Anatomy and development of the human taste system.

The sense of taste relies on well-defined neuroanatomical structures, namely, the taste buds and afferent nerve fibers. Taste buds are clusters of 50-100 neuroepithelial cells located throughout the oral cavity, including the epiglottis and larynx. They are responsible for the initial transduction process that ultimately results in the perception of bitter, sour, salty, sweet, and umami (savory) sensations. They service as the initial sentinel for a sensory system critical in evolution for distinguishing "dangerous" food components, often perceived as bitter or unpleasant, from "useful" ones, often perceived as pleasant, salty, or sweet. This chapter describes the anatomy and development of the human peripheral taste system and provides historical context for what is presently known about this element of this important sensory system. Its main focus is on the fundamental question of how tastants are perceived-a question that has been of philosophical and scientific interest for more than two millennia. Descriptions of lingual and extralingual taste buds, their blood and nerve supplies, and the associated salivary glands are provided, including details of their microstructure and transduction mechanisms.

Differential Expression of Taste Receptors in Tongue Papillae of DBA Mouse

The tongue has 4 kinds of papillae, which are filiform, fungiform (FU), foliate (FO) and circumvallate papilla (CV). Tongue papillae except filiform papilla include taste buds. The papillae differ in taste sensitivities, likely due to differential expression of taste receptors. In this study, we evaluated differences in the expression levels of taste receptors in FU, FO and CV. Male DBA2 mice, 42-60 days old, were used in the study. Messenger RNAs were extracted from the murine epithelial tissues including FU, FO and CV. Cloned DNAs were synthesized by reverse transcription. Quantitative PCRs (qPCRs) were performed to determine mRNA expression levels of taste receptors. Results of qPCR revealed that the relative expression levels and patterns were different among FU, FO and CV. All three type 1 taste receptors were expressed FU, FO and CV at varying relative expression levels. All 35 kinds of type 2 taste receptors showed higher expression in FO and CV than in FU. Tas2r108 and Tas2r137 showed the two highest expression levels in all tested papillae. The differential expression levels and patterns of taste receptors among the three papillae could contribute to the different physiological sensitivities by tongue areas. Additional studies such as in situ hybridization or taste receptor cell activity recording is necessary to elucidate the functional relationship between expression levels of taste receptors and taste sensitivity.