Journal of Ecology
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A role for below-ground biota in plant–plant facilitation

Authors

  • Susana Rodríguez-Echeverría,

    Corresponding author
    1. Centro de Ecologia Funcional, Departamento de Ciências da Vida, Faculdade de Ciências e Tecnologia, Universidade de Coimbra, Coimbra, Portugal
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    • These authors contributed equally to the paper.

  • Cristina Armas,

    Corresponding author
    1. Estación Experimental de Zonas Áridas, Consejo Superior de Investigaciones Científicas, Almería, Spain
    Current affiliation:
    1. Institute of Ecology and Biodiversity, Santiago, Chile
    2. Departamento de Biología, Universidad de La Serena, La Serena, Chile
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    • These authors contributed equally to the paper.

  • Nuria Pistón,

    1. Estación Experimental de Zonas Áridas, Consejo Superior de Investigaciones Científicas, Almería, Spain
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  • Sara Hortal,

    1. Estación Experimental de Zonas Áridas, Consejo Superior de Investigaciones Científicas, Almería, Spain
    Current affiliation:
    1. University of Western Sydney, Hawkesbury Institute for the Environment, Penrith, NSW, Australia
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  • Francisco I. Pugnaire

    1. Estación Experimental de Zonas Áridas, Consejo Superior de Investigaciones Científicas, Almería, Spain
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Summary

  1. Plant–plant facilitation is an important driver of plant diversity, which in turn maintains ecosystem multifunctionality and can buffer some negative effects of climate change. Facilitation is classically attributed to the amelioration of environmental extremes and resource availability. Integrating below-ground biota into the positive plant interactions framework should provide a more realistic understanding of this process, enabling us to gain insights into the dynamics of below–above-ground communities.
  2. We tested the effect of below-ground biota on the performance of a plant community and of individual species using soil extracts from the understorey of a benefactor plant species and adjacent open spaces. Soil bacteria from extracts and experimental microcosms were analysed using pyrosequencing.
  3. Soil biota had a significant effect on the abundance, growth, functional traits and reproductive output of beneficiary plant species through processes that are independent of the direct influence of the benefactor species. Different soil bacterial communities were associated with the benefactor species, the individual beneficiary plant species and the plant community, revealing complex below–above-ground links between plants and soil microbiota.
  4. Synthesis. The below-ground biota cultivated by benefactor plant species play a fundamental role in positive interactions between plant species contributing to the preservation of diversity and the evolution of plant communities.
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Article Information

DOI

10.1111/1365-2745.12159

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© 2013 The Authors. Journal of Ecology © 2013 British Ecological Society

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Keywords

  • nurse species;
  • plant reproduction;
  • plant–soil (below-ground) interactions;
  • pyrosequencing;
  • Retama;
  • soil bacteria

Publication History

  • Issue online:
  • Version of record online:
  • Accepted manuscript online:
  • Manuscript Accepted:
  • Manuscript Received:

Funded by

  • Spanish National Research Council (CSIC). Grant Number: 143AP Program 2009Pt0007
  • Portuguese FCT
  • Spanish Ministry of Science and Innovation
  • Junta de Andalucía Regional Government. Grant Numbers: CGL2010-17081, P09-RNM-4821

Supporting Information

FilenameDescription
jec12159-sup-0001-FigS1-S3-TableS1-S6.pdfapplication/PDF, 940K

Figure S1. Rarefaction curves for operational taxonomic units (OTUs) found in each treatment.

Figure S2. Relative contribution of each plant species to total biomass (plant community experiment).

Figure S3. Hierarchical cluster analysis of the relative abundance (%) of bacterial genera detected in the soil communities before and after the experiments.

Table S1. F values from anova or GLZ, degrees of freedom (d.f.) and significance.

Table S2. Plant species richness, plant diversity (Shannon's Index) and below-ground mass (g) of the plant communities.

Table S3. Above-ground dry mass (g), height (cm), number of leaves and SLA (specific leaf area, m2/kg-1) of each studied plant species (single-species experiment).

Table S4. Reproductive effort (number of fruits and mean seed mass) and fitness (total seed mass per plant) of each studied plant species (single-species experiment).

Table S5. Mean relative abundance per treatment of the most abundant identified soil bacterial taxonomic groups.

Table S6. P-values obtained in the GLM analysis of relative abundance of the bacterial taxa showed in Table S5.

Please note: Wiley-Blackwell is not responsible for the content or functionality of any supporting information supplied by the authors. Any queries (other than missing content) should be directed to the corresponding author for the article.

