Microbe-mediated plant-soil feedback causes historical contingency effects in plant community assembly

P. Kardol; N.J. Cornips; M.M.L. Van Kempen; J.M.T. Bakx-Schotman; W.H. Van der Putten

doi:10.1890/06-0502

Microbe-mediated plant-soil feedback causes historical contingency effects in plant community assembly

P. Kardol, N.J. Cornips, M.M.L. Van Kempen, J.M.T. Bakx-Schotman, W.H. Van der Putten

Research output: Contribution to journal/periodical › Article › Scientific › peer-review

397 Citations (Scopus)

1290 Downloads (Pure)

Abstract

Plant–soil feedback affects performance and competitive ability of individual plants. However, the importance of plant–soil feedback in historical contingency processes and plant community dynamics is largely unknown. In microcosms, we tested how six early-successional plant species of secondary succession on ex-arable land induced plant-specific changes in soil community composition. Following one growth cycle of conditioning the soil community, soil feedback effects were assessed as plant performance in soil of their own as compared to soil from a mixture of the other five early-successional species. Performance was tested in monocultures and in mixed communities with heterospecific competition from mid-successional species. The role of soil microorganisms was determined by isolating the microbial component from the soil community, re-inoculating microorganisms into sterilized substrate, and analyzing plant biomass responses of the early- and mid-successional species. Plant–soil feedback responses of the early-successional species were negative and significantly increased when the plants were grown in a competitive environment with heterospecifics. In monocultures, three early-successional species experienced negative feedback in soil with a history of conspecifics, while all early-successional species experienced negative feedback when grown with interspecific competition. Interestingly, the nonnative forb Conyza canadensis showed the weakest soil feedback e We conclude that feedback between early-successional plant species and soil microorganisms can play a crucial role in breaking dominance of early-successional plant communities. Moreover the influences on soil microorganism community composition influenced plant community dynamics in the mid-successional plant communities. These results shed new light on how feedback effects between plants and soil organisms in one successional stage result in a biotic legacy effect, which influences plant commu

Original language	English
Pages (from-to)	147-162
Journal	Ecological Monographs
Volume	77
Issue number	2
DOIs	https://doi.org/10.1890/06-0502
Publication status	Published - 2007

Access to Document

10.1890/06-0502

PDF
Ecological Society of America -- First page must state "Copyright by the Ecological Society of America," along with the full citation
Final published version, 490 KB

Cite this

@article{e9147c045a524cb69240d4f032183d4f,

title = "Microbe-mediated plant-soil feedback causes historical contingency effects in plant community assembly",

abstract = "Plant–soil feedback affects performance and competitive ability of individual plants. However, the importance of plant–soil feedback in historical contingency processes and plant community dynamics is largely unknown. In microcosms, we tested how six early-successional plant species of secondary succession on ex-arable land induced plant-specific changes in soil community composition. Following one growth cycle of conditioning the soil community, soil feedback effects were assessed as plant performance in soil of their own as compared to soil from a mixture of the other five early-successional species. Performance was tested in monocultures and in mixed communities with heterospecific competition from mid-successional species. The role of soil microorganisms was determined by isolating the microbial component from the soil community, re-inoculating microorganisms into sterilized substrate, and analyzing plant biomass responses of the early- and mid-successional species. Plant–soil feedback responses of the early-successional species were negative and significantly increased when the plants were grown in a competitive environment with heterospecifics. In monocultures, three early-successional species experienced negative feedback in soil with a history of conspecifics, while all early-successional species experienced negative feedback when grown with interspecific competition. Interestingly, the nonnative forb Conyza canadensis showed the weakest soil feedback e We conclude that feedback between early-successional plant species and soil microorganisms can play a crucial role in breaking dominance of early-successional plant communities. Moreover the influences on soil microorganism community composition influenced plant community dynamics in the mid-successional plant communities. These results shed new light on how feedback effects between plants and soil organisms in one successional stage result in a biotic legacy effect, which influences plant commu",

author = "P. Kardol and N.J. Cornips and {Van Kempen}, M.M.L. and J.M.T. Bakx-Schotman and {Van der Putten}, W.H.",

note = "Reporting year: 2007 Metis note: 3949;CTE; MTI; file:///C:/pdfs/Pdfs2007/Kardol_ea_3949.pdf",

year = "2007",

doi = "10.1890/06-0502",

language = "English",

volume = "77",

pages = "147--162",

journal = "Ecological Monographs",

issn = "0012-9615",

publisher = "Ecological Society of America",

number = "2",

}

TY - JOUR

T1 - Microbe-mediated plant-soil feedback causes historical contingency effects in plant community assembly

AU - Kardol, P.

