Osmotic Adaptation and Compatible Solute Biosynthesis of Phototrophic Bacteria as Revealed from Genome Analyses

Osmotic adaptation and accumulation of compatible solutes is a key process for life at high osmotic pressure and elevated salt concentrations. Most important solutes that can protect cell structures and metabolic processes at high salt concentrations are glycine betaine and ectoine. The genome analy...

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Bibliographic Details
Published in:Microorganisms (Basel) 2020-12, Vol.9 (1), p.46
Main Authors: Imhoff, Johannes F, Rahn, Tanja, Künzel, Sven, Keller, Alexander, Neulinger, Sven C
Format: Article
Language:English
Subjects:
Adaptation
Bacilli
Bacteria
Biosynthesis
Cyanobacteria
Dehydrogenases
Deoxyribonucleic acid
DNA
DNA methylation
E coli
Ectoine
ectoine biosynthesis
Enzymes
Genes
Genetic testing
Genomes
genomes of photosynthetic bacteria
Glycine
Glycine betaine
glycine betaine biosynthesis
Gram-positive bacteria
Kinases
Methyltransferase
Osmosis
osmotic adaptation
Osmotic adaptations
Osmotic pressure
Phototrophic bacteria
Phylogeny
phylogeny of osmolyte biosynthesis
Pyruvic acid
Salts
Sarcosine
Solutes
Streptomycetes
Sulfur
Transportation systems
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Summary:Osmotic adaptation and accumulation of compatible solutes is a key process for life at high osmotic pressure and elevated salt concentrations. Most important solutes that can protect cell structures and metabolic processes at high salt concentrations are glycine betaine and ectoine. The genome analysis of more than 130 phototrophic bacteria shows that biosynthesis of glycine betaine is common among marine and halophilic phototrophic and their chemotrophic relatives, as well as in representatives of and , but are also found in halophilic and This ability correlates well with the successful toleration of extreme salt concentrations. Freshwater bacteria in general lack the possibilities to synthesize and often also to take up these compounds. The biosynthesis of ectoine is found in the phylogenetic lines of phototrophic - and , most prominent in the species and a number of . It is also common among and . The phylogeny of glycine-sarcosine methyltransferase (GMT) and diaminobutyrate-pyruvate aminotransferase (EctB) sequences correlate well with otherwise established phylogenetic groups. Most significantly, GMT sequences of cyanobacteria form two major phylogenetic branches and the branch of species is distinct from all other . A variety of transport systems for osmolytes are present in the studied bacteria.
ISSN:2076-2607
2076-2607
DOI:10.3390/microorganisms9010046