Abstract
Sensory stimulation from foods elicits cephalic phase responses, which facilitate digestion and nutrient assimilation. One such response, cephalic-phase insulin release (CPIR), enhances glucose tolerance. Little is known about the chemosensory mechanisms that activate CPIR. We studied the contribution of the sweet taste receptor (T1r2+T1r3) to sugar-induced CPIR in C57BL/6 (B6) and T1r3 knockout (KO) mice. First, we measured insulin release and glucose tolerance following oral (i.e., normal ingestion) or intragastric (IG) administration of 2.8 M glucose. Both groups of mice exhibited a CPIR following oral but not IG administration, and this CPIR improved glucose tolerance. Second, we examined the specificity of CPIR. Both mouse groups exhibited a CPIR following oral administration of 1 M glucose and 1 M sucrose but not 1 M fructose or water alone. Third, we studied behavioral attraction to the same three sugar solutions in short-term acceptability tests. B6 mice licked more avidly for the sugar solutions than for water, whereas T1r3 KO mice licked no more for the sugar solutions than for water. Finally, we examined chorda tympani (CT) nerve responses to each of the sugars. Both mouse groups exhibited CT nerve responses to the sugars, although those of B6 mice were stronger. We propose that mice possess two taste transduction pathways for sugars. One mediates behavioral attraction to sugars and requires an intact T1r2+T1r3. The other mediates CPIR but does not require an intact T1r2+T1r3. If the latter taste transduction pathway exists in humans, it should provide opportunities for the development of new treatments for controlling blood sugar.
Highlights
WHEN A MAMMAL INGESTS A sugar-sweetened beverage, it activates circuits in the gustatory neuraxis that perform three distinct functions: analyze its chemical composition, determine its acceptability, and activate cephalic-phase responses [40, 41]
We focused on one aspect of digestive preparation: cephalicphase insulin release (CPIR)
Insulin release and glucose tolerance following oral vs. IG glucose administration
Summary
WHEN A MAMMAL INGESTS A sugar-sweetened beverage, it activates circuits in the gustatory neuraxis that perform three distinct functions: analyze its chemical composition (stimulus identification/discrimination), determine its acceptability (hedonic evaluation), and activate cephalic-phase responses (digestive preparation) [40, 41]. We focused on one aspect of digestive preparation: cephalicphase insulin release (CPIR) It is elicited by pregastric contact with nutrients and enhances glucose tolerance (i.e., ability to maintain glucose homeostasis) in humans [22, 44] and rats [6, 18, 26, 37, 43, 47, 48]. Because sugars and artificial sweeteners are ligands of T1r2ϩT1r3 [25, 30, 31], they may be able to elicit a CPIR by activating the T1r2ϩT1r3-dependent taste signaling pathway [7]. Prior studies have established that T1r2 KO and T1r3 KO mice display impaired glucose tolerance [12, 28, 29, 38], but normal insulin sensitivity [38]. The third goal was to confirm prior reports of divergent behavioral attraction and CT nerve responses to sugars across both mouse groups
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