Evolution of Regulatory Responses to Feeding in Snakes

Do animal species that normally consume large meals at long intervals evolve to down‐regulate their metabolic physiology while fasting and to up‐regulate it steeply on feeding? To test this hypothesis, we compared postfeeding regulatory responses in eight snake species: four frequent feeders on smal...

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Bibliographic Details
Published in:Physiological and biochemical zoology 2000-03, Vol.73 (2), p.123-141
Main Authors: Secor, Stephen M., Diamond, Jared M.
Format: Article
Language:English
Subjects:
Animal digestion
Animals
Aspartic Acid - analysis
Aspartic Acid - metabolism
Average linear density
Biological Evolution
Biological Transport
Boidae - genetics
Boidae - metabolism
Boidae - physiology
Colubridae - genetics
Colubridae - metabolism
Colubridae - physiology
Digestion - physiology
Fasting
Feeding Behavior
Flagella
Gene Expression Regulation
Glucose - analysis
Glucose - metabolism
Human organs
Intestine, Small - chemistry
Intestine, Small - metabolism
Intestine, Small - physiology
Invited Perspectives in Physiological and Biochemical Zoology
Leucine - analysis
Leucine - metabolism
Lysine - analysis
Lysine - metabolism
Metabolism
Microvilli - chemistry
Microvilli - metabolism
Microvilli - physiology
Nutrient uptake
Oxygen Consumption - physiology
Phylogeny
Proline - analysis
Proline - metabolism
Small intestine
Snakes
Snakes - genetics
Snakes - metabolism
Snakes - physiology
Stomach
Stomach - chemistry
Stomach - metabolism
Stomach - physiology
Viperidae - genetics
Viperidae - metabolism
Viperidae - physiology
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Summary:Do animal species that normally consume large meals at long intervals evolve to down‐regulate their metabolic physiology while fasting and to up‐regulate it steeply on feeding? To test this hypothesis, we compared postfeeding regulatory responses in eight snake species: four frequent feeders on small meals and four infrequent feeders on large meals. For each species, we measured factorial changes in metabolic rate, in activities and capacities of five small intestinal brush border nutrient transporters, and in masses of eight organs that function in nutrient processing after consumption of a rodent meal equivalent to 25% of the snake's body mass. It turned out that, compared with frequent feeders, infrequent feeders digest that meal more slowly; have lower metabolic rates, organ masses, and nutrient uptake rates and capacities while fasting; have higher energy expenditure during digestion; and have higher postfeeding factorial increases in metabolic rate, organ masses, and nutrient uptake rates and capacities. These conclusions, which conform to the hypothesis mentioned above, remain after phylogeny has been taken into account. The small organ masses and low nutrient transporter activities during fasting contribute to the low fasting metabolism of infrequent feeders. Quantitative calculations of partial energy budgets suggest that energy savings drive the evolution of low mass and activities of organs during fasting and of large postfeeding regulatory responses in infrequent feeders. We propose further tests of this hypothesis among other snake species and among other ectotherms.
ISSN:1522-2152
1537-5293
DOI:10.1086/316734