Cumulative Stress Restricts Niche Filling Potential of Habitat-Forming Kelps in a Future Climate

King, NG, Wilcockson, DC, Webster, R, Smale, DA, Hoelters, LS and Moore, PJ 2017 Cumulative Stress Restricts Niche Filling Potential of Habitat-Forming Kelps in a Future Climate. Functional Ecology. https://doi.org/10.1111/1365-2435.12977

[img]
Preview
Text
King et al Funct Ecol 2017.pdf - Accepted Version
Available under License Creative Commons Attribution No Derivatives.

Download (579kB) | Preview
[img] Text
fec12977-sup-0002-TableS1-S6.docx - Supplemental Material
Available under License Creative Commons Attribution No Derivatives.

Download (22kB)
Official URL: https://doi.org/10.1111/1365-2435.12977

Abstract/Summary

Climate change is driving range contractions and local population extinctions across the globe. When this affects ecosystem engineers the vacant niches left behind are likely to alter the wider ecosystem unless a similar species can fulfil them. Here, we explore the stress physiology of two coexisting kelps undergoing opposing range shifts in the Northeast Atlantic and discuss what differences in stress physiology may mean for future niche filling. We used chlorophyll florescence (Fv/Fm) and differentiation of the Heat Shock Response (HSR) to determine the capacity of the expanding kelp, Laminaria ochroleuca, to move into the higher shore position of the retreating kelp, Laminaria digitata. We applied both single and consecutive exposures to immersed and emersed high and low temperature treatments, replicating low tide exposures experienced in summer and winter. No interspecific differences in HSR were observed which was surprising given the species’ different biogeographic distributions. However, chlorophyll florescence revealed clear differences between species with L. ochroleuca better equipped to tolerate high immersed temperatures but showed little capacity to tolerate frosts or high emersion temperatures. Many patterns observed were only apparent after consecutive exposures. Such cumulative effects have largely been overlooked in tolerance experiments on intertidal organisms despite being more representative of the stress experienced in natural habitats. We therefore suggest future experiments incorporate consecutive stress into their design. Climate change is predicted to result in fewer ground frosts and increased summer temperatures. Therefore, L. ochroleuca may be released from its summer cold limit in winter but still be prevented from moving up the shore due to desiccation in the summer. L. ochroleuca will however likely be able to move into tidal pools. Therefore, only partial niche filling by L. ochroleuca will be possible in this system as climate change advances.

Item Type: Publication - Article
Divisions: Marine Biological Association of the UK > Ocean Biology
Depositing User: Dr Dan Smale
Date made live: 16 Jan 2018 15:30
Last Modified: 09 Feb 2024 16:51
URI: https://plymsea.ac.uk/id/eprint/7522

Actions (login required)

View Item View Item