4.3 Article

Responses to elevated CO2 exposure in a freshwater mussel, Fusconaia flava

Publisher

SPRINGER HEIDELBERG
DOI: 10.1007/s00360-016-1023-z

Keywords

Chitin synthase; Heat shock protein 70; Metabolic rate; Bivalve

Funding

  1. Illinois Department of Natural Resources
  2. United States Geological Survey through United States Environmental Protection Agency's Great Lakes Restoration Initiative
  3. USFWS Federal Aid in Sport Fish Restoration Project [F-69-R]
  4. USDA National Institute of Food and Agriculture Hatch project [ILLU-875-947]

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Freshwater mussels are some of the most imperiled species in North America and are particularly susceptible to environmental change. One environmental disturbance that mussels may encounter that remains understudied is an increase in the partial pressure of CO2 (pCO(2)). The present study quantified the impacts of acute (6 h) and chronic (up to 32 days) exposures to elevated pCO(2) on genes associated with shell formation (chitin synthase; cs) and the stress response (heat shock protein 70; hsp70) in Fusconaia flava. Oxygen consumption (MO2) was also assessed over the chronic CO2 exposure period. Although mussels exhibited an increase in cs following an acute exposure to elevated pCO(2), long-term exposure resulted in a decrease in cs mRNA abundance, suggesting that mussels may invest less in shell formation during chronic exposure to elevated pCO(2). In response to an acute elevation in pCO(2), mussels increased hsp70 mRNA abundance in mantle and adductor muscle and a similar increase was observed in the gill and adductor muscle in response to a chronic elevation in pCO(2). A chronic elevation in pCO(2) also increased mussel MO2. This overall increase in hsp70 mRNA levels and MO2 in F. flava indicates that exposure to elevated pCO(2) initiates activation of the general stress response and an increased energy demand. Together, the results of the present study suggest that freshwater mussels respond to elevated pCO(2) by increasing processes necessary to 'deal with' the stressor and, over the long-term, may reduce their investment in non-essential processes such as shell growth.

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