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The Energetic Demand of Low Tide Stress on Balanus glandula Under Varying Thermal Conditions

Like all intertidal species, the barnacle Balanus glandula must cope with temperature and desiccation stress during daily low tide exposure. The increase in temperature at low tide leads to both increased metabolic rate and the potential for increased ATP demand. With its additional inhibition of oxygen intake, low tide thus has an energetic cost that is often reflected in an increase in oxygen consumption following resubmersion. As anthropogenically induced global climate change increases air and water temperatures, its cost might increase. B. glandula individuals were exposed to 4‑hour low tides with maximal temperatures of 18, 30, 35, and 38°C, and their oxygen consumption rates and behaviors were recorded for 4 hours upon resubmersion. It was found that aerial respiration could be measured, though aerial rates were only a fraction of aquatic rates. It was further found that relative aquatic oxygen consumption rates were not elevated following low tide for any temperatures. However, B. glandula individuals exposed to 35 and 38°C low tides remained active a significantly greater portion of time through the first and second hours of recovery, respectively. This indicates that a low tide stress effect is evident in B. glandula, but that it manifests not as an increase in the respiration rate when active, but rather as an increase in the overall activity time. Thus, with increasing global temperatures B. glandula will likely have increased energy needs. This might lead to range relocations, a drive to find new energy sources, and/or reallocations of energy budgets.

Identiferoai:union.ndltd.org:CLAREMONT/oai:scholarship.claremont.edu:scripps_theses-1150
Date01 January 2012
CreatorsHendrix, Alicia M
PublisherScholarship @ Claremont
Source SetsClaremont Colleges
Detected LanguageEnglish
Typetext
Formatapplication/pdf
SourceScripps Senior Theses
Rights© 2012 Alicia M. Hendrix, default

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