Abstract
Many nectar-feeding bird species decrease food intake when sugar concentration in food is increased. This feeding response can be explained by two alternative hypotheses: compensatory feeding and physiological constraint. The compensatory feeding hypothesis predicts that if birds vary intake to maintain a constant energy intake to match energy expenditures, then they should increase intake when expenditures are increased. Broad-tailed hummingbirds were presented with sucrose solutions at four concentrations (292, 584, 876, and 1,168 mmol L(-1)) and exposed to two environmental temperatures (10 degrees and 22 degrees C). Birds decreased volumetric food intake in response to sugar concentration. However, when they were exposed to a relatively sudden drop in environmental temperature and, hence, to an acute increase in thermoregulatory energy expenditures, they did not increase their rate of energy consumption and lost mass. These results support the existence of a physiological constraint on feeding intake. A simple chemical reactor model based on intestinal morphology and in vitro measurements of sucrose hydrolysis predicted observed intake rates closely. This model suggests that intestinal sucrose hydrolysis rates were near maximal and, thus, may have imposed limits to sugar assimilation. Although sugar assimilation was high (95%), the proportions of excreted sucrose, glucose, and fructose found in excreta differed significantly. The monosaccharides glucose and fructose were about eight and three times more abundant than sucrose, respectively. Broad-tailed hummingbirds are small high-altitude endotherms that face unpredictable weather and the energetic expense of premigratory fattening. Digestive processes have the potential to impose severe challenges to their energy budgets.
Highlights
To fuel the energetic demands of hovering flight (Suarez 1992) and temperature regulation of tiny bodies (Pearson 1950; Lasiewski 1963), hummingbirds feed on sugar-containing floral nectars (Martınez del Rio 1990b)
Intake was negatively correlated with sugar concentration (ANCOVAconcentration, F1,12 = 25.2, P ! 0.001), the relationship between intake and sugar concentration in food did not vary between temperatures (ANCOVAslopes, F1, 12 = 0.03, and ANCOVAintercepts, F1, 12 = 0.02, P 1 0.8)
Ingested sugar was positively correlated with food sugar concentration (ANCOVAconcentration, F1,12 = 9.0, P ! 0.01; Fig. 1), but it was independent of temperature (ANCOVAslopes F1,12 = 0.15; ANCOVAintercepts, F1,12 = 0.04, P 1 0.7; Fig. 1)
Summary
To fuel the energetic demands of hovering flight (Suarez 1992) and temperature regulation of tiny bodies (Pearson 1950; Lasiewski 1963), hummingbirds feed on sugar-containing floral nectars (Martınez del Rio 1990b). We explore the idea that digestive processes can impose constraints on the rate at which hummingbirds ingest food. When sugar concentration in food is experimentally increased, many nectar-feeding bird species, including hummingbirds, decrease volumetric food intake (Collins 1981; Downs 1997; Lopez-Calleja et al 1997). By modulating volumetric intake with sugar concentration, birds appear to defend a constant rate of energy intake (Lopez-Calleja et al 1997). A reciprocal relationship between nutrient density and food intake is not exclusive to nectar-feeding birds. The negative relationship between intake and food quality has been called an “intake-response relationship” (Castle and Wunder 1995), and we adopt this terminology here
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