Intercropping drives plant phenotypic plasticity and changes in functional trait space

Department of Plant and Environmental Sciences

Intercropping drives plant phenotypic plasticity and changes in functional trait space

Research output: Contribution to journal › Journal article › Research › peer-review

Standard

Intercropping drives plant phenotypic plasticity and changes in functional trait space. / Ajal, James; Kiær, Lars P.; Pakeman, Robin J.; Scherber, Christoph; Weih, Martin.

In: Basic and Applied Ecology, Vol. 61, 2022, p. 41-52.

Research output: Contribution to journal › Journal article › Research › peer-review

Harvard

Ajal, J, Kiær, LP, Pakeman, RJ, Scherber, C & Weih, M 2022, 'Intercropping drives plant phenotypic plasticity and changes in functional trait space', Basic and Applied Ecology, vol. 61, pp. 41-52. https://doi.org/10.1016/j.baae.2022.03.009

APA

Ajal, J., Kiær, L. P., Pakeman, R. J., Scherber, C., & Weih, M. (2022). Intercropping drives plant phenotypic plasticity and changes in functional trait space. Basic and Applied Ecology, 61, 41-52. https://doi.org/10.1016/j.baae.2022.03.009

Vancouver

Ajal J, Kiær LP, Pakeman RJ, Scherber C, Weih M. Intercropping drives plant phenotypic plasticity and changes in functional trait space. Basic and Applied Ecology. 2022;61:41-52. https://doi.org/10.1016/j.baae.2022.03.009

Author

Ajal, James ; Kiær, Lars P. ; Pakeman, Robin J. ; Scherber, Christoph ; Weih, Martin. / Intercropping drives plant phenotypic plasticity and changes in functional trait space. In: Basic and Applied Ecology. 2022 ; Vol. 61. pp. 41-52.

Bibtex

@article{1b9c8be25a6e416cb6a772926fd5b5e0,

title = "Intercropping drives plant phenotypic plasticity and changes in functional trait space",

abstract = "The relevance of intercropping, where two or more crop species are simultaneously grown on the same land space, is growing due to its potential for improving resource use and maintaining stable yields under variable weather conditions. However, the actual growth of intercropped species may differ resulting from the idiosyncratic effect of crop diversity, and with this, the realized benefits from intercrops are found to depend critically on the cultivar, species, management and environmental conditions. This study aimed to apply a trait-based approach, in which ecological niche spaces are defined through n-dimensional hypervolumes, to identify the contribution of species/cultivar, cultivation design (sole crop or intercrop) and management (low or high fertilization) to the trait diversity of four crop species, pea-barley and faba bean-wheat, when grown as sole crops and intercrops. Four traits were used as trait axes for the trait space analysis: canopy height, shoot biomass, tiller/node number, and grain yield. We found that trait spaces differed with crop species and cultivars, and whether they were grown as intercrops or sole crops. Trait spaces differed between high and low fertilization only for the cereals grown in the more productive site (i.e. Denmark). Species grown as intercrops had larger volumes than when grown as sole crops, as a result of trait plasticity. This response to intercropping was apparent in almost all the species grown in Sweden and Denmark, except for wheat in Denmark. The study demonstrated that individual species responded to intercropping compared to sole cropping through the plasticity of traits, which influenced the shape of the hypervolumes to divide up the trait space between the species. The findings are important in illustrating the plastic responses of arable crops, which are relevant for understanding the productivity of species grown in intercrops as compared to sole crops.",

keywords = "Cereal-legume, Crop diversity, Functional traits, Hypervolume, Intercrops, Trait space",

author = "James Ajal and Ki{\ae}r, {Lars P.} and Pakeman, {Robin J.} and Christoph Scherber and Martin Weih",

note = "Funding Information: This work has received funding from the DIVERSify project, a grant from the European Union's Horizon 2020 Research and Innovation Programme under grant agreement No. 727284 . Publisher Copyright: {\textcopyright} 2022 The Author(s)",

year = "2022",

doi = "10.1016/j.baae.2022.03.009",

language = "English",

volume = "61",

pages = "41--52",

journal = "Basic and Applied Ecology",

issn = "1439-1791",

publisher = "Elsevier GmbH - Urban und Fischer",

}

RIS

TY - JOUR

T1 - Intercropping drives plant phenotypic plasticity and changes in functional trait space

AU - Ajal, James

AU - Kiær, Lars P.

