Structural basis for the aminoacid composition of proteins from halophilic archea

Proteins from halophilic organisms, which live in extreme saline conditions, have evolved to remain folded at very high ionic strengths. The surfaces of halophilic proteins show a biased amino acid composition with a high prevalence of aspartic and glutamic acids, a low frequency of lysine, and a hi...

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Veröffentlicht in:	PLoS biology 2009-12, Vol.7 (12), p.e1000257-1000257
Hauptverfasser:	Tadeo, Xavier, López-Méndez, Blanca, Trigueros, Tamara, Laín, Ana, Castaño, David, Millet, Oscar
Format:	Artikel
Sprache:	eng
Schlagworte:	Adaptation, Biological Amino acids Amino Acids - analysis Archaeal Proteins - chemistry Archaeal Proteins - genetics Biochemistry/Protein Chemistry Biophysics Brackish Chemistry/Biochemistry Composition DNA Ligases - chemistry DNA Ligases - genetics Haloferax volcanii - chemistry Haloferax volcanii - genetics Halophilic bacteria Microbiology Microbiology/Environmental Microbiology Mutagenesis, Site-Directed Mutation Physiological aspects Protein Conformation Proteins Salinity Solubility Spectrum analysis Structure
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creator	Tadeo, Xavier López-Méndez, Blanca Trigueros, Tamara Laín, Ana Castaño, David Millet, Oscar
description	Proteins from halophilic organisms, which live in extreme saline conditions, have evolved to remain folded at very high ionic strengths. The surfaces of halophilic proteins show a biased amino acid composition with a high prevalence of aspartic and glutamic acids, a low frequency of lysine, and a high occurrence of amino acids with a low hydrophobic character. Using extensive mutational studies on the protein surfaces, we show that it is possible to decrease the salt dependence of a typical halophilic protein to the level of a mesophilic form and engineer a protein from a mesophilic organism into an obligate halophilic form. NMR studies demonstrate complete preservation of the three-dimensional structure of extreme mutants and confirm that salt dependency is conferred exclusively by surface residues. In spite of the statistically established fact that most halophilic proteins are strongly acidic, analysis of a very large number of mutants showed that the effect of salt on protein stability is largely independent of the total protein charge. Conversely, we quantitatively demonstrate that halophilicity is directly related to a decrease in the accessible surface area.
doi_str_mv	10.1371/journal.pbio.1000257
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subjects	Adaptation, Biological Amino acids Amino Acids - analysis Archaeal Proteins - chemistry Archaeal Proteins - genetics Biochemistry/Protein Chemistry Biophysics Brackish Chemistry/Biochemistry Composition DNA Ligases - chemistry DNA Ligases - genetics Haloferax volcanii - chemistry Haloferax volcanii - genetics Halophilic bacteria Microbiology Microbiology/Environmental Microbiology Mutagenesis, Site-Directed Mutation Physiological aspects Protein Conformation Proteins Salinity Solubility Spectrum analysis Structure
title	Structural basis for the aminoacid composition of proteins from halophilic archea
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