Transient species driving ecosystem multifunctionality: Insights from competitive interactions between rocky intertidal mussels

• Published in: Marine environmental research Vol. 196; p. 106422
• Main Authors: Betancourtt, Claudia, Catalán, Alexis M., Morales-Torres, Diego F., Lopez, Daniela N., Escares-Aguilera, Valentina, Salas-Yanquin, Luis P., Büchner-Miranda, Joseline A., Chaparro, Oscar R., Nimptsch, Jorge, Broitman, Bernardo R., Valdivia, Nelson
• Format: Journal Article
• Language: English
• Published: England Elsevier Ltd 01.04.2024
• Subjects: BEF research; Biodiversity; Dominance; Ecosystem functioning; Physiological variables; Species identity; Physiological variables; BEF research; Dominance; Species identity; Ecosystem functioning; Biodiversity
• ISSN: 0141-1136; 1879-0291
• DOI: 10.1016/j.marenvres.2024.106422

Anthropogenic biodiversity loss poses a significant threat to ecosystem functioning worldwide. Numerically dominant and locally rare (i.e., transient) species are key components of biodiversity, but their contribution to multiple ecosystem functions (i.e., multifunctionality) has been seldomly assessed in marine ecosystems. To fill this gap, here we analyze the effects of a dominant and a transient species on ecosystem multifunctionality. In an observational study conducted along ca. 200 km of the southeastern Pacific coast, the purple mussel Perumytilus purpuratus numerically dominated the mid-intertidal and the dwarf mussel Semimytilus patagonicus exhibited low abundances but higher recruitment rates. In laboratory experiments, the relative abundances of both species were manipulated to simulate the replacement of P. purpuratus by S. patagonicus and five proxies for ecosystem functions—rates of clearance, oxygen consumption, total biodeposit, organic biodeposit, and excretion—were analyzed. This replacement had a positive, linear, and significant effect on the combined ecosystem functions, particularly oxygen consumption and excretion rates. Accordingly, S. patagonicus could well drive ecosystem functioning given favorable environmental conditions for its recovery from rarity. Our study highlights therefore the key role of transient species for ecosystem performance. Improving our understanding of these dynamics is crucial for effective ecosystem conservation, especially in the current scenario of biological extinctions and invasions. •Turnover of a numerically dominant by a transient mussel increased ecosystem multifunctionality.•Multifunctionality was assessed as rates of clearance rate, oxygen consumption rate, total and organic biodeposit, and excretion rate.•Understanding these dynamics is essential for effective ecosystem conservation.