Microbial Dormancy Supports Multi‐Species Coexistence Under Resource Fluctuations

ABSTRACT The ability for microbes to enter dormant states is adaptive under resource fluctuations and has been linked to the maintenance of diversity. Nevertheless, the mechanism by which microbial dormancy gives rise to the density‐dependent feedbacks required for stable coexistence under resource...

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Bibliographic Details
Published in:Ecology letters 2024-09, Vol.27 (9), p.e14507-n/a
Main Authors: Letten, Andrew D., Yamamichi, Masato, Richardson, James A., Ke, Po‐Ju
Format: Article
Language:English
Subjects:
Biodiversity
Coexistence
Dormancy
Ecosystem
Fluctuations
Frequency dependence
Microbial Interactions
Microorganisms
Models, Biological
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Summary:ABSTRACT The ability for microbes to enter dormant states is adaptive under resource fluctuations and has been linked to the maintenance of diversity. Nevertheless, the mechanism by which microbial dormancy gives rise to the density‐dependent feedbacks required for stable coexistence under resource fluctuations is not well understood. Via analysis of consumer‐resource models, we show that the stable coexistence of dormancy and non‐dormancy strategists is a consequence of the former benefiting more from resource fluctuations while simultaneously reducing overall resource variability, which sets up the requisite negative frequency dependence. Moreover, we find that dormants can coexist alongside gleaner and opportunist strategies in a competitive‐exclusion‐defying case of three species coexistence on a single resource. This multi‐species coexistence is typically characterised by non‐simple assembly rules that cannot be predicted from pairwise competition outcomes. The diversity maintained via this three‐way trade‐off represents a novel phenomenon that is ripe for further theoretical and empirical inquiry. The mechanism by which microbial dormancy gives rise to the density‐dependent feedbacks required for stable coexistence under resource fluctuations is not well understood. We show that the stable coexistence of dormancy and non‐dormancy strategists can emerge via relative nonlinearity of competition and that dormants can coexist alongside gleaner and opportunist strategies in a case of three species coexistence on a single resource. This novel phenomenon is ripe for further theoretical and empirical inquiry.
ISSN:1461-023X
1461-0248
1461-0248
DOI:10.1111/ele.14507