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Tolerances to high temperature of infaunal bivalves and the effect of geographical distribution, position on the shore and season

Published online by Cambridge University Press:  11 May 2009

James G. Wilson  and
Bernard Elkaim
James G. Wilson
Affiliation:
Environmental Sciences Unit, Trinity College, Dublin 2, Ireland
Bernard Elkaim
Affiliation:
Laboratoire de Hydrobiologie, Universite Pierre et Marie Curie Paris VI, 12 Rue Cuvier, 75005 Paris, France
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Extract

There are four important influences on the temperature tolerance displayed by infaunal bivalves, namely their position on the shore, the depth to which they burrow, their geographical distribution and the seasonal cycle.

The temperature tolerance of a species is closely related to shore position and burrowing depth, since these both modify the actual range of temperatures to which the organism is exposed and the tidal variation in temperature. As one might expect, southern populations of a species tend to be lower on the shore than equivalents in northern Europe, but at any one location it is difficult to detect a difference in tolerance between individuals from the top of the shore and those from the bottom. Southern populations do have a higher tolerance to high temperatures than northern, despite the shift in littoral distribution. A similar pattern of response and shift in tolerance is shown between summer- and winter-acclimated specimens.

However, the seasonal shift in response to temperature is not entirely as might be expected, as oxygen consumption measurements show reverse acclimation (i.e. winter respiration rates lower than summer). Reverse acclimation has been demonstrated in a number of bivalve species, and the degree of reverse acclimation is here suggested to be related to the degree of deposit- or filter-feeding habit.

There is evidence that bivalves are capable of regulating to some extent their metabolic rate, independent of temperature. Six groups of Macoma balthica were investigated, of which the four from relatively high temperature environments regulated from 20°C, while the other two did not, suggesting that this capability can be acquired.

Type
Research Article
Information
Journal of the Marine Biological Association of the United Kingdom , Volume 71 , Issue 1 , February 1991 , pp. 169 - 177
Copyright
Copyright © Marine Biological Association of the United Kingdom 1991

