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Structural and physiological adaptations of soil microorganisms to freezing revealed by position-specific labeling and compound-specific <sup>13</sup>C analysis

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dc.contributor.author Bore E.
dc.contributor.author Halicki S.
dc.contributor.author Kuzyakov Y.
dc.contributor.author Dippold M.
dc.date.accessioned 2020-01-15T21:17:06Z
dc.date.available 2020-01-15T21:17:06Z
dc.date.issued 2019
dc.identifier.issn 0168-2563
dc.identifier.uri https://dspace.kpfu.ru/xmlui/handle/net/155515
dc.description.abstract © 2019, Springer Nature Switzerland AG. Psychrotolerant microbes are crucial for carbon cycling and biotechnological applications. Nonetheless, the mechanisms enabling their survival and functioning in frozen environments remain unclear. To elucidate adaptations of microbial cell membranes to freezing, we incubated soils with position-specific 13C labeled glucose at + 5 (control), − 5 and − 20 °C and quantified 13C in CO2 and phospholipid fatty acids. High oxidation of glucose C-1 at + 5 °C revealed a transformation via the pentose phosphate pathway. At subzero temperatures, however, the preferential oxidation of C-4 position suggested a switch to glycolysis. The threefold increase of Gram-negative phospholipid fatty acids in soil incubated at − 5 °C was accompanied by a twofold increase in 13C incorporation. This unequal increase of phospholipid fatty acids and incorporated 13C can be explained by simultaneous desaturation of existing fatty acid chains and the de novo synthesis of monounsaturated fatty acids, which indicates microbial growth. In contrast, Gram-positive bacteria incorporated 2 times higher 13C into their phospholipid fatty acids at − 20 °C than at − 5 and + 5 °C without a significant increase in their fatty acid contents. This reflects intensive repair of membranes damaged at − 20 °C without microbial growth. The fungal/bacterial ratio was 1.5 times lower at subzero temperatures than at + 5 °C, reflecting a shift in microbial community structure towards bacteria. Accordingly, soil microorganisms adapted to freezing by (1) switching their metabolic pathway from the pentose phosphate pathway to glycolysis, (2) modifying phospholipid fatty acids by desaturation and, (3) shifting microbial community structure towards Gram-negative bacteria by reducing the fungal population.
dc.relation.ispartofseries Biogeochemistry
dc.subject Community structure
dc.subject Metabolic tracing
dc.subject Phospholipid adaptations
dc.subject Psychrotolerant microbes
dc.subject Subzero temperatures
dc.title Structural and physiological adaptations of soil microorganisms to freezing revealed by position-specific labeling and compound-specific <sup>13</sup>C analysis
dc.type Article
dc.relation.ispartofseries-issue 2
dc.relation.ispartofseries-volume 143
dc.collection Публикации сотрудников КФУ
dc.relation.startpage 207
dc.source.id SCOPUS01682563-2019-143-2-SID85062692730


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  • Публикации сотрудников КФУ Scopus [24551]
    Коллекция содержит публикации сотрудников Казанского федерального (до 2010 года Казанского государственного) университета, проиндексированные в БД Scopus, начиная с 1970г.

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