Forest growth resistance and resilience to the 2018-2020 drought depend on tree diversity and mycorrhizal type

Sachsenmaier, Lena; Schnabel, Florian; Dietrich, Peter; Eisenhauer, Nico; Ferlian, Olga; Quosh, Julius; Richter, Ronny; Wirth, Christian

doi:10.1101/2024.01.23.576797

Cited by 2 publications

(1 citation statement)

References 119 publications

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“…Further, it is remarkable that this pattern for C:N was encountered both for AM and EM tree species, which suggests that, despite the higher hostspecificity of AMF in our study site (Ferlian et al, 2021), EM trees are not only linked to AMF through dual mycorrhization (see Figure S12; Heklau et al, 2021;Teste et al, 2019), but may also benefit from AMF richness. For instance, the dual mycorrhization of EM trees might be especially beneficial during dry periods (Querejeta et al, 2009), which might explain the advantage of these trees during droughts shown in Sachsenmaier et al (2024) for our study site. Last, EMF richness did not have any significant effect on the traits studied, which suggest that even though EMF diversity can affect the uptake of nutrients (Khokon & Meier, 2023), this does not necessarily have an effect on the leaf strategy of the tree.…”

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confidence: 87%

Tree and mycorrhizal fungal diversity drive intraspecific and intraindividual trait variation in temperate forests: Evidence from a tree diversity experiment

Castro Sánchez‐Bermejo,

Monjau,

Goldmann

et al. 2024

Functional Ecology

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The study of tree species coexistence is crucial to understand the assembly of forest communities. In this context, trees adjust their traits in response to the interactions with other trees and, specifically, as a result of the competition for resources. Further, mycorrhizal fungal diversity and associations are important drivers of ecosystem functioning in forests, but their role as drivers of intraspecific trait variation has been disregarded. Here, we studied intraspecific trait variation of trees in response to tree and mycorrhizal fungal diversity. We sampled 3200 leaves from 640 trees belonging to 10 native, deciduous species in a tree diversity experiment in Central Germany. This experiment relies on the combination of gradients of tree richness and mycorrhizal associations. To handle large amounts of leaf samples, we acquired leaf‐level spectral data and used deep learning to predict values for five leaf traits from the leaf economics spectrum (LES): specific leaf area, leaf dry matter content, carbon to nitrogen ratio, carbon content and phosphorus content. For every tree, we calculated the mean value for every trait and two multi‐trait functional indices (functional richness and functional dispersion) based on values for individual leaves. Finally, we used sequencing‐based data to assess the richness of mycorrhizal fungi associated with the trees. We found that tree and mycorrhizal fungi richness had an effect on different leaf functional traits. Specifically, tree richness positively affected specific leaf area and, additionally, had a negative effect on the functional indicies, which revealed that the phenotypic diversity within the tree crown decreased with tree species richness. In addition, leaf carbon to nitrogen ratio decreased with increasing arbuscular mycorrhizal fungal richness in both arbuscular and ectomycorrhizal tree species. Finally, we did not find differences between arbuscular and ectomycorrhizal trees regarding their location within the LES. Our results suggest that trees modify their strategy in response to local tree diversity, not only by shifting trait values but also by shifting the variability intraindividually. In addition, higher mycorrhizal fungal diversity does not seem to lead to higher complementarity, but instead, tree and mycorrhizal fungi affect different aspects of leaf traits. Read the free Plain Language Summary for this article on the Journal blog.

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Section: Discussionmentioning

confidence: 87%

Tree and mycorrhizal fungal diversity drive intraspecific and intraindividual trait variation in temperate forests: Evidence from a tree diversity experiment

Castro Sánchez‐Bermejo,

Monjau,

Goldmann

et al. 2024

Functional Ecology

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Forest growth resistance and resilience to the 2018–2020 drought depend on tree diversity and mycorrhizal type

Sachsenmaier,

Schnabel,

Dietrich

et al. 2024

Journal of Ecology

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The frequency of consecutive drought years is predicted to increase due to climate change. These droughts have strong negative impacts on forest ecosystems. Mixing tree species is proposed to increase the drought resistance and resilience of tree communities. However, this promising diversity effect has not yet been investigated under extreme drought conditions and in the context of complementary mycorrhizal associations and their potential role in improving water uptake. Here, we investigate whether tree diversity promotes growth resistance and resilience to extreme drought and whether drought responses are modulated by mycorrhizal associations. We used inventory data (2015–2021) from a young tree diversity experiment in Germany, manipulating tree species richness (1, 2 and 4 species) and mycorrhizal type (communities containing arbuscular mycorrhizal [AM] or ectomycorrhizal [EM] tree species, or both). For all tree communities, we calculated basal area increment in the periods before, during and after drought and used the concepts of resistance and resilience to quantify growth responses to drought. We found strong growth declines during the extreme 2018–2020 drought for most tree communities. Contrary to our hypothesis, we did not find that tree species richness per se can buffer the negative impacts of extreme drought on tree growth. However, while for EM communities, drought resistance and resilience decreased with tree species richness, they increased for AM communities and communities comprising both mycorrhizal types. We highlight that among various mixtures of tree species, only those with mixed mycorrhizal types outperformed their respective monocultures during and after drought. Furthermore, under extreme drought, the community tends to segregate into ‘winner’ and ‘loser’ tree species in terms of diversity, indicating a possible intensification of competition. While we cannot disentangle the underlying mechanisms or clarify the role of mycorrhiza during drought, our findings suggest that mixtures of mycorrhizal types within tree communities could help safeguard forests against increasing drought frequency. Synthesis. Drought resistance and resilience of tree communities depend on tree diversity and mycorrhizal association types. Mixing tree species with diverse mycorrhizal types holds promise for forest restoration in the face of climate change.

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Forest growth resistance and resilience to the 2018-2020 drought depend on tree diversity and mycorrhizal type

Cited by 2 publications

References 119 publications

Tree and mycorrhizal fungal diversity drive intraspecific and intraindividual trait variation in temperate forests: Evidence from a tree diversity experiment

Tree and mycorrhizal fungal diversity drive intraspecific and intraindividual trait variation in temperate forests: Evidence from a tree diversity experiment

Forest growth resistance and resilience to the 2018–2020 drought depend on tree diversity and mycorrhizal type

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