Taste preference, a key component of food choice, changes with aging. However, it remains unclear how this occurs. To determine differences in taste preference between rats in different life stages, we examined the consumption of taste solutions and water using a two-bottle test. Male Sprague-Dawley rats of different ages were used: juvenile (3–6 weeks), young adult (8–11 weeks), adult (17–20 weeks), middle-aged (34–37 weeks), and old-aged (69–72 weeks). The intakes of the high and low concentration solutions presented simultaneously were measured. We observed that the old-aged group had lower preference ratios for 0.3 M sucrose and 0.1 M MSG in comparison with other groups. The preference ratio for 0.03 mM QHCl was higher in the middle-aged group than in the three younger groups and higher in the old-aged group than the juvenile group. The taste preferences for HCl and NaCl did not significantly differ among the age groups. The old-aged group tended to prefer high concentrations of sucrose, QHCl, NaCl, and MSG to low concentrations, indicating age-related decline in taste sensitivity. We also aimed to investigate differences between life stages in the electrophysiological responses of the chorda tympani nerve, one of the peripheral gustatory nerves, to taste stimuli. The electrophysiological recordings showed that aging did not alter the function of the chorda tympani nerve. This study showed that aging induced alterations in taste preference. It is likely that these alterations are a result of functional changes in other peripheral taste nerves, the gastrointestinal system, or the central nervous system.
Simple sugars are thought to elicit a unitary sensation, principally via the “sweet” taste receptor type 1 taste receptor (T1R)2+T1R3, yet we previously found that rats with experience consuming two metabolically distinct sugars, glucose and fructose, subsequently licked more for glucose than fructose, even when postingestive influences were abated. The results pointed to the existence of an orosensory receptor that binds one sugar but not the other and whose signal is channeled into neural circuits that motivate ingestion. Here we sought to determine the chemosensory nature of this signal. First, we assessed whether T1R2 and/or T1R3 are necessary to acquire this behavioral discrimination, replicating our rat study in T1R2+T1R3 double-knockout (KO) mice and their wild-type counterparts as well as in two common mouse strains that vary in their sensitivity to sweeteners [C57BL/6 (B6) and 129X1/SvJ (129)]. These studies showed that extensive exposure to multiple concentrations of glucose and fructose in daily one-bottle 30-min sessions enhanced lick responses for glucose over fructose in brief-access tests. This was true even for KO mice that lacked the canonical “sweet” taste receptor. Surgical disconnection of olfactory inputs to the forebrain (bulbotomy) in B6 mice severely disrupted the ability to express this experience-dependent sugar discrimination. Importantly, these bulbotomized B6 mice exhibited severely blunted responsiveness to both sugars relative to water in brief-access lick tests, despite the fact that they have intact T1R2+T1R3 receptors. The results highlight the importance of other sources of chemosensory and postingestive inputs in shaping and maintaining “hardwired” responses to sugar.
The sodium salt of glutamic acid, or monosodium glutamate (MSG), has two effects in foods: one is to induce a unique taste called umami, which is one of the five basic tastes, and the other is to make food palatable (i.e., flavor-enhancing or seasoning effects). However, the mechanism behind how MSG makes food more palatable remains poorly understood, although many food scientists seem to believe that the umami taste itself plays an important role. Here, we propose an alternative notion regarding this topic based on previous and recent studies. When added to complex food compositions, MSG facilitates the binding of existing kokumi substances to kokumi receptors. In turn, these bound kokumi substances enhance the intensity of umami, sweet, salty, and fatty tastes, resulting in increased palatability accompanied by kokumi flavor, such as thickness, mouthfulness, and continuity. The requisite for sufficient palatability and kokumi flavor is a good balance of umami and kokumi substances. This framework gives a scientifically useful background for providing newly developed foods, including cultured meat and plant-based meat substitutes, with good taste characteristics.
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