Succession of a bacterial rhizospheric community along a chronosequence of a cold desert

Global warming and ongoing climate changes result in glacier retreat at different latitude and altitude on Earth. Ice melting determines the exposure of a barren mineral substrate subjected to the processes of primary colonization and soil formation. Chronosequences can be identified on glacier mora...

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Main Authors: F. Mapelli, B. Scaglia, R. Marasco, A. Balloi, E. Rolli, F. Tambone, F. Adani, S. Borin, D. Daffonchio, G. Tsiamis, S. Vasileiadis, K. Bourtzis
Other Authors: F, ., M, a, p, e, l, i, ; G, T, m, ; B, S, c, g, ; R, r, o, ; A, B, ; E, R, ; F, b, n, ; S, V, d, A, ; K, u, t, z, ; D, D, f
Format: Conference Object
Language:English
Published: 2012
Subjects:
Settore AGR/16 - Microbiologia Agraria
Arctic
Svalbard
Norway
glacier
Global warming
Saxifraga oppositifolia
Online Access:http://hdl.handle.net/2434/266364
id ftunivmilanoair:oai:air.unimi.it:2434/266364
record_format openpolar
spelling ftunivmilanoair:oai:air.unimi.it:2434/266364 2024-01-14T10:05:02+01:00 Succession of a bacterial rhizospheric community along a chronosequence of a cold desert F. Mapelli B. Scaglia R. Marasco A. Balloi E. Rolli F. Tambone F. Adani S. Borin D. Daffonchio G. Tsiamis S. Vasileiadis K. Bourtzis F . M a p e l i ; G T m ; B S c g ; R r o ; A B ; E R ; F b n ; S V d A ; K u t z ; D D f 2012-07 http://hdl.handle.net/2434/266364 eng eng BIODESERT International Workshop - Microbial diversity in desert extreme environment “Microarrays from theory to application” http://hdl.handle.net/2434/266364 Settore AGR/16 - Microbiologia Agraria info:eu-repo/semantics/conferenceObject 2012 ftunivmilanoair 2023-12-19T23:33:00Z Global warming and ongoing climate changes result in glacier retreat at different latitude and altitude on Earth. Ice melting determines the exposure of a barren mineral substrate subjected to the processes of primary colonization and soil formation. Chronosequences can be identified on glacier moraines, where the increasing distance from the forefront corresponds to the increase of time of permanence out of ice and to ecosystem development. Shifts of microbial and plant communities over time are defined as succession, which can be influenced by several factors over a forefield chronosequence. To describe the ecological succession of the microbiome composition during primary succession of high arctic soils we identified an endemic vascular plant present in the whole transect of the Midtre-Loveénbreen glacier, namely Saxifraga oppositifolia, and we analyzed the associated rhizospheric communities and the corresponding bulk soils. In the present study we applied cultivation-independent methods to investigate (i) the role of successional stages and (ii) the influence of the host plant on the microbial community inhabiting both bulk and rhizospheric soils collected from seven stations of a chronosequence on the forefront of the Midtre-Loveénbreen glacier (78°53’N, Svalbard Islands, Norway), distinguished by increasing levels of soil fertility and plant colonization (Hodkinson et al., 2003). Detailed description of the rhizospheric microbiome realized by Denaturing Gradient Gel Electrophoresis, 16S rRNA clone libraries and PhyloChip analyses revealed a complex bacterial community in all the successional stages. Bulk and rhizospheric soils hosted different microbial communities, although the rhizosphere microbiome in the youngest soils was more similar to those of bulk soils than to the older rhizospheres. The results indicated therefore that the structure of the bacterial communities colonizing the S. oppositifolia rhizosphere is shaped by the presence of the plant together with the degree of soil development. The ... Conference Object Arctic glacier glacier Global warming Saxifraga oppositifolia Svalbard The University of Milan: Archivio Istituzionale della Ricerca (AIR) Arctic Svalbard Norway
institution Open Polar