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References

AnsellA.D., A.D., 1974. Seasonal changes in the biochemical composition of the bivalve Nucula sulcata from the Clyde sea area. Marine Biology, 25, 101108.CrossRefGoogle Scholar
AnsellA.D., A.D.,BarnettP.R.O., P.R.O.,BodoyA., A., & Masse, H. 1980a. Upper temperature tolerances of some European molluscs. I. Tellina fabula and Tellina tennis. Marine Biology, 58, 3339.CrossRefGoogle Scholar
AnsellA.D., A.D.,BarnettP.R.O., P.R.O.,Bodoy, A. & MasseH., H., 1980b. Upper temperature tolerances of some European molluscs. II. Donax vittatus and D. trunculus. Marine Biology, 58, 4146.CrossRefGoogle Scholar
AnsellA.D., A.D.,BarnettP.R.O., P.R.O.,Bodoy, A. & MasseH., H., 1981. Upper temperature tolerances of some European molluscs. III. Cardium glaucum, C. tuberculatum and C. edule. Marine Biology, 65, 117183.Google Scholar
Bachelet, G. 1980. Growth and recruitment of the tellinid bivalve Macoma balthica at the southern limit of its geographical distribution. Marine Biology, 59,105117.CrossRefGoogle Scholar
Beukema, J.J. & Desprez, M. 1986. Single and dual animal growing seasons in the tellinid bivalve Macoma balthica (L.). Journal of Experimental Marine Biology and Ecology, 102, 3545.Google Scholar
BeukemaJ.J., J.J.,Knol, E. & CadeeG.C., G.C., 1985. Effects of temperature on the length of the growing season in the tellinid bivalve Macoma balthica (L.) living on the tidal flats in the Dutch Wadden Sea. Journal of Experimental Marine Biology and Ecology, 90, 129144.CrossRefGoogle Scholar
Beukema, J.J. & MeehanB.W., B.W., 1985. Latitudinal variation in linear growth and other shell characteristics of Macoma balthica. Marine Biology, 90, 2733.CrossRefGoogle Scholar
Calow, P. 1975. The respiratory strategies of two species of freshwater gastropods (Ancylusfluviatilis Mull, and Planorbis contortus Linn.) in relation to temperature, oxygen concentration, body size, and season. Physiological Zoology, 48, 114129.Google Scholar
Calow, P. 1981. Resource, utilisation and reproduction. In Physiological Zoology: an Evolutionary Approach to Resource Use (ed. Townsend, C.R. and Calow, P.) pp 245270. Oxford:Blackwell Scientific Publications.Google Scholar
Calow, P. 1983. Life cycle patterns and evolution. In The Mollusca, vol 6.Ecology (ed. Wilbur, K.M.) pp. 649678. London:Academic Press.CrossRefGoogle Scholar
Fry, F.E.J. 1947. Effects of the environment on animal activity. University of Toronto Studies. Bio-logical Series, 55, 562.Google Scholar
Hummel, H. 1985. Food intake and growth in Macoma balthica (Mollusca) in the laboratory. Netherlands Journal of Sea Research, 19, 7783.CrossRefGoogle Scholar
McMahon, R.F. & WilsonJ.G., J.G., 1981. Seasonal respiratory responses to temperature and hypoxia in relation to burrowing depth in three intertidal bivalves. Journal of Thermal Biology, 6, 267277.CrossRefGoogle Scholar
Newell, R.C. & BranchG.M., G.M., 1980. The influence of temperature on the maintenance of energy balance in marine invertebrates. Advances in Marine Biology, 17, 371376Google Scholar
Wilde, P.A.De, W.J. 1975. Influence of temperature on behaviour, energy metabolism and growth of Macoma balthica (L.). In Proceedings of the Ninth European Marine Biology Symposium, Oban, Scotland, 1974 (ed. Barnes, H.) pp. 239256. Aberdeen:Aberdeen University Press.Google Scholar
Wilson, J.G. 1976. Dispersion of Tellina tenuis da Costa from Kames Bay, Millport, Scotland. Marine Biology, 37, 371376.CrossRefGoogle Scholar
Wilson, J.G. 1978. Upper temperature tolerances of Tellina tenuis and T. fabula. Marine Biology, 45, 123128.CrossRefGoogle Scholar
Wilson, J.G. 1981. Temperature tolerance of circatidal bivalves in relation to their distribution. Journal of Thermal Biology, 6, 279286.CrossRefGoogle Scholar
Wilson, J.G. 1985. Oxygen consumption of Tellina fabula Gmelin in relation to temperature and low oxygen tension. Soosiana, 13, 2732.Google Scholar
Wilson, J.G. 1988. Resource partitioning and predation as a limit to size in Nucula turgida (Leckenby & Marshall). Functional Ecology, 2, 6366.Google Scholar
WilsonJ.G., J.G., 1990a. Effects of temperature changes on infaunal circalittoral bivalves, particularly Tellina tenuis and T. fabula. In Expected Effects of Climatic Change on Marine Ecosystems (ed. Beukema, J. J. et ah) pp. 9397. Amsterdam:Kluwer Academic Publishers.CrossRefGoogle Scholar
Wilson, J.G. 1990b. Gill and palp morphology of Tellina tenuis and Tellina fabula in relation to feeding. In The Bivalvia. Proceedings of a Symposium in Memory of Sir Charles Maurice Yonge, Edinburgh, 1986 (ed. Morton, B.) Hong Kong:University of Hong Press.Google Scholar
Wilson, J.G. & DavisJ.P., J.P., 1984. The Effect Of Environmental Variables On The Oxygen Consumption Of The Protobranch Bivalve Nucula Turgida (Leckenby And Marshall). Journal of Molluscan Studies, 50, 7377.CrossRefGoogle Scholar