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Title: Effects of hypoxia and acidification on Calanus pacificus: behavioral changes in response to stressful environments

Copepods, which play major roles in marine food webs and biogeochemical cycling, frequently undergo diel vertical migration (DVM), swimming downwards during the day to avoid visual predation and upwards at night to feed. Natural water columns that are stratified with chemical stressors at depth, such as hypoxia and acidification, are increasing with climate change. Understanding behavioral responses of copepods to these stresses—in particular, whether copepods alter their natural migration—is important to anticipating impacts of climate change on marine ecosystems. We conducted laboratory experiments using stratified water columns to measure the effects of bottom water hypoxia and pH on mortality, distribution, and swimming behaviors of the calanoid copepodCalanuspacificus. When exposed to hypoxic (0.65 mg O2l-1) bottom waters, the height ofC.pacificusfrom the bottom increased 20% within hypoxic columns, and swimming speed decreased 46% at the bottom of hypoxic columns and increased 12% above hypoxic waters. When exposed to low pH (7.48) bottom waters, swimming speeds decreased by 8 and 9% at the base of the tanks and above acidic waters, respectively. Additionally, we found a 118% increase in ‘moribund’ (immobile on the bottom) copepods when exposed to hypoxic, but not acidic, bottom waters. Some swimming statistics differed between copepods collected from sites with versus without historical hypoxia and acidity. Observed responses suggest potential mechanisms underlyinginsituchanges in copepod population distributions when exposed to chemical stressors at depth.

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Award ID(s):
1657992
NSF-PAR ID:
10494456
Author(s) / Creator(s):
; ;
Publisher / Repository:
Marine Ecology Progress Series
Date Published:
Journal Name:
Marine Ecology Progress Series
Volume:
697
ISSN:
0171-8630
Page Range / eLocation ID:
15 to 29
Format(s):
Medium: X
Sponsoring Org:
National Science Foundation
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