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  1. 1Yudi M. Lozano, Cristina Armas, Sara Hortal, Fernando Casanoves, Francisco I. Pugnaire, Disentangling above- and below-ground facilitation drivers in arid environments: the role of soil microorganisms, soil properties and microhabitat, New Phytologist, 2017Wiley Online Library
  2. 2Jan Smyčka, Tomáš Herben, Phylogenetic patterns of tragedy of commons in intraspecific root competition, Plant and Soil, 2017CrossRef
  3. 3Shan Luo, Gerlinde B. De Deyn, Bin Jiang, Shixiao Yu, Nina Wurzburger, Soil biota suppress positive plant diversity effects on productivity at high but not low soil fertility, Journal of Ecology, 2017Wiley Online Library
  4. 4Kurt O. Reinhart, Matthew J. Rinella, A common soil handling technique can generate incorrect estimates of soil biota effects on plants, New Phytologist, 2016, 210, 3, 786Wiley Online Library
  5. 5Nuria Pistón, Christian Schöb, Cristina Armas, Iván Prieto, Francisco I. Pugnaire, Contribution of co-occurring shrub species to community richness and phylogenetic diversity along an environmental gradient, Perspectives in Plant Ecology, Evolution and Systematics, 2016, 19, 30CrossRef
  6. 6Ruyi Yang, Fuyu Guo, Jing Li, Nannan Su, Zongyuan Shao, Shuting Zan, Effect of copper tolerant Elsholtzia splendens on bacterial community associated with Commelina communis on a copper mine spoil, Journal of Environmental Sciences, 2016, 46, 165CrossRef
  7. 7Richard Michalet, Francisco I. Pugnaire, Facilitation in communities: underlying mechanisms, community and ecosystem implications, Functional Ecology, 2016, 30, 1, 3Wiley Online Library
  8. 8Amanda R. Liczner, Diego A. Sotomayor, Alessandro Filazzola, Christopher J. Lortie, Germination response of desert annuals to shrub facilitation is species specific but not ecotypic, Journal of Plant Ecology, 2016, rtw030CrossRef
  9. 9Susana Rodríguez-Echeverría, Yudi M. Lozano, Richard D. Bardgett, Francisco Pugnaire, Influence of soil microbiota in nurse plant systems, Functional Ecology, 2016, 30, 1, 30Wiley Online Library
  10. 10Jill Kowal, Silvia Pressel, Jeffrey G. Duckett, Martin I. Bidartondo, Katie Field, Liverworts to the rescue: an investigation of their efficacy as mycorrhizal inoculum for vascular plants, Functional Ecology, 2016, 30, 6, 1014Wiley Online Library
  11. 11James F. Cahill, Jonathan A. Cale, Justine Karst, Tan Bao, Gregory J. Pec, Nadir Erbilgin, No silver bullet: different soil handling techniques are useful for different research questions, exhibit differential type I and II error rates, and are sensitive to sampling intensity, New Phytologist, 2016Wiley Online Library
  12. 12Johannes Metz, Katja Tielbörger, Richard Michalet, Spatial and temporal aridity gradients provide poor proxies for plant-plant interactions under climate change: a large-scale experiment, Functional Ecology, 2016, 30, 1, 20Wiley Online Library
  13. 13Santiago Soliveres, Fernando T. Maestre, Miguel Berdugo, Eric Allan, Scott Wilson, A missing link between facilitation and plant species coexistence: nurses benefit generally rare species more than common ones, Journal of Ecology, 2015, 103, 5, 1183Wiley Online Library
  14. 14S. Hortal, F. Bastida, J.L. Moreno, C. Armas, C. García, F.I. Pugnaire, Benefactor and allelopathic shrub species have different effects on the soil microbial community along an environmental severity gradient, Soil Biology and Biochemistry, 2015, 88, 48CrossRef
  15. 15Teresa E. Gimeno, Adrián Escudero, Fernando Valladares, Different intra- and interspecific facilitation mechanisms between two Mediterranean trees under a climate change scenario, Oecologia, 2015, 177, 1, 159CrossRef
  16. 16Richard Michalet, Rob W. Brooker, Christopher J. Lortie, Jean-Paul Maalouf, Francisco I. Pugnaire, Disentangling direct and indirect effects of a legume shrub on its understorey community, Oikos, 2015, 124, 9, 1251Wiley Online Library
  17. 17Marco A. Molina-Montenegro, Rómulo Oses, Cristian Torres-Díaz, Cristian Atala, Martín A. Núñez, Cristina Armas, Fungal endophytes associated with roots of nurse cushion species have positive effects on native and invasive beneficiary plants in an alpine ecosystem, Perspectives in Plant Ecology, Evolution and Systematics, 2015, 17, 3, 218CrossRef
  18. 18Laura Felice, Nicholas R. Jordan, Ruth Dill-Macky, Craig C. Sheaffer, Laura Aldrich-Wolfe, Sheri C. Huerd, Linda L. Kinkel, Soil Streptomyces communities in a prairie establishment reflect interactions between soil edaphic characteristics and plant host, Plant and Soil, 2015, 386, 1-2, 89CrossRef
  19. 19Yudi M. Lozano, Sara Hortal, Cristina Armas, Francisco I. Pugnaire, Interactions among soil, plants, and microorganisms drive secondary succession in a dry environment, Soil Biology and Biochemistry, 2014, 78, 298CrossRef