Apoptosis in mouse taste buds after denervation

Apoptotic cells in the taste buds of mouse circumvallate papillae after the sectioning of bilateral glossopharyngeal nerves were examined by the method of DNA nick-end labeling (TUNEL), together with standard electron microscopy. The taste buds decreased in number and size 3–11 days after denervation and disappeared at 11 days. The TUNEL method revealed only a few positively stained nuclei in normal taste buds but, in those of mice 1–5 days after denervation, the number of positive nuclei had increased to 3–5 times that of taste buds from normal mice. Electron-microscopic observation after denervation demonstrated taste bud cells containing condensed and fragmentary nuclei in a cytoplasm with increased density. The results show that taste bud cells under normal conditions die by apoptosis at the end of their life span, and that gustatory nerve sectioning causes apoptosis of taste bud cells with taste buds decreasing in number and ultimately disappearing. Received: 20 November 1995 / Accepted: 15 May 1996     

Age-related alteration of taste bud distribution in the common marmoset

Alteration in the number of taste buds on the soft palate (SP), fungiform (FF), foliate (FL) and circumvallate (CV) papillae in the common marmoset at different postnatal ages was examined histologically. After paraffin embedding, complete serial sections at 10 microm thickness were made and stained by HE. Digitized images for each section were examined carefully. The number of FF taste buds at day 1 was 334. While only 20% of all the taste buds at birth possessed a taste pore, 39% of 174 SP taste buds at day 1 possessed a taste pore. The number of taste buds with pores at day 1 was small for the center CV (19 of 59), one side CV (7 of 25), and one side FL (2 of 16). These results suggest that the functional maturation of SP taste buds may precede maturation in other areas of the tongue. The total number of taste buds increased with increasing age, reached a maximum at 2 months of age: FF, 1069; SP, 609; CV-center, 530; CV-side, 390; FL, 201, and decreased thereafter. Almost all taste buds possessed a taste pore after 2 months of age. The decrease in the number of taste buds in the oral cavity with increase in age may change taste sensitivity.     

The time course of taste bud regeneration after glossopharyngeal or greater superficial petrosal nerve transection in rats

We previously have published data detailing the time course of taste bud regeneration in the anterior tongue following transection of the chorda tympani (CT) nerve in the rat. This study extends the prior work by determining the time course of taste bud regeneration in the vallate papilla, soft palate and nasoincisor ducts (NID) following transection of either the glossopharyngeal (GL) or greater superficial petrosal (GSP) nerve. Following GL transection in rats (n = 6 per time point), taste buds reappeared in the vallate papilla between 15 and 28 days after surgery, and returned to 80.3% of control levels (n = 12) of taste buds by 70 days postsurgery. The first appearance and the final percentage of the normal complement of regenerated vallate taste buds after GL transection resembled that seen previously in the anterior tongue after CT transection. However, in the latter case, regenerated taste buds reached asymptotic levels by 42 days after surgery, whereas within the time frame of the present study, a clear asymptotic return of vallate taste buds was not observed. In contrast to the posterior (and anterior) tongue, only 25% of the normal complement of palatal taste buds regenerated by 112 days and 224 days after GSP transection (n = 9). The difference in regenerative capacity might relate to the surgical approach used to transect the GSP. These experiments provide useful parametric data for investigators studying the functional consequences of gustatory nerve transection and regeneration.     

Functional Cell Types in Taste Buds Have Distinct Longevities

Taste buds are clusters of polarized sensory cells embedded in stratified oral epithelium. In adult mammals, taste buds turn over continuously and are replenished through the birth of new cells in the basal layer of the surrounding non-sensory epithelium. The half-life of cells in mammalian taste buds has been estimated as 8–12 days on average. Yet, earlier studies did not address whether the now well-defined functional taste bud cell types all exhibit the same lifetime. We employed a recently developed thymidine analog, 5-ethynil-2′-deoxyuridine (EdU) to re-evaluate the incorporation of newly born cells into circumvallate taste buds of adult mice. By combining EdU-labeling with immunostaining for selected markers, we tracked the differentiation and lifespan of the constituent cell types of taste buds. EdU was primarily incorporated into basal extragemmal cells, the principal source for replenishing taste bud cells. Undifferentiated EdU-labeled cells began migrating into circumvallate taste buds within 1 day of their birth. Type II (Receptor) taste cells began to differentiate from EdU-labeled precursors beginning 2 days after birth and then were eliminated with a half-life of 8 days. Type III (Presynaptic) taste cells began differentiating after a delay of 3 days after EdU-labeling, and they survived much longer, with a half-life of 22 days. We also scored taste bud cells that belong to neither Type II nor Type III, a heterogeneous group that includes mostly Type I cells, and also undifferentiated or immature cells. A non-linear decay fit described these cells as two sub-populations with half-lives of 8 and 24 days respectively. Our data suggest that many post-mitotic cells may remain quiescent within taste buds before differentiating into mature taste cells. A small number of slow-cycling cells may also exist within the perimeter of the taste bud. Based on their incidence, we hypothesize that these may be progenitors for Type III cells.     

