Promoting pinto abalone (Haliotis kamtschatkana) recovery in the Salish Sea: The effects of fluctuating temperature and elevated CO2 on survival, growth, and radula morphology
Overharvesting of pinto abalone (Haliotis kamtschatkana) in the Salish Sea between 1959 and 1994 caused severe population declines. This led to the Washington Department of Fish and Wildlife classifying pinto abalone as a “species of concern.” The Puget Sound Restoration Fund (PSRF) is committed to...
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| Format: | Text |
| Language: | English |
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Western CEDAR
2022
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| Online Access: | https://cedar.wwu.edu/wwuet/1142 https://cedar.wwu.edu/cgi/viewcontent.cgi?article=2176&context=wwuet |
| Summary: | Overharvesting of pinto abalone (Haliotis kamtschatkana) in the Salish Sea between 1959 and 1994 caused severe population declines. This led to the Washington Department of Fish and Wildlife classifying pinto abalone as a “species of concern.” The Puget Sound Restoration Fund (PSRF) is committed to help pinto abalone recover by outplanting juveniles at specific sites around the Salish Sea. Survival of outplanted individuals is different at each site, but it is not clear why. Differences in water chemistry parameters, such as temperature and pH, could explain the differences in survival, either through differences in the mean conditions or through short term exposure to more extreme conditions. Future ocean warming and acidification could make fluctuations in water chemistry parameters more severe. The goal of my thesis was to simulate in lab the outplanting of abalone post-sets in fluctuating temperature and elevated CO2 conditions. I utilized an ocean acidification system to create atmospheres that affect seawater pH. I hypothesized that temperature fluctuations and high dissolved CO2 (low pH) will negatively affect survival, growth, and shell and radula morphology. Fluctuating temperatures yielded lower survival and greater growth, determined by mean shell length, compared to constant temperature. High CO2 yielded comparable survival and smaller growth than low CO2. Traditional morphological analysis of the radula found that fluctuating temperatures caused the radula to grow in a more compact manner, with smaller teeth formed closer together. Geometric morphological analysis found that radula tooth orientation was not affected by any of the treatments. This is the first study to find any effects of water chemistry on abalone radula morphology. Overall, the presence of a single stressor was detrimental to pinto abalone post-sets. However, the combination of stressors performed similarly to the absence of stressors. This indicates that fluctuating temperature can mitigate the negative effects of high CO2, ... |
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