Ocean acidification is a consequence of rapidly increasing atmospheric levels of carbon
dioxide and, in tandem with increasing sea temperature, poses a significant threat to marine
life. A series of mesocosm experiments have been conducted at the Plymouth Marine
Laboratory (Plymouth, UK) and the Kings Bay Marine Laboratory (Ny-Alesund, Svalbard)
where ophiuroid brittlestars were used as a model to investigate the physiological response
of marine organisms to ocean acidification and ocean warming. A 'whole organism'
approach was adopted to elucidate the primary physiological responses, trade offs and
conflicts that occurred. Three ophiuroid species of differing lifestyle and habitats were
chosen to give an insight into how such factors influenced a species' response to ocean
acidification and warming; the infaunal Amphiura filiformis, the epibenthic Ophiura
ophiura, both temperate, and the Arctic epibenthic Ophiocten sericeum. There was a
similar physiological response of metabolic upregulation across all three species. All
species survived the lowest pH exposures (6.8 for A. filiformis, 7.3 for 0. ophiura and 0.
sericeum) and showed signs of synergy between increasing water temperature and ocean
acidification with the effects of lowered pH amplified as temperature increased. Beyond
this, whilst specific responses differed between species, some similarity was observed
between the epibenthic species 0. ophiura and 0. sericeum which both reduced arm
regeneration and motility at lowered pH. In contrast, A. filiformis increased arm
regeneration and suffered arm muscle wastage that appeared unsustainable. Differences in
response and long term vulnerability to ocean acidification related to lifestyle (infaunal
versus epibenthic) were consolidated by the Energy Limitation Model whereby the
response of a species to ocean acidification is based on the increased cost of maintaining
the acid-base balance of extracellular fluids. The ability to do this, and where the energy is
taken from to do so, rationalises the variety of physiological responses seen between
species. The results of the investigations described in this thesis indicate that even species
with low regulatory capacity may survive ocean acidification. However, lifestyle may have
a determining role in where energy trade offs are made to maintain acid-base balance and
this may ultimately determine species survival.
Date of Award | 2009 |
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Original language | English |
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Awarding Institution | |
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Assessing the impact of increasing seawater temperature and acidity on marine organisms using ophiuroid brittlestars as an experimental model
Wood, H. L. (Author). 2009
Student thesis: PhD