Salivary proteins alter taste-guided behaviors and taste nerve signaling in rat.

Taste stimuli are normally dissolved in saliva prior to interacting with their respective receptor targets. There are hundreds of proteins in saliva, and it has been hypothesized that these proteins could interact with either taste stimuli or taste receptors to alter taste signaling and diet acceptance. However, the impact of these proteins on feeding has been relatively unexplored using rodent models. We have developed a novel technique for saliva collection that allows us to link salivary protein expression with feeding behavior. First, we monitored the microstructure of rats' feeding patterns on a 0.375% quinine diet (Q-diet) while tracking changes in salivary protein expression. We found 5 protein bands were upregulated by diet exposure to Q-diet and upregulation of a subset of these bands were statistically related to increased diet acceptance, including changes in behavioral measures that are thought to represent both orosensory and postingestive signaling. In a second experiment, we measured the licking to a range of quinine solutions (0.01-1.0mM) before and after the animals were exposed to a tannic acid diet that altered salivary protein expression. Rats found the quinine solutions less aversive after salivary protein altering diets. In a third experiment we recorded the response of the chorda tympani (CT) nerve while delivering quinine solutions (0.3-30mM) to the front of the tongue dissolved in either "donor saliva" containing salivary proteins or donor saliva which has had the salivary proteins removed. Donor saliva was collected from a separate group of animals using isoproterenol and pilocarpine. The samples containing salivary proteins resulted in lower nerve responses than those without salivary proteins. Together these data suggest that salivary proteins are capable of altering taste-guided behaviors and taste nerve signaling.

Leptin increases temperature-dependent chorda tympani nerve responses to sucrose in mice.

Leptin receptors are present in taste buds and previous research indicates that leptin administration modified electrophysiological and behavioral responses to sweet taste. It is now known that sweet taste is temperature dependent. We examined the influence of (1) stimulus temperature on chorda tympani (CT) nerve responses to sucrose, saccharin and NH(4)Cl; and (2) leptin administration on CT nerve responses to sucrose, saccharin and other basic taste stimuli at 35°C that maximized sweet-taste sensitivity in C57BL/6 mice. We found that the CT nerve responded with greater magnitude to sucrose and saccharin as stimulus temperature increased from 23 to 35°C and then declined at higher temperatures. In contrast, the CT nerve responses to NH(4)Cl increased in magnitude as temperature increased from 23 to 44°C. We also showed that leptin selectively increased the CT nerve responses to sucrose at 35°C in both fasted and free-fed mice. The responses of mice treated with the saline vehicle did not change. Our findings are consistent with the notion that leptin binds with its receptors in fungiform taste buds and alters the message conveyed by sugar-responsive neurons to the brain.