Multi-generational Responses of a Marine Polychaete to a Rapid Change in Seawater CO

Overview

Journal Evol Appl

Specialty Biology

Date 2016 Oct 4

PMID 27695517

Citations 20

Authors

Araceli Rodriguez-Romero

Michael D Jarrold

Gloria Massamba-NSiala

John I Spicer

Piero Calosi

Affiliations

Soon will be listed here.

Abstract

Little is known of the capacity that marine metazoans have to evolve under rapid CO changes. Consequently, we reared a marine polychaete, , previously cultured for approximately 33 generations under a low/variable pH regime, under elevated and low CO for six generations. The strain used was found to be tolerant to elevated CO conditions. In generations F1 and F2 females' fecundity was significantly lower in the low CO treatment. However, from generation F3 onwards there were no differences between CO treatments, indicating that trans-generational effects enabled the restoration and maintenance of reproductive output. Whilst the initial fitness recovery was likely driven by trans-generational plasticity (TGP), the results from reciprocal transplant assays, performed using F7 individuals, made it difficult to disentangle between whether TGP had persisted across multiple generations, or if evolutionary adaptation had occurred. Nonetheless, both are important mechanisms for persistence under climate change. Overall, our study highlights the importance of multi-generational experiments in more accurately determining marine metazoans' responses to changes in CO , and strengthens the case for exploring their use in conservation, by creating specific CO tolerant strains of keystone ecosystem species.

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