Can niche plasticity mediate species persistence under ocean acidification?

Global change stressors can modify ecological niches of species, thereby altering ecological interactions within communities and food webs. Yet, some species might take advantage of a fast‐changing environment, allowing species with high niche plasticity to thrive under climate change. We used natur...

Full description

Bibliographic Details
Published in:Journal of Animal Ecology
Main Authors: Cipriani, Vittoria, Goldenberg, Silvan U., Connell, Sean D., Ravasi, Timothy, Nagelkerken, Ivan
Format: Article in Journal/Newspaper
Language:English
Published: Wiley 2024
Subjects:
Online Access:https://oceanrep.geomar.de/id/eprint/60667/
https://oceanrep.geomar.de/id/eprint/60667/1/Journal%20of%20Animal%20Ecology%20-%202024%20-%20Cipriani%20-%20Can%20niche%20plasticity%20mediate%20species%20persistence%20under%20ocean%20acidification.pdf
https://doi.org/10.1111/1365-2656.14163
Description
Summary:Global change stressors can modify ecological niches of species, thereby altering ecological interactions within communities and food webs. Yet, some species might take advantage of a fast‐changing environment, allowing species with high niche plasticity to thrive under climate change. We used natural CO 2 vents to test the effects of ocean acidification on niche modifications of a temperate rocky reef fish assemblage. We quantified three ecological niche traits (overlap, shift and breadth) across three key niche dimensions (trophic, habitat and behavioural). Only one species increased its niche width along multiple niche dimensions (trophic and behavioural), shifted its niche in the remaining (habitat) was the only species to experience a highly increased density (i.e. doubling) at vents. The other three species that showed slightly increased or declining densities at vents only displayed a niche width increase in one (habitat niche) out of seven niche metrics considered. This niche modification was likely in response to habitat simplification (transition to a system dominated by turf algae) under ocean acidification. We further showed that, at the vents, the less abundant fishes had a negligible competitive impact on the most abundant and common species. This species appeared to expand its niche space, overlapping with other species, which likely led to lower abundances of the latter under elevated CO 2 . We conclude that niche plasticity across multiple dimensions could be a potential adaptation in fishes to benefit from a changing environment in a high‐CO 2 world.