AU - Pakeman, Robin J.

AU - Scherber, Christoph

AU - Weih, Martin

N1 - Funding Information: This work has received funding from the DIVERSify project, a grant from the European Union's Horizon 2020 Research and Innovation Programme under grant agreement No. 727284 . Publisher Copyright: © 2022 The Author(s)

PY - 2022

Y1 - 2022

N2 - The relevance of intercropping, where two or more crop species are simultaneously grown on the same land space, is growing due to its potential for improving resource use and maintaining stable yields under variable weather conditions. However, the actual growth of intercropped species may differ resulting from the idiosyncratic effect of crop diversity, and with this, the realized benefits from intercrops are found to depend critically on the cultivar, species, management and environmental conditions. This study aimed to apply a trait-based approach, in which ecological niche spaces are defined through n-dimensional hypervolumes, to identify the contribution of species/cultivar, cultivation design (sole crop or intercrop) and management (low or high fertilization) to the trait diversity of four crop species, pea-barley and faba bean-wheat, when grown as sole crops and intercrops. Four traits were used as trait axes for the trait space analysis: canopy height, shoot biomass, tiller/node number, and grain yield. We found that trait spaces differed with crop species and cultivars, and whether they were grown as intercrops or sole crops. Trait spaces differed between high and low fertilization only for the cereals grown in the more productive site (i.e. Denmark). Species grown as intercrops had larger volumes than when grown as sole crops, as a result of trait plasticity. This response to intercropping was apparent in almost all the species grown in Sweden and Denmark, except for wheat in Denmark. The study demonstrated that individual species responded to intercropping compared to sole cropping through the plasticity of traits, which influenced the shape of the hypervolumes to divide up the trait space between the species. The findings are important in illustrating the plastic responses of arable crops, which are relevant for understanding the productivity of species grown in intercrops as compared to sole crops.

AB - The relevance of intercropping, where two or more crop species are simultaneously grown on the same land space, is growing due to its potential for improving resource use and maintaining stable yields under variable weather conditions. However, the actual growth of intercropped species may differ resulting from the idiosyncratic effect of crop diversity, and with this, the realized benefits from intercrops are found to depend critically on the cultivar, species, management and environmental conditions. This study aimed to apply a trait-based approach, in which ecological niche spaces are defined through n-dimensional hypervolumes, to identify the contribution of species/cultivar, cultivation design (sole crop or intercrop) and management (low or high fertilization) to the trait diversity of four crop species, pea-barley and faba bean-wheat, when grown as sole crops and intercrops. Four traits were used as trait axes for the trait space analysis: canopy height, shoot biomass, tiller/node number, and grain yield. We found that trait spaces differed with crop species and cultivars, and whether they were grown as intercrops or sole crops. Trait spaces differed between high and low fertilization only for the cereals grown in the more productive site (i.e. Denmark). Species grown as intercrops had larger volumes than when grown as sole crops, as a result of trait plasticity. This response to intercropping was apparent in almost all the species grown in Sweden and Denmark, except for wheat in Denmark. The study demonstrated that individual species responded to intercropping compared to sole cropping through the plasticity of traits, which influenced the shape of the hypervolumes to divide up the trait space between the species. The findings are important in illustrating the plastic responses of arable crops, which are relevant for understanding the productivity of species grown in intercrops as compared to sole crops.

KW - Cereal-legume

KW - Crop diversity

KW - Functional traits

KW - Hypervolume

KW - Intercrops

KW - Trait space

U2 - 10.1016/j.baae.2022.03.009

DO - 10.1016/j.baae.2022.03.009

M3 - Journal article

AN - SCOPUS:85127472238

VL - 61

SP - 41

EP - 52

JO - Basic and Applied Ecology

JF - Basic and Applied Ecology

SN - 1439-1791

ER -

ID: 303867359