AU - Cornips, N.J.

AU - Van Kempen, M.M.L.

AU - Bakx-Schotman, J.M.T.

AU - Van der Putten, W.H.

N1 - Reporting year: 2007 Metis note: 3949;CTE; MTI; file:///C:/pdfs/Pdfs2007/Kardol_ea_3949.pdf

PY - 2007

Y1 - 2007

N2 - Plant–soil feedback affects performance and competitive ability of individual plants. However, the importance of plant–soil feedback in historical contingency processes and plant community dynamics is largely unknown. In microcosms, we tested how six early-successional plant species of secondary succession on ex-arable land induced plant-specific changes in soil community composition. Following one growth cycle of conditioning the soil community, soil feedback effects were assessed as plant performance in soil of their own as compared to soil from a mixture of the other five early-successional species. Performance was tested in monocultures and in mixed communities with heterospecific competition from mid-successional species. The role of soil microorganisms was determined by isolating the microbial component from the soil community, re-inoculating microorganisms into sterilized substrate, and analyzing plant biomass responses of the early- and mid-successional species. Plant–soil feedback responses of the early-successional species were negative and significantly increased when the plants were grown in a competitive environment with heterospecifics. In monocultures, three early-successional species experienced negative feedback in soil with a history of conspecifics, while all early-successional species experienced negative feedback when grown with interspecific competition. Interestingly, the nonnative forb Conyza canadensis showed the weakest soil feedback e We conclude that feedback between early-successional plant species and soil microorganisms can play a crucial role in breaking dominance of early-successional plant communities. Moreover the influences on soil microorganism community composition influenced plant community dynamics in the mid-successional plant communities. These results shed new light on how feedback effects between plants and soil organisms in one successional stage result in a biotic legacy effect, which influences plant commu

AB - Plant–soil feedback affects performance and competitive ability of individual plants. However, the importance of plant–soil feedback in historical contingency processes and plant community dynamics is largely unknown. In microcosms, we tested how six early-successional plant species of secondary succession on ex-arable land induced plant-specific changes in soil community composition. Following one growth cycle of conditioning the soil community, soil feedback effects were assessed as plant performance in soil of their own as compared to soil from a mixture of the other five early-successional species. Performance was tested in monocultures and in mixed communities with heterospecific competition from mid-successional species. The role of soil microorganisms was determined by isolating the microbial component from the soil community, re-inoculating microorganisms into sterilized substrate, and analyzing plant biomass responses of the early- and mid-successional species. Plant–soil feedback responses of the early-successional species were negative and significantly increased when the plants were grown in a competitive environment with heterospecifics. In monocultures, three early-successional species experienced negative feedback in soil with a history of conspecifics, while all early-successional species experienced negative feedback when grown with interspecific competition. Interestingly, the nonnative forb Conyza canadensis showed the weakest soil feedback e We conclude that feedback between early-successional plant species and soil microorganisms can play a crucial role in breaking dominance of early-successional plant communities. Moreover the influences on soil microorganism community composition influenced plant community dynamics in the mid-successional plant communities. These results shed new light on how feedback effects between plants and soil organisms in one successional stage result in a biotic legacy effect, which influences plant commu

U2 - 10.1890/06-0502

DO - 10.1890/06-0502

M3 - Article

SN - 0012-9615

VL - 77

SP - 147

EP - 162

JO - Ecological Monographs

JF - Ecological Monographs

IS - 2

ER -

Microbe-mediated plant-soil feedback causes historical contingency effects in plant community assembly

Abstract

Access to Document

Fingerprint

Cite this