Preparation and isolation of a taste bud-derived fraction from bovine circumvallate papillae.

A crude extract from taste buds was prepared from circumvallate papillae of bovine tongues by a procedure consisting of freezing, coring, excision, treatment with hypotonic buffer, nitrogen pressurization and selective homogenization. Examination of taste buds by light and electron microscopy before and after this procedure indicated that some of the contents of the buds, mainly from the more apical portions, was extruded following the procedure; anatomical changes could not be observed in the epithelial tissue immediately surrounding the taste buds.     

Lgr5 Identifies Progenitor Cells Capable of Taste Bud Regeneration after Injury

Taste buds are composed of a variety of taste receptor cell types that develop from tongue epithelium and are regularly replenished under normal homeostatic conditions as well as after injury. The characteristics of cells that give rise to regenerating taste buds are poorly understood. Recent studies have suggested that Lgr5 (leucine-rich repeat-containing G-protein coupled receptor 5) identifies taste bud stem cells that contribute to homeostatic regeneration in adult circumvallate and foliate taste papillae, which are located in the posterior region of the tongue. Taste papillae in the adult anterior region of the tongue do not express Lgr5. Here, we confirm and extend these studies by demonstrating that Lgr5 cells give rise to both anterior and posterior taste buds during development, and are capable of regenerating posterior taste buds after injury induced by glossopharyngeal nerve transection.     

Morphometry and cellular dynamics of denervated fungiform taste buds in the hamster

For most species and gustatory papillae denervation resultsin a virtual disappearance of taste buds. This is not the casefor hamster fungiform papillae, which contain taste buds thatsurvive denervation. To characterize these taste buds, in thisstudy, counts and measurements were made of all buds on theanterior 3 mm of the hamster tongue at 36 or 91 days after resectingthe chorda/lingual nerve. Taste bud numbers were, at both timeperiods, unaffected by denervation. However, bud dimensionswere affected with denervated buds 25–30% smaller thancontrol ones. Counts of taste bud cells indicated that decreasesin bud size may result from shrinkage, but not a loss of cells.Tritiated thymidine autoradiography was used to evaluate whetherdenervation influences the mitotic activity or the migratorypattern of bud cells. For every animal, the average number oflabelled cells per bud was slightly lower on the denervatedthan the control side of the tongue. However, when labelledcell positions were evaluated at 0.25, 3 and 6 days after thymidine,the distances from the sides of the bud increased at increasingtimes after injection for both the innervated and the denervatedbuds. Stem cells were located laterally or basally in the bud.Labelled cells that migrated into the centers of the buds werefew and seen only at 6 days post-injection time in both controland experimental buds. The moderate effects of denervation ontaste bud sizes and mitotic activities may indicate a generalizedatrophy. Remarkably intact were taste bud numbers and the migratorypatterns of cells, features of anterior tongue taste buds inthe hamster that are relatively invulnerable to resection ofthe chorda /lingual nerve.     

Changes in number and morphology of fungiform taste buds in rat after transection of the chorda tympani or chordalingual nerve

