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Dynamics of Cellulose Degradation by Soil Microorganisms from Two Contrasting Soil Types. / Гладков, Григорий Валерьевич; Кимеклис, Анастасия Кирилловна; Орлова, Ольга Владимировна; ЛИСИНА, Т.О.; Кичко, Арина Александровна; Безлепский, Александр; Андронов, Евгений Евгеньевич.

In: Microorganisms, Vol. 12, No. 8, 1728, 21.08.2024.

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Гладков ГВ, Кимеклис АК, Орлова ОВ, ЛИСИНА ТО, Кичко АА, Безлепский А et al. Dynamics of Cellulose Degradation by Soil Microorganisms from Two Contrasting Soil Types. Microorganisms. 2024 Aug 21;12(8). 1728. https://doi.org/10.3390/microorganisms12081728

Author

Гладков, Григорий Валерьевич ; Кимеклис, Анастасия Кирилловна ; Орлова, Ольга Владимировна ; ЛИСИНА, Т.О. ; Кичко, Арина Александровна ; Безлепский, Александр ; Андронов, Евгений Евгеньевич. / Dynamics of Cellulose Degradation by Soil Microorganisms from Two Contrasting Soil Types. In: Microorganisms. 2024 ; Vol. 12, No. 8.

BibTeX

@article{70f2f43ad61e4a21b204272f9929eea4,
title = "Dynamics of Cellulose Degradation by Soil Microorganisms from Two Contrasting Soil Types",
abstract = "The search for active cellulolytic consortia among soil microorganisms is of significant applied interest, but the dynamics of the formation of such communities remain insufficiently studied. To gain insight into the formation of an active cellulolytic community, the experiment was designed to examine the colonization of a sterile substrate (cellulose) by microorganisms from two soil types: sod-podzolic and chernozem. To achieve this, the substrate was placed in the soil and incubated for six months. To assess microbiome dynamics, the experiment employed sequencing of 16S rRNA gene fragment and ITS2 amplicon libraries at four time points. It was demonstrated that, from the second month of the experiment, the prokaryotic component of the communities reached a state of stability, with a community composition specific to each soil type. The results demonstrated no relationship between changes in community diversity and soil respiration. There also was no significant shift in the community diversity throughout the chronosequence. Furthermore, the taxonomic composition of the community shifted towards a decrease in the proportion of Pseudomonadota and an increase in representatives of the Bacteroidota, Bacillota, and Verrucomicrobiota phyla. The network analysis of the community demonstrated that, in contrast to sod-podzolic soil, chernozem is distinguished by a higher modularity, with the formation of taxon-specific groups of microorganisms at each stage of the chronoseries. These differences are attributed to the alterations in the eukaryotic component of the community, particularly in the prevalence of nematodes and predatory fungi, which in turn influenced the cellulolytic community.",
keywords = "amplicon sequencing, cellulolytic community, cellulose decomposition, chernozem soil, sod-podzolic soil, succession",
author = "Гладков, {Григорий Валерьевич} and Кимеклис, {Анастасия Кирилловна} and Орлова, {Ольга Владимировна} and Т.О. ЛИСИНА and Кичко, {Арина Александровна} and Александр Безлепский and Андронов, {Евгений Евгеньевич}",
year = "2024",
month = aug,
day = "21",
doi = "10.3390/microorganisms12081728",
language = "English",
volume = "12",
journal = "Microorganisms",
issn = "2076-2607",
publisher = "MDPI AG",
number = "8",

}

RIS

TY - JOUR

T1 - Dynamics of Cellulose Degradation by Soil Microorganisms from Two Contrasting Soil Types

AU - Гладков, Григорий Валерьевич

AU - Кимеклис, Анастасия Кирилловна

AU - Орлова, Ольга Владимировна

AU - ЛИСИНА, Т.О.

AU - Кичко, Арина Александровна

AU - Безлепский, Александр

AU - Андронов, Евгений Евгеньевич

PY - 2024/8/21

Y1 - 2024/8/21

N2 - The search for active cellulolytic consortia among soil microorganisms is of significant applied interest, but the dynamics of the formation of such communities remain insufficiently studied. To gain insight into the formation of an active cellulolytic community, the experiment was designed to examine the colonization of a sterile substrate (cellulose) by microorganisms from two soil types: sod-podzolic and chernozem. To achieve this, the substrate was placed in the soil and incubated for six months. To assess microbiome dynamics, the experiment employed sequencing of 16S rRNA gene fragment and ITS2 amplicon libraries at four time points. It was demonstrated that, from the second month of the experiment, the prokaryotic component of the communities reached a state of stability, with a community composition specific to each soil type. The results demonstrated no relationship between changes in community diversity and soil respiration. There also was no significant shift in the community diversity throughout the chronosequence. Furthermore, the taxonomic composition of the community shifted towards a decrease in the proportion of Pseudomonadota and an increase in representatives of the Bacteroidota, Bacillota, and Verrucomicrobiota phyla. The network analysis of the community demonstrated that, in contrast to sod-podzolic soil, chernozem is distinguished by a higher modularity, with the formation of taxon-specific groups of microorganisms at each stage of the chronoseries. These differences are attributed to the alterations in the eukaryotic component of the community, particularly in the prevalence of nematodes and predatory fungi, which in turn influenced the cellulolytic community.

AB - The search for active cellulolytic consortia among soil microorganisms is of significant applied interest, but the dynamics of the formation of such communities remain insufficiently studied. To gain insight into the formation of an active cellulolytic community, the experiment was designed to examine the colonization of a sterile substrate (cellulose) by microorganisms from two soil types: sod-podzolic and chernozem. To achieve this, the substrate was placed in the soil and incubated for six months. To assess microbiome dynamics, the experiment employed sequencing of 16S rRNA gene fragment and ITS2 amplicon libraries at four time points. It was demonstrated that, from the second month of the experiment, the prokaryotic component of the communities reached a state of stability, with a community composition specific to each soil type. The results demonstrated no relationship between changes in community diversity and soil respiration. There also was no significant shift in the community diversity throughout the chronosequence. Furthermore, the taxonomic composition of the community shifted towards a decrease in the proportion of Pseudomonadota and an increase in representatives of the Bacteroidota, Bacillota, and Verrucomicrobiota phyla. The network analysis of the community demonstrated that, in contrast to sod-podzolic soil, chernozem is distinguished by a higher modularity, with the formation of taxon-specific groups of microorganisms at each stage of the chronoseries. These differences are attributed to the alterations in the eukaryotic component of the community, particularly in the prevalence of nematodes and predatory fungi, which in turn influenced the cellulolytic community.

KW - amplicon sequencing

KW - cellulolytic community

KW - cellulose decomposition

KW - chernozem soil

KW - sod-podzolic soil

KW - succession

UR - https://www.mendeley.com/catalogue/ce9fc659-2503-3ff1-b364-dd12f9fac64f/

U2 - 10.3390/microorganisms12081728

DO - 10.3390/microorganisms12081728

M3 - Article

C2 - 39203569

VL - 12

JO - Microorganisms

JF - Microorganisms

SN - 2076-2607

IS - 8

M1 - 1728

ER -

ID: 124310421