Setting the stage for plant–soil feedback: Mycorrhizal influences over conspecific recruitment, plant and fungal communities, and coevolution

Author:

Eagar Andrew C.1ORCID,Abu Princess H.1ORCID,Brown Megan A.1ORCID,Moledor Sara M.1ORCID,Smemo Kurt A.2ORCID,Phillips Richard P.3ORCID,Case Andrea L.1ORCID,Blackwood Christopher B.14ORCID

Affiliation:

1. Department of Plant Biology Michigan State University East Lansing Michigan USA

2. Environmental Studies and Science Program Skidmore College Saratoga Springs New York USA

3. Department of Biology Indiana University Bloomington Indiana USA

4. Department of Plant, Soil, and Microbial Sciences Michigan State University East Lansing Michigan USA

Abstract

Abstract Plant–soil feedback (PSF) plays a central role in determining plant community dynamics, yet our understanding of how different combinations of plants and microbes influence PSF remains limited. Plants of different mycorrhizal types often exhibit contrasting PSF outcomes, influencing plant recruitment and spatial structure. Generalizing across plant species based on mycorrhizal type creates the potential to examine broader effects on ecological communities. We review mechanisms contributing to different PSF outcomes between arbuscular mycorrhizal and ectomycorrhizal trees. We focus on how plant and fungal traits that differ between mycorrhizal types interact with pathogenic and saprotrophic microorganisms and nutrient and carbon cycling. Synthesis. Building on this framework, we propose several new research directions. First, mycorrhizal‐induced changes in soils can operate beyond the conspecific level, spilling over from abundant plant species onto less abundant ones. This community‐level ‘mycorrhizal spillover’ is hypothesized to affect PSF in ways that are additive and interactive with conspecific density dependence. Second, we describe how mycorrhizal effects on PSF could structure the way plant communities respond to global change. Third, we discuss how they may influence plant evolution by altering the balance of selection pressures on traits and genes related to pathogen defence and mutualism formation.

Funder

Division of Environmental Biology

Publisher

Wiley

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