AI Article Synopsis
- Coastal ecosystems are facing challenges from rising sea temperatures and expanding low-oxygen (hypoxic) areas, affecting the respiratory responses of bivalve species.
- The study examined two bivalve species, Pecten maximus and Mytilus spp., in different coastal habitats, finding that Mytilus spp. tolerated temperature increases better than P. maximus, which struggled at 25°C.
- P. maximus had superior oxyregulation abilities under hypoxic conditions, but both species showed decreased performance at higher temperatures, indicating that subtidal species may be more at risk from heat and low oxygen than intertidal ones like Mytilus spp.
Article Abstract
Coastal ecosystems are increasingly disturbed by the increase of mean sea surface temperature and expansion of hypoxic areas. The objectives of the present work were to describe and compare the respiratory responses to combined heat and hypoxia in two bivalve species (Pecten maximus and Mytilus spp.) living in two contrasted coastal habitats (subtidal and intertidal, respectively). Results were consistent with the vertical zonation of both species. Mytilus spp. seemed to cope better with a temperature increase than P. maximus, which was found to be outside of its optimal thermal window at 25°C. Concerning respiratory responses to hypoxia at a given temperature, P. maximus displayed greater oxyregulation capacity that was maintained over a larger range of O2 levels, as compared to Mytilus spp. When acclimation temperatures increased, both species showed a decrease in their oxyregulation capacities alongside a reduction in aerobic performance, especially in P. maximus. The comparison between species suggests that subtidal species, such as P. maximus, might be more vulnerable to a combination of heat and hypoxia than intertidal species, such as Mytilus spp. Lastly, this study highlighted the utility of segmented linear models to estimate PcO2 and regulation percentages in marine organisms exposed to hypoxia.
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| http://dx.doi.org/10.1016/j.cbpa.2014.06.005 | DOI Listing |
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