In normal rats there is one taste bud on the apical surfaceof each fungiform papilla. These taste buds are innervated bythe chorda tympani proper nerve (CT). According to general consensus,after cutting the nerve the taste buds should disappear. Inthis study, performed on 24 rats divided in six groups, theCT nerve on the left side (singly denervated) and the combinedchorda-lingual (CT-L) nerve on the other side (doubly denervatedwere permanently interrupted. The animals were sacrificed after5, 10, 20, 35,60 and 100 days and their tongues serially sectionedfor light microscope examiation. Some papillae were examinedunder an electron microscope. The papillae were categorizedinto three groups: papillae with a normal looking taste bud,with an abnormal looking taste bud and without a taste bud.The results showed a substantial number of papillae with a normallooking taste bud present at all time intervals in all animals.More specifically, on the singly denervated side the proportionof normal looking taste buds stayed below 10% until day 60,when it increased to 15% and to 23% on day 100. The proportionof abnormal looking taste buds decreased from above 92% by day5 to 49% on day 100. The percentage of fungiform papillae withoutsigns of a taste bud was relatively low on the singly denervatedside at times (1, 5, 16, 29, 34 and 28%). On the doubly denervatedside fewer than than 4% normal looking taste buds were foundthroughout the time period. The proportion of abnormal lookingtaste buds decreased from {small tilde} 96% by day 5 to 35%on day 100. A significantly higher proportion of papillae withno taste bud was observed on this side from day 10 onwards.(1, 29, 32, 52, 60 and 63%). The reasons for the differencein tast bud number between the doubly and singly denervatedsides are unknown, but it is possible that collaterals fromother (non-gustatory) nerves have an ability, although limited,to induce and maintain fungiform taste buds. In other words,the capacity to induce taste bud formation is not limited exclusivelyto gustatory nerves.     

Co-expression pattern of Shh with Prox1 and that of Nkx2.2 with Mash1 in mouse taste bud

In mammals, taste buds are maintained by continuous turnover of cells, even in adulthood. Cell proliferation and differentiation continue to produce taste cells, which express various genes related to taste reception. We found the co-expression of Sonic hedgehog (Shh) with Prox1 and that of Nkx2.2 with Mash1 in adult mouse taste buds. Whereas Prox1was expressed strongly in cells in the basal region of mouse taste buds where Shh was co-expressed, it was expressed weakly in almost all taste bud cells lacking Shh expression. At 0.5 day after birth, when taste cells have not yet differentiated, the expressions of Shh and Prox1 completely overlapped in the epithelium of circumvallate papillae. Nkx2.2 was observed in cells expressing Mash1, but not in cells expressing genes related to taste reception, such as gustducin and T1R3. Almost all fusiform cells expressing Mash1 co-expressed Nkx2.2, while the majority of round cells expressing Mash1 in the basal region of taste buds lacked Nkx2.2 expression.     

Histogenesis of the taste buds of the vallate papilla in the in the rat in the postnatal stages of development

The developing taste buds of vallate papillae were studied with electron microscope in rats during the first 7 days after birth. Two types of cells--light and dark--are identified in the taste buds of a one day old animal. The apical parts of dark cells are characterized by numerous dark granules. A distinguishing feature of light cells is the presence of synaptic contacts with afferent intragemmal nerves. On the 4th day of development on the top of the apical parts of the cell, a microvillar apparatus is seen to form, which does not yet communicate with the oral cavity. On the 7th day, basal cells appear in the taste buds. Some of these cells are seen mitotically dividing. The differentiated microvillar apparatus now communicates with oral cavity. The structure of the taste buds is getting similar to that in the adults. The structural and functional peculiarities of the developing taste buds are discussed in association with the period of ontogenesis under consideration.     

Shh and Ptc are associated with taste bud maintenance in the adult mouse

In mammals, taste receptor cells are organized into taste buds on tongue. Taste buds are trophically maintained by taste neurons and under continuous renewal, even in adults. We found that the receptor for Sonic hedgehog (Shh), Patched1 (Ptc), was expressed around taste buds where cells were proliferating, and that Shh was expressed within basal cells of taste buds. Denervation caused the loss of Shh and Ptc expression before the degeneration of taste buds.     

Isolation of taste buds from the foliate papillae of the rabbit

Summary A method to isolate taste buds from the foliate papillae of the rabbit tongue is described. The method comprises (a) separation of the epidermis from the dermal layer after treatment with dilute acetic acid, and (b) mechanical removal of the taste buds from the epithelium with the use of a surgical needle. The procedure yields taste buds that are morphologically well preserved, and in quantities sufficient to enable a detailed biochemical characterization. Preliminary tests have shown the taste buds to have biochemical properties clearly distinct from those of the adjacent epithelium. The method may provide a basis for studying the molecular mechanism of taste perception in greater detail.On leave of absence from the Medical Research Centre, Polish Academy of Sciences, Warsaw, Poland.     

