Global mycorrhizal fungal range sizes vary within and among mycorrhizal guilds but are not correlated with dispersal traits

Kivlin, Stephanie N.

doi:10.1111/jbi.13866

Cited by 28 publications

(31 citation statements)

References 64 publications

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“…Notwithstanding the above, there are reasons why codependency may be counterintuitive: AM fungi are globally distributed (Davison et al ., 2015; but see Bruns & Taylor, 2016) and most AM fungi do not appear to suffer dispersal limitations (Correia et al ., 2019; Kivlin, 2020). If every fungus has the opportunity to occur in every habitat, regardless of plant community identity, specific associations may be less common. The Glomeromycota have significantly fewer taxa than their hosts (<1000 AMF species vs 391 000 plant species) making it improbable that plants develop strict specificity with fungal partners. AM fungi are obligate biotrophs.…”

Section: Should We Expect Codependency Among Am Communities?mentioning

confidence: 99%

Codependency between plant and arbuscular mycorrhizal fungal communities: what is the evidence?

et al. 2020

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828 I. What is codependency and why should we care? 829 II. Should we expect codependency among AM communities? 830 III. Requirements for codependency 830 IV. When and where has codependency been observed? 831 V. Is codependency scale-and resolution-dependent? 831 VI. Unexplained variation: if not codependency then what? 834 VII Recommendations for future studies 834 VIII. Conclusion 835 Acknowledgements 835 References 835

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Section: Should We Expect Codependency Among Am Communities?mentioning

confidence: 99%

Codependency between plant and arbuscular mycorrhizal fungal communities: what is the evidence?

et al. 2020

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“…Additionally, different study taxa are likely to yield variable distance–decay relationships because they differ in traits that are linked to dispersal efficacy. For example, small cells disperse more efficiently over long distances (Norros et al., 2014; Wilkinson, 2001; Wilkinson et al., 2012), meaning that organisms with larger cell sizes, such as microbial Eukarya, should be more strongly dispersal limited than those with small cell sizes, such as Bacteria (although this might not be true for all taxa, e.g., see Kivlin, 2020). Finally, it is known that spatial extent can influence our perception of ecological relationships, which might contribute to variable distance–decay relationships (Steinbauer et al., 2012).…”

Section: Introductionmentioning

confidence: 99%

What drives study‐dependent differences in distance–decay relationships of microbial communities?

Clark

Underwood

McGenity

et al. 2021

Global Ecol. Biogeogr.

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Aim Ecological communities that exist closer together in space are generally more compositionally similar than those far apart, as defined by the distance–decay of similarity relationship. However, recent research has revealed substantial variability in the distance–decay relationships of microbial communities between studies of different taxonomic groups, ecosystems and spatial scales and between those using different molecular methodologies (e.g., high‐throughput sequencing versus molecular fingerprinting). Here, we test how these factors influence the strength of microbial distance–decay relationships, in order to draw generalizations about how microbial β‐diversity scales with space. Location Global. Time period Studies published between 2005 and 2019 (inclusive). Major taxa studied Bacteria, Archaea and microbial Eukarya. Methods We conducted a meta‐analysis of microbial distance–decay relationships, using the Mantel correlation coefficient as a measure of the strength of distance–decay relationships. Our final dataset consisted of 452 data points, varying in environmental/ecological context or methodological approaches, and we used linear models to test the effects of each variable. Results Both ecological and methodological factors had significant impacts on the strength of microbial distance–decay relationships. Specifically, the strength of these relationships varied between environments and habitats, with soils showing significantly weaker distance–decay relationships than other habitats, whereas increasing spatial extents had no effect. Methodological factors, such as sequencing depth, were positively related to the strength of distance–decay relationships, and choice of dissimilarity metric was also important, with phylogenetic metrics generally giving weaker distance–decay relationships than binary or abundance‐based indices. Main conclusions We conclude that widely studied microbial biogeographical patterns, such as the distance–decay relationship, vary by ecological context but are primarily distorted by methodological choices. Consequently, we suggest that by linking methodological approaches appropriately to the ecological context of a study, we can progress towards generalizable biogeographical relationships in microbial ecology.

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“…We found no correlation either between spore size and level of endemism ( Supplementary Fig. 26), suggesting that even AMF with large spores can experience long-distance dispersal 60,62 . Large spores might limit dispersal at smaller (e.g.…”

Section: Resultsmentioning

confidence: 86%

“…Finally, although spore size is often inversely related to dispersal capacity [87], which can either promote diversification by favoring founder speciation events, or limit diversification by increasing gene flow, we found no significant correlation between spore size and diversification rates, which may be explained either by a weak or absent effect or by the low number of species for which this data is available. In addition, the absence of correlation between spore size and level of endemism suggests that even AMF with large spores experience long-distance dispersal [57, 88]. Thus, if large spores might limit dispersal at smaller (e.g.…”

Section: Discussionmentioning

confidence: 99%

Global drivers of obligate mycorrhizal symbionts diversification

Perez‐Lamarque

Öpik

Maliet

et al. 2020

Preprint

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Arbuscular mycorrhizal fungi (AMF) are widespread microfungi that provide mineral nutrients to most land plants and form one of the oldest terrestrial symbioses. They have often been referred to as an “evolutionary cul-de-sac” for their limited ecological and species diversity. Here we use a global database of AMF to analyze their diversification dynamics in the past 500 million years (Myr). We find that AMF have low diversification rates. After a diversification peak around 150 Myr ago, they experienced an important diversification slowdown in the last 100 Myr, likely related to a shrinking of their suitable ecological niches. Our results clarify patterns and drivers of diversification in a group of obligate symbionts of major ecological and evolutionary importance. They also highlight a striking example of a diversification slowdown that, instead of reflecting an adaptive radiation as typically assumed, results from a limited ability to colonize new niches in an evolutionary cul-de-sac.

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Global mycorrhizal fungal range sizes vary within and among mycorrhizal guilds but are not correlated with dispersal traits

Cited by 28 publications

References 64 publications

Codependency between plant and arbuscular mycorrhizal fungal communities: what is the evidence?

Codependency between plant and arbuscular mycorrhizal fungal communities: what is the evidence?

What drives study‐dependent differences in distance–decay relationships of microbial communities?

Global drivers of obligate mycorrhizal symbionts diversification

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