Nancy Collins Johnson1, Gail W T Wilson2, Jacqueline A Wilson2, R Michael Miller3, Matthew A Bowker4. 1. School of Earth Sciences and Environmental Sustainability and Department of Biological Sciences, Northern Arizona University Flagstaff, Flagstaff, AZ, 86011, USA. 2. Natural Resource Ecology & Management, Oklahoma State University, Stillwater, OK, 74077, USA. 3. Biosciences Division, Argonne National Laboratory, Argonne, IL, 60439, USA. 4. School of Forestry, Northern Arizona University, Flagstaff, AZ, 86011, USA.
Abstract
Mycorrhizal phenotypes arise from interactions among plant and fungal genotypes and the environment. Differences in the stoichiometry and uptake capacity of fungi and plants make arbuscular mycorrhizal (AM) fungi inherently more nitrogen (N) limited and less phosphorus (P) limited than their host plants. Mutualistic phenotypes are most likely in P-limited systems and commensal or parasitic phenotypes in N-limited systems. Carbon (C) limitation is expected to cause phenotypes to shift from mutualism to commensalism and even parasitism. Two experiments compared the influence of fertilizer and shade on mycorrhizas in Andropogon gerardii across three naturally N-limited or P-limited grasslands. A third experiment examined the interactive effects of N and P enrichment and shade on A. gerardii mycorrhizas. Our experiments generated the full spectrum of mycorrhizal phenotypes. These findings support the hypothesis that mutualism is likely in P-limited systems and commensalism or parasitism is likely in N-limited systems. Furthermore, shade decreased C-assimilation and generated less mutualistic mycorrhizal phenotypes with reduced plant and fungal biomass. Soil fertility is a key controller of mycorrhizal costs and benefits and the Law of the Minimum is a useful predictor of mycorrhizal phenotype. In our experimental grasslands arbuscular mycorrhizas can ameliorate P-limitation but not N-limitation.
Mycorrhizal phenotypes arise from interactions among plant and fungal genotypes and the environment. Differences in the stoichiometry and uptake capacity of fungi and plants make arbuscular mycorrhizal (AM) fungi inherently more n class="Chemical">nitrogen (N) limited and less n class="Chemical">phosphorus (P) limited than their host plants. Mutualistic phenotypes are most likely in P-limited systems and commensal or parasitic phenotypes in N-limited systems. Carbon (C) limitation is expected to cause phenotypes to shift from mutualism to commensalism and even parasitism. Two experiments compared the influence of fertilizer and shade on mycorrhizas in Andropogon gerardii across three naturally N-limited or P-limited grasslands. A third experiment examined the interactive effects of N and P enrichment and shade on A. gerardii mycorrhizas. Our experiments generated the full spectrum of mycorrhizal phenotypes. These findings support the hypothesis that mutualism is likely in P-limited systems and commensalism or parasitism is likely in N-limited systems. Furthermore, shade decreased C-assimilation and generated less mutualistic mycorrhizal phenotypes with reduced plant and fungal biomass. Soil fertility is a key controller of mycorrhizal costs and benefits and the Law of the Minimum is a useful predictor of mycorrhizal phenotype. In our experimental grasslands arbuscular mycorrhizas can ameliorate P-limitation but not N-limitation.
Authors: Camille S Delavaux; Tessa Camenzind; Jürgen Homeier; Rosa Jiménez-Paz; Mark Ashton; Simon A Queenborough Journal: Mycorrhiza Date: 2016-12-06 Impact factor: 3.387
Authors: Katie M Becklin; Jill T Anderson; Laci M Gerhart; Susana M Wadgymar; Carolyn A Wessinger; Joy K Ward Journal: Plant Physiol Date: 2016-09-02 Impact factor: 8.340
Authors: Haiyan Ren; Weiyang Gui; Yongfei Bai; Claudia Stein; Jorge L M Rodrigues; Gail W T Wilson; Adam B Cobb; Yingjun Zhang; Gaowen Yang Journal: Mycorrhiza Date: 2017-12-14 Impact factor: 3.387