Lack of functional and morphological susceptibility of the greater superficial petrosal nerve to developmental dietary sodium restriction

Restriction of dietary sodium during gestation has major effects on taste function and anatomy in the offspring. The chorda tympani nerve of offspring that are maintained on sodium-reduced chow throughout life (NaDep) has reduced neurophysiological responses to sodium and altered morphology of its terminal field in the nucleus of the solitary tract. There are many anatomical and physiological similarities between the chorda tympani nerve that innervates taste buds on the anterior tongue and the greater superficial petrosal nerve (GSP) that innervates taste buds on the palate. To determine if the GSP is similarly susceptible to the effects of dietary sodium restriction, the present study examined neurophysiological responses and the terminal field of the GSP in NaDep and control rats. Neurophysiological responses of the GSP to a variety of sodium and non-sodium stimuli did not differ between NaDep and control rats. Furthermore, the volume and shape of the GSP terminal field in the nucleus of the solitary tract did not differ between the groups. Therefore, despite the high degree of functional and anatomical correspondence between the chorda tympani nerve and the GSP, the GSP does not appear to be susceptible to the effects of lifelong dietary sodium restriction.     

Rapid changes in gustatory function induced by contralateral nerve injury and sodium depletion

The combination of dietary sodium depletion and unilateral chorda tympani (CT) nerve section decreases sodium taste function in the intact CT nerve. However, functional changes have not been examined prior to day 4 postsectioning, even though degenerative and inflammatory responses are robust during that period. Rats received unilateral CT section and/or dietary sodium depletion, accomplished by 2 injections of furosemide and a sodium-restricted diet, on day 0. Surgical controls received sham nerve sectioning. At days 1, 2, 3, or 4, taste responses were recorded from the intact nerve. Functional changes were rapid and unexpected. At day 1 postsectioning, neural responses from the uninjured CT of both control-fed and sodium-depleted animals were reduced. By day 2, however, normal function was restored in control-fed rats, whereas functional deficits persisted in depleted animals. Sodium depletion alone also induced a transient decrease in sodium responses at days 2-3 after furosemide injection. These results demonstrate that distant neural injury can elicit gustatory plasticity regardless of the dietary environment, but normal responses can be restored. We suggest that neutrophils mediate the initial postinjury deficits in taste function, whereas macrophages promote the recovery of normal function.     

Mercury and cadmium induced structural alterations in the taste buds of the fish Alburnus alburnus

The ultrastructural damages of the taste buds of the fish, Alburnus alburnus were studied after applying 0.05 microM and 0.5 microM mercury chloride as well as 0.1 microM and 1 microM cadmium chloride. The most conspicuous alterations were induced during the first week of heavy metal exposition. The main structural alterations are: 1) the swelling of sensory microvilli and cilia; 2) the extreme dilation of the rER tubules and nuclear membranes, which is most expressed after cadmium exposition; 3) the increase in the number of lysosomes and dens bodies, which is more expressed after mercury exposition; 4) the swelling of the innervating nerve fibres at the synaptic areas of the taste buds, especially after mercury exposition. The damaging processes induced by the applied dose of heavy metals did not increase after the first week of exposition. The taste buds showed regenerated structural appearance after two weeks of exposition to 1 microM CdCl2, while the evoked structural alterations could be detected even after two weeks of exposition to 0.5 microM HgCl2.     

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.     

Time course of morphological alterations of fungiform papillae and taste buds following chorda tympani transection in neonatal rats

The time course of structural changes in fungiform papillae was analyzed in rats that received unilateral chorda tympani nerve transection at 10 days of age. Morphological differences between intact and denervated sides of the tongue were first observed at 8 days postsection, with an increase in the number of fungiform papillae that did not have a pore. In addition, the first papilla with a filiform-like appearance was noted on the denervated side at 8 days postsectioning. By 11 days after surgery, the total number of papillae and the number of papillae with a pore were significantly lower on the transected side of the tongue as compared to the intact side. At 50 days postsection, there was an average of 70.5 fungiform papillae on the intact side and a mean of only 20.8 fungiform papillae the denervated side. Of those few remaining papillae on the cut side, an average of 13.5 papillae were categorized as filiform-like, while no filiform-like papillae occurred on the intact side. Significant reduction in taste bud volume was noted at 4 days posttransection and further decrements in taste bud volume were noted at 8 and 30 days postsection. Electron microscopy of the lingual branch of the trigeminal nerve from adult rats that received neonatal chorda tympani transection showed normal numbers of both myelinated and unmyelinated fibers. Thus, in addition to the well-characterized dependence of taste bud maintenance on the chorda tympani nerve, the present study shows an additional role of the chorda tympani nerve in papilla maintenance during early postnatal development.     

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.     

Early dietary sodium restriction disrupts the peripheral anatomical development of the gustatory system

Dietary sodium restriction has profound effects on the development of peripheral taste function and central taste system anatomy. This study examined whether early dietary sodium restriction also affects innervation of taste buds. The number of geniculate ganglion cells that innervate single fungiform taste buds were quantified for the midregion of the tongue in two groups of rats: those fed either a low-sodium diet and those fed a sodium replete diet (control rats) from early prenatal development through adulthood. The same mean number of ganglion cells in developmentally sodium-restricted and control adult rats innervated taste buds on the midregion of the tongue. However, the characteristic relationship of the larger the taste bud, the more neurons that innervate it did not develop in sodium-restricted rats. The failure to form such a relationship in experimental rats was likely due to a substantially smaller mean taste bud volume than controls and probably not to changes in innervation. Further experiments demonstrated that the altered association between number of innervating neurons and taste bud size in restricted rats was reversible. Feeding developmentally sodium-restricted rats a sodium replete diet at adulthood resulted in an increase in taste bud size. Accordingly, the high correlation between taste bud volume and innervation was established in sodium-replete rats. Findings from the current study reveal that early dietary manipulations influence neuron-target interactions; however, the effects of dietary sodium restriction on peripheral gustatory anatomy can be completely restored, even in adult animals.     

Nerve regeneration-induced recovery of quinine avoidance after complete gustatory deafferentation of the tongue

The concentration-dependent decrease in quinine licking by rats is substantially attenuated by combined bilateral transection of the chorda tympani (CT) and glossopharyngeal (GL) nerves, but transection of either nerve alone produces marginal impairments at most. Here we tested whether regeneration of one or both of these nerves after combined transection would result in recovery of taste avoidance. Water-restricted rats were presented with a series of brief-access (5 s) taste trials (water and 0.003-3.0 mM quinine-HCl) in a 5-day test block of 40-min sessions both before nerve transection and starting 75-77 days after transection. Licking avoidance returned to presurgical levels when both nerves were allowed to regenerate. When only the GL was allowed to regenerate, performance did not differ from that of sham-transected animals. This suggests that even after considerable gustatory deafferentation, regeneration has the capacity to restore normal taