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Elevated CO2 and temperature increase arbuscular mycorrhizal fungal diversity, but decrease root col

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Elevated CO2 and temperature increase arbuscular mycorrhizal fungal diversity, but decrease root colonization, in maize and wheat
第一作者: Liu, Zihao
英文第一作者: Liu, Zihao
联系作者: Adams, Jonathan M.;Yu, Zhenhua
英文联系作者: Adams, Jonathan M.;Yu, Zhenhua
发表年度: 2023
卷: 873
摘要: Anthropogenic climate change threatens ecosystem multifunctionality. Arbuscular mycorrhizal (AM) fungi are impor-tant symbionts that participate in mediating many ecosystem processes, and thus being potentially essential link in the chain of responses to climate change. Yet, how climate change affect the abundance and community structure of AM fungi associated with different crops remains elusive. Here, we investigated the changes in rhizosphere AM fungal communities and growth performance of maize and wheat grown in Mollisols under experimentally elevated CO2 (eCO2, +300 ppm), temperature (eT, +2 degrees C) and both in-combination (eCT) with open-top chambers, representing a scenario likely to occur by this century's end. The results showed that eCT significantly shifted AM fungal communi-ties in both rhizospheres compared with control, but with no remarkable variation of the overall communities in maize rhizosphere, suggesting their greater resistance to climate change. Both eCO2 and eT increased rhizosphere AM fungal diversity, and conversely they reduced mycorrhizal colonization of both crops, probably since AM fungi had distinct adaptive strategies to climate change in rhizospheres (i.e., r-strategy) and roots (K-strategy), while the colonization in-tensity positively correlated with a decreased phosphorus (P)-uptake in two crops. Furthermore, co-occurrence net-work analysis showed that eCO2 strongly decreased the modularity and betweenness centrality of network structure than that of eT and eCT in both rhizospheres, along with the reduced network robustness, implied their destabilized communities under eCO2, while root stoichiometry (C:N and C:P ratio) was the most important factor associating with taxa in networks regardless of climate change. Overall, those findings suggest that rhizosphere AM fungal com-munities in wheat appear to be more sensitive to climate change than that in maize, further highlighting the impor-tance of effective monitoring and managing AM fungi, which may allow crops to maintain critical levels of mineral nutrients (at least P) under future global change.
刊物名称: SCIENCE OF THE TOTAL ENVIRONMENT
参与作者: Liu,ZH(Liu,Zihao)[1];Yu,ZH(Yu,Zhenhua)[2];Song,B(Song,Bin)[1];Li,YS(Li,Yansheng)[2];Fang,J(Fang,Jie)[1];Guo,YP(Guo,Yaping)[1];Jin,J(Jin,Jian)[2];Adams,JM(Adams,JonathanM.)[1]



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