Chronic hypoxia alters calbindin D-28k immunoreactivity in lingual and laryngeal taste buds in the rat

The distribution and abundance of the calcium binding protein, calbindin D-28k (CB) immunoreactivity in the taste buds of the circumvallate papillae and larynx were compared between normoxic and chronically hypoxic rats (10% O2 for 8 weeks). In the normoxic rats, CB immunoreactivity was observed in some cells and fibers of the intragemmal region of the taste buds in the circumvallate papillae. In contrast, in the subgemmal region of the laryngeal taste buds, fibers but not cells were immunoreactive for CB. In chronically hypoxic rats, CB immunoreactive cells and fibers in the taste buds were decreased in the circumvallate papillae. In the laryngeal taste buds, the density of the subgemmal CB immunoreactive fibers in chronically hypoxic rats was greater than in normoxic rats. It is considered that function of the laryngeal taste buds is different from that of the lingual taste buds, so that laryngeal taste buds may be involved in chemosensation other than taste. The altered density of CB immunoreactive cells and fibers in the lingual and laryngeal taste buds is a predominant feature of hypoxic adaptation, and chronic hypoxic exposure might change the chemical sensitivity of the circumvallate papillae and larynx through the regulation of intracellular Ca2+.     

Location of taste buds in intact taste papillae by a selective staining method

Summary Taste buds were found to stain strongly and selectively in intact papillae with highly acidic dyes such as ponceau S. In intact tongues the taste buds in the fungiform, circumvallate and foliate papillae of the cynomolgus monkey and in the fungiform papillae of the rat as well as the taste discs in the fungiform papillae of the frog could be visualized. This method enables a rapid location and counting of taste buds in taste papillae without preparing histological sections. In cynomolgus tongue material fixed in formalin, the dyes penetrate into the buds. In fresh tongues only the taste pore region of the buds stains, which suggests that in vivo taste buds are impenetrable underneath the pore.     

Disc Electrophoresis of Extracts from the Taste Buds Located in Circumvallate Papillae of Rat Tongues

The epithelium of the circumvallate papillae of rat tongues was stripped off by treatment with 0.005% elastase in a state when many taste buds were present. The taste buds were isolated from the stripped epithelium by further treatment with 0.005% elastase and 0.08% trypsin. A protein which was thought to be characteristic of taste buds was found from semimicro disc polyacrylamide gel electrophoretic studies of the stripped epithelia with and without taste buds. This result was supported by micro disc polyacrylamide gel electrophoretic studies of isolated taste buds.     

Location of taste buds in intact taste papillae by a selective staining method.

Taste buds were found to stain strongly and selectively in intact papillae with highly acidic dyes such as ponceau S. In intact tongues the taste buds in the fungiform, circumvallate and foliate papillae of the cynomolgus monkey and in the fungiform papillae of the rat as well as the taste discs in the fungiform papillae of the frog could be visualized. This method enables a rapid location and counting of taste buds in taste papillae without preparing histological sections. In cynomolgus tongue material fixed in formalin, the dyes penetrate into the buds. In fresh tongues only the taste pore region of the buds stains, which suggests that in vivo taste buds are impenetrable underneath the pore.     

Cytokeratin 14 is expressed in immature cells in rat taste buds

We analyzed the differentiation of taste bud cells, by precisely describing expression profiles of cytokeratins (CKs) 8 and 14 in relation to those of marker molecules including label of 5-bromo-2′-deoxy uridine (BrdU) injected. In rat circumvallate papillae, cell division was observed at the basal layer of the epithelium expressing CK14 and located outside taste buds. The progenitor cells began to migrate toward the apical surface and maintained CK14 expression at 1 day after BrdU injection (day 1). On the other hand, a minor population of newly divided cells was infrequently incorporated into taste buds and also maintained CK14 expression at day 1. In taste buds, the conversion of CK subtypes occurred from CK14 to cytokeratin 8 (CK8) at day 2–3, showing the differentiation from immature cells expressing CK14 into mature or maturing cells expressing CK8. Functionally matured cells such as taste receptor cells expressing inositol triphospate receptor type 3 (IP₃R3) never expressed CK14, suggesting that CK14 would be expressed only in immature cells. On the other hand, a small but distinct population of BrdU-positive cells still showed CK14 immunoreactivity in taste buds even at day 12, which might correspond to the cells that remain undifferentiated for a long period within taste buds.