An Intertidal Sea Star Adjusts Thermal Inertia to Avoid Extreme Body Temperatures

The body temperature of ectotherms is influenced by the interaction of abiotic conditions, morphology, and behavior. Although organisms living in different thermal habitats may exhibit morphological plasticity or move from unfavorable locations, there are few examples of animals adjusting their thermal properties in response to short‐term changes in local conditions. Here, we show that the intertidal sea star Pisaster ochraceus modulates its thermal inertia in response to prior thermal exposure. After exposure to high body temperature at low tide, sea stars increase the amount of colder‐than‐air fluid in their coelomic cavity when submerged during high tide, resulting in a lower body temperature during the subsequent low tide. Moreover, this buffering capacity is more effective when seawater is cold during the previous high tide. This ability to modify the volume of coelomic fluid provides sea stars with a novel thermoregulatory “backup” when faced with prolonged exposure to elevated aerial temperatures.

[1]  R. Huey,et al.  Evolution of thermal sensitivity of ectotherm performance. , 1989, Trends in ecology & evolution.

[2]  B. Helmuth INTERTIDAL MUSSEL MICROCLIMATES: PREDICTING THE BODY TEMPERATURE OF A SESSILE INVERTEBRATE , 1998 .

[3]  J. C. Ferguson,et al.  Cytology and function of the madreporite systems of the starfish Henricia Sanguinolenta and Asterias Vulgaris , 1991, Journal of morphology.

[4]  D. Wethey,et al.  Climate change in the rocky intertidal zone: predicting and measuring the body temperature of a keystone predator , 2009 .

[5]  H. J. Fyhn,et al.  Eco-physiological studies of an intertidal crustacean, Pollicipes polymerus (Cirripedia, Lepadomorpha): aquatic and aerial respiration. , 1972, The Journal of experimental biology.

[6]  R. Huey,et al.  WITHIN‐ AND BETWEEN‐GENERATION EFFECTS OF TEMPERATURE ON THE MORPHOLOGY AND PHYSIOLOGY OF DROSOPHILA MELANOGASTER , 1996, Evolution; international journal of organic evolution.

[7]  T. J. Breen,et al.  Biostatistical Analysis (2nd ed.). , 1986 .

[8]  J. Burnaford,et al.  Solar radiation plays a role in habitat selection by the sea star Pisaster ochraceus , 2008 .

[9]  D. Wethey,et al.  Variation in the sensitivity of organismal body temperature to climate change over local and geographic scales. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[10]  J. C. Ferguson The Function of the Madreporite in Body Fluid Volume Maintenance by an Intertidal Starfish, Pisaster ochraceus. , 1992, The Biological bulletin.

[11]  T. Blackburn,et al.  Testing the thermal melanism hypothesis: a macrophysiological approach , 2008 .

[12]  D. Franz Seasonal changes in pyloric caecum and gonad indices during the annual reproductive cycle in the seastar Asterias forbesi , 1986 .

[13]  R. Desharnais,et al.  Complex equilibria in the maintenance of boundaries: experiments with mussel beds. , 2009, Ecology.

[14]  Jessica Gurevitch,et al.  Design and Analysis of Ecological Experiments , 1993 .

[15]  B. Helmuth,et al.  Living on the Edge of Two Changing Worlds: Forecasting the Responses of Rocky Intertidal Ecosystems to Climate Change , 2006 .

[16]  D. DeNardo,et al.  Cloacal evaporative cooling: a previously undescribed means of increasing evaporative water loss at higher temperatures in a desert ectotherm, the Gila monster Heloderma suspectum , 2004, Journal of Experimental Biology.

[17]  Sanford,et al.  Regulation of keystone predation by small changes in ocean temperature , 1999, Science.

[18]  T. Casey Biophysical Ecology and Heat Exchange in Insects , 1992 .

[19]  W. B. Watt ADAPTIVE SIGNIFICANCE OF PIGMENT POLYMORPHISMS IN COLIAS BUTTERFLIES. I. VARIATION OF MELANIN PIGMENT IN RELATION TO THERMOREGULATION , 1968, Evolution; international journal of organic evolution.

[20]  K. A. S. Mislan,et al.  Predator–prey interactions under climate change: the importance of habitat vs body temperature , 2009 .

[21]  C. Franklin,et al.  Physiological mechanisms of thermoregulation in reptiles: a review , 2005, Journal of Comparative Physiology B.

[22]  Chris C. Nice,et al.  How caterpillars avoid overheating: behavioral and phenotypic plasticity of pipevine swallowtail larvae , 2005, Oecologia.

[23]  E. Sanford The feeding, growth, and energetics of two rocky intertidal predators (Pisaster ochraceus and Nucella canaliculata) under water temperatures simulating episodic upwelling , 2002 .

[24]  W. J. Gross Osmotic Responses in the Sipunculid Dendrostomum Zostericolum , 1954 .

[25]  R. Etter PHYSIOLOGICAL STRESS AND COLOR POLYMORPHISM IN THE INTERTIDAL SNAIL NUCELLA LAPILLUS , 1988, Evolution; international journal of organic evolution.

[26]  H. Prange Evaporative cooling in insects , 1996 .

[27]  H. Dingle,et al.  Altitudinal variation in behavioural thermoregulation: local adaptation vs. plasticity in California grasshoppers , 2005, Journal of evolutionary biology.

[28]  Joel G. Kingsolver,et al.  Evolutionary Analyses of Morphological and Physiological Plasticity in Thermally Variable Environments , 1998 .

[29]  S. Pincebourde,et al.  Body temperature during low tide alters the feeding performance of a top intertidal predator , 2008 .

[30]  D. M. Gates,et al.  Heat-Transfer Analysis of Animals: Some Implications for Field Ecology, Physiology, and Evolution , 1975 .

[31]  S. D. Garrity Some adaptations of gastropods to physical stress on a tropical rocky shore , 1984 .

[32]  R. Huey,et al.  Physiological Consequences of Habitat Selection , 1991, The American Naturalist.

[33]  C. Robles,et al.  Responses of a Key Intertidal Predator to Varying Recruitment of Its Prey , 1995 .

[34]  G. Somero,et al.  Biochemical Adaptation: Mechanism and Process in Physiological Evolution , 1984 .

[35]  R. Paine Food Web Complexity and Species Diversity , 1966, The American Naturalist.

[36]  D. Wethey Biogeography, Competition, and Microclimate: The Barnacle Chthamalus fragilis in New England1 , 2002, Integrative and comparative biology.

[37]  Stillman,et al.  Adaptation to temperature stress and aerial exposure in congeneric species of intertidal porcelain crabs (genus Petrolisthes): correlation of physiology, biochemistry and morphology with vertical distribution , 1996, The Journal of experimental biology.