Effects of dehydration on organ metabolism in the frogPseudacris crucifer: hyperglycemic responses to dehydration mimic freezing-induced cryoprotectant production |
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Authors: | T A Churchill K B Storey |
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Institution: | (1) Institute of Biochemistry, Carleton University, K1S 5B6 Ottawa, Ontario, Canada;(2) Department of Biology, Carleton University, K1S 5B6 Ottawa, Ontario, Canada;(3) Present address: Academic Department of Surgery, Royal Free Hospital School of Medicine, NW3 2QG London, UK |
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Abstract: | The metabolic effects of evaporative water loss at 5 °C were assessed for both fall- and spring-collected spring peepersPsuedacris crucifer. Frogs readily endured the loss of 50% of total body water. During dehydration organ water content was defended with no change in water content in skeletal muscle, gut, and kidney of 50% dehydrated frogs and reduced water content in liver, brain and heart. Dehydration stimulated a rapid and massive increase in liver glucose production. In fall-collected frogs liver glucose rose by 120-fold to 2690±400 nmol · mg protein-1 or 220 mol · g ww-1 in 50% dehydrated frogs and glucose in other organs increased by 2.6- to 60-fold. Spring-collected frogs showed the same qualitative response to dehydration although absolute glucose levels were lower, rising maximally by 8.4-fold in liver. Glucose synthesis was supported by glycogenolysis in liver and changes in the levels of glycolytic intermediates in liver indicated that an inhibitory block at the phosphofructokinase locus during desiccation helped to divert hexose phosphates into the production of glucose. Liver energy status (ATP, total adenylates, energy charge) was maintained even after the loss of 35% of total body water but at 50% dehydration all parameters showed a sharp decline; for example, energy charge fell from about 0.85 to 0.42. Severe dehydration also led to an accumulation of lactate in four organs, probably hypoxia-induced the to impaired circulation. The hyperglycemic response ofP. crucifer to dehydration mimics the cryoprotectant synthesis response seen during freezing of this freeze-tolerant frog, suggesting that these share a common regultory mechanism and that the cryoprotectant response may have arisen out of pre-existing volume regulatory responses of amphibians. The hyperglycemic response to dehydration might also be utilized during winter hibernation to help retard body water loss by raising the osmolality of the body fluids in situations where hibernaculum conditions become dry.Abbreviations bin
body mass
- bw
body water
- CrP
creatine phosphate
- dw
dry weight
- F6P
fructose-6-phosphate
- FBP
fructose-1,6-bisphosphate
- G6P
glucose-6-phosphate
- PEP
phosphoenolpyruvate
- PFK
phosphofructokinase
- PYR
pyruvate
- ww
wet weight |
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Keywords: | Amphibian water balance Desiccation tolerance Freeze tolerance Spring peeper Cell volume regulation |
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