Changing patterns of growth in a changing planet: how a shift in phenology affects critical life‐history traits in annual fishes

Garcia, D, Smith, C ORCID logoORCID: https://orcid.org/0000-0003-3285-0379, Machín, E, Loureiro, M and Reichard, M, 2019. Changing patterns of growth in a changing planet: how a shift in phenology affects critical life‐history traits in annual fishes. Freshwater Biology, 64 (10), pp. 1848-1858. ISSN 0046-5070

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Abstract

1. Changes to the timing of key life‐cycle events can alter selection on life‐history traits and have the potential to drive a cascade of effects at the community level. We investigated how the growth rate and sexual maturation of two annual killifish species (Austrolebias bellottii and Austrolebias nigripinnis) were altered by a change in the pattern of precipitation. These are annual species, endemic to ephemeral pools, persist in desiccated sediment as partly developed embryos.

2. We sampled 18 pools supporting populations of both species in a Pampa region adjacent to the Rio Negro in western Uruguay throughout the austral winter of 2015. Fish growth and maturation were monitored from pool inundation to habitat desiccation, along with environmental variables.

3. The region experienced an unprecedented mid‐winter desiccation of pools that usually contain water from autumn to late spring, typically only desiccating in summer. Many desiccated pools were re‐inundated from later rains, generating a second cohort of killifish in some pools (53%) in response to atypical conditions.

4. The second cohort developed more rapidly than the first, with 40% earlier attainment of asymptotic body size. Rapid development of second‐cohort fish was associated with earlier maturation and greater investment in reproductive tissue.

5. The study demonstrated the capacity of annual fish to express developmental plasticity that buffered the negative consequences of an atypical seasonal climatic cycle. The capacity of these annual fishes to cope with alternations to their life cycle will depend on the ability of egg banks in the sediment to tolerate an increased unpredictability of precipitation.
6. Overall, we demonstrate how phenotypic plasticity can mitigate the negative impacts of climate change and associated altered phenology.

Item Type: Journal article
Publication Title: Freshwater Biology
Creators: Garcia, D., Smith, C., Machín, E., Loureiro, M. and Reichard, M.
Publisher: Wiley-Blackwell
Date: October 2019
Volume: 64
Number: 10
ISSN: 0046-5070
Identifiers:
Number
Type
10.1111/fwb.13376
DOI
1114688
Other
Divisions: Schools > School of Animal, Rural and Environmental Sciences
Record created by: Jonathan Gallacher
Date Added: 21 Aug 2019 09:47
Last Modified: 21 Jul 2021 14:52
URI: https://irep.ntu.ac.uk/id/eprint/37399

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