Physiological and biochemical traits correlate with differences in growth rate and temperature adaptation among groups of the eastern oyster<i>Crassostrea virginica</i>

Pernet, Fabrice; Tremblay, Réjean; Redjah, Iften; Sévigny, Jean‐Marie; Gionet, Chantal

doi:10.1242/jeb.014639

Cited by 72 publications

(51 citation statements)

References 44 publications

(70 reference statements)

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“…On the face of it, bivalves do not appear to compensate oxygen consumption rates at low temperatures, but do partially compensate at intermediate, and in some species, at high temperatures. Evidence for this can be drawn from several marine species, namely Mytilis edulis (Newell and Pye, 1970a;Widdows, 1973), Ostrea edulis (Newell et al, 1977), Crassostrea virginica (Pernet et al, 2007;Pernet et al, 2008), Perna perna (Resgalla et al, 2007), Protothaca thaca (Riascos et al, 2012) and Littorea littorea (Newell and Pye, 1970a). Similar patterns have also been observed in freshwater bivalves, namely Dreissena polymorpha (Alexander and McMahon, 2004) and Amblema plicata (Baker and Hornbach, 2001).…”

Section: Research Articlementioning

confidence: 55%

“…We are unaware of any data relating the behaviours we studied to temperature change; however, a comparison of previously published data examining the effects of temperature change on oxygen consumption from a range of bivalves is possible. Evidence from a number of marine (Newell and Pye, 1970a;Newell and Pye, 1970b;Widdows, 1973;Newell et al, 1977;Pernet et al, 2007;Resgalla et al, 2007;Pernet et al, 2008;Riascos et al, 2012) and freshwater (Hornbach et al, 1983;Baker and Hornbach, 2001;Alexander and McMahon, 2004) bivalve species indicates that bivalves compensate oxygen consumption rates at intermediate, and in some species, higher temperatures, while there is no evidence of compensation at lower temperatures. As our primary interest was the difference between summer-and winter-acclimatized mussels, we did not measure oxygen consumption rates in Table 1 for a summary of the statistical analysis.…”

Section: Discussionmentioning

confidence: 99%

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Seasonal changes in the behaviour and respiration physiology of the freshwater duck musselAnodonta anatina.

Lurman

Walter

Hoppeler

2013

Journal of Experimental Biology

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For low-energy organisms such as bivalves, the costs of thermal compensation of biological rates (synonymous with acclimation or acclimatization) may be higher than the benefits. We therefore conducted two experiments to examine the effect of seasonal temperature changes on behaviour and oxygen consumption. In the first experiment, we examined the effects of seasonal temperature changes on the freshwater bivalve Anodonta anatina, taking measurements each month for a year at the corresponding temperature for that time of year. There was no evidence for compensation of burrowing valve closure duration or frequency, or locomotory speed. In the second experiment, we compared A. anatina at summer and winter temperatures (24 and 4°C, respectively) and found no evidence for compensation of the burrowing rate, valve closure duration or frequency, or oxygen consumption rates during burrowing, immediately after valve closure or at rest. Within the experimental limits of this study, the evidence suggests that thermal compensation of biological rates is not a strategy employed by A. anatina. We argue that this is due to either a lack of evolutionary pressure to acclimatize, or evolutionary pressure to not acclimatize. Firstly, there is little incentive to increase metabolic rate to enhance predatory ability given that these are filter feeders. Secondly, maintained low energetic demand, enhanced at winter temperatures, is essential for predator avoidance, i.e. valve closure. Thus, we suggest that the costs of acclimatization outweigh the benefits in A. anatina.

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Section: Research Articlementioning

confidence: 55%

Section: Discussionmentioning

confidence: 99%

Seasonal changes in the behaviour and respiration physiology of the freshwater duck musselAnodonta anatina.

Lurman

Walter

Hoppeler

2013

Journal of Experimental Biology

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“…Intraspecific variations in membrane lipid remodeling have been reported in hard clams Mercenaria mercenaria and eastern oysters Crassostrea virginica (Pernet et al 2006(Pernet et al , 2008. For example, the phospholipid to sterol ratio in wild hard clams increased transiently with the lowering of temperature, whereas it remained constant in the selectively bred M. mercenaria var.…”

Section: Introductionmentioning

confidence: 99%

Remodeling of membrane lipids in gills of adult hard clam Mercenaria mercenaria during declining temperature

Parent¹,

Tremblay²,

Sévigny³

et al. 2008

Aquat. Biol.

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In a previous study, a major remodeling of lipids, consistent with the theory of homeoviscous adaptation, was observed in the juvenile hard clam Mercenaria mercenaria during a temperature reduction from 24 to -1°C. In addition, the lipid remodeling varied between genetically distinct lines of hard clams. The present study examined whether adult hard clams originating from different locations and a selectively bred variety show differences related to their genetic characteristics in the remodeling of lipids that normally occur during decreasing temperatures. Wild hard clams from 4 locations in Atlantic Canada and the selectively bred M. mercenaria var. notata were held at an aquaculture growout site located at the northern distribution limit of the species in the Gulf of St. Lawrence from August to December 2006. Gills were sampled monthly for lipid analyses. Hard clams from the 5 groups showed an increase in the unsaturation index, mainly attributable to 22:6n-3 and 20:5n-3 as temperature decreased during the fall, followed by an increase in the phospholipid to sterol ratio in December. Although hard clams from the wild showed a lower unsaturation index than the selectively bred clams, there was no effect of location on the lipid remodeling. This result coincided with low genetic differentiation among hard clams from the 5 groups. Interestingly, the levels of 20:5n-3, 20:4n-6 and 22:6n-3 -3 fatty acids obtained from the diet -were generally lower in the environment compared to the levels in hard clams, thus suggesting some mechanisms for the selective incorporation of these fatty acids in hard clams.

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“…In general, oxygen consumption in a range of marine and freshwater bivalves exhibits no thermal compensation at low to intermediate temperatures and only minimal evidence of compensation at intermediate to high temperatures characteristic of their natural thermal range (Alexander and McMahon, 2004;Baker and Hornbach, 2001;Hornbach et al, 1983;Huebner, 1982;Newell et al, 1977;Newell and Pye, 1970;Pernet et al, 2007Pernet et al, , 2008Resgalla et al, 2007;Riascos et al, 2012;Tankersley and Dimock, 1993;Widdows, 1973).…”

mentioning

confidence: 99%

The effect of seasonal temperature variation on behaviour and metabolism in the freshwater mussel (Unio tumidus)

Lurman

Walter

Hoppeler

2014

Journal of Thermal Biology

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Physiological and biochemical traits correlate with differences in growth rate and temperature adaptation among groups of the eastern oysterCrassostrea virginica

Cited by 72 publications

References 44 publications

Seasonal changes in the behaviour and respiration physiology of the freshwater duck musselAnodonta anatina.

Seasonal changes in the behaviour and respiration physiology of the freshwater duck musselAnodonta anatina.

Remodeling of membrane lipids in gills of adult hard clam Mercenaria mercenaria during declining temperature

The effect of seasonal temperature variation on behaviour and metabolism in the freshwater mussel (Unio tumidus)

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