collection The University of Milan: Archivio Istituzionale della Ricerca (AIR)
op_collection_id ftunivmilanoair
language English
topic Settore AGR/16 - Microbiologia Agraria
spellingShingle Settore AGR/16 - Microbiologia Agraria
F. Mapelli
B. Scaglia
R. Marasco
A. Balloi
E. Rolli
F. Tambone
F. Adani
S. Borin
D. Daffonchio
G. Tsiamis
S. Vasileiadis
K. Bourtzis
Succession of a bacterial rhizospheric community along a chronosequence of a cold desert
topic_facet Settore AGR/16 - Microbiologia Agraria
description Global warming and ongoing climate changes result in glacier retreat at different latitude and altitude on Earth. Ice melting determines the exposure of a barren mineral substrate subjected to the processes of primary colonization and soil formation. Chronosequences can be identified on glacier moraines, where the increasing distance from the forefront corresponds to the increase of time of permanence out of ice and to ecosystem development. Shifts of microbial and plant communities over time are defined as succession, which can be influenced by several factors over a forefield chronosequence. To describe the ecological succession of the microbiome composition during primary succession of high arctic soils we identified an endemic vascular plant present in the whole transect of the Midtre-Loveénbreen glacier, namely Saxifraga oppositifolia, and we analyzed the associated rhizospheric communities and the corresponding bulk soils. In the present study we applied cultivation-independent methods to investigate (i) the role of successional stages and (ii) the influence of the host plant on the microbial community inhabiting both bulk and rhizospheric soils collected from seven stations of a chronosequence on the forefront of the Midtre-Loveénbreen glacier (78°53’N, Svalbard Islands, Norway), distinguished by increasing levels of soil fertility and plant colonization (Hodkinson et al., 2003). Detailed description of the rhizospheric microbiome realized by Denaturing Gradient Gel Electrophoresis, 16S rRNA clone libraries and PhyloChip analyses revealed a complex bacterial community in all the successional stages. Bulk and rhizospheric soils hosted different microbial communities, although the rhizosphere microbiome in the youngest soils was more similar to those of bulk soils than to the older rhizospheres. The results indicated therefore that the structure of the bacterial communities colonizing the S. oppositifolia rhizosphere is shaped by the presence of the plant together with the degree of soil development. The ...
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format Conference Object
author F. Mapelli
B. Scaglia
R. Marasco
A. Balloi
E. Rolli
F. Tambone
F. Adani
S. Borin
D. Daffonchio
G. Tsiamis
S. Vasileiadis
K. Bourtzis
author_facet F. Mapelli
B. Scaglia
R. Marasco
A. Balloi
E. Rolli
F. Tambone
F. Adani
S. Borin
D. Daffonchio
G. Tsiamis
S. Vasileiadis
K. Bourtzis
author_sort F. Mapelli
title Succession of a bacterial rhizospheric community along a chronosequence of a cold desert
title_short Succession of a bacterial rhizospheric community along a chronosequence of a cold desert
title_full Succession of a bacterial rhizospheric community along a chronosequence of a cold desert
title_fullStr Succession of a bacterial rhizospheric community along a chronosequence of a cold desert
title_full_unstemmed Succession of a bacterial rhizospheric community along a chronosequence of a cold desert
title_sort succession of a bacterial rhizospheric community along a chronosequence of a cold desert
publishDate 2012
url http://hdl.handle.net/2434/266364
geographic Arctic
Svalbard
Norway
geographic_facet Arctic
Svalbard
Norway
genre Arctic
glacier
glacier
Global warming
Saxifraga oppositifolia
Svalbard
genre_facet Arctic
glacier
glacier
Global warming
Saxifraga oppositifolia
Svalbard
op_relation BIODESERT International Workshop - Microbial diversity in desert extreme environment “Microarrays from theory to application”
http://hdl.handle.net/2434/266364
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