperature-dependent barriers to carbon uptake. Modeling of three-dimensional protein homology from bacteria representing a range of optimal growth temperatures suggests changes to proteome composition that may enhance enzyme effectiveness at low temperatures. Comparative genome analyses suggest that the psychrophilic lifestyle is most likely conferred not by a unique set of genes but by a collection of synergistic changes in overall genome content and amino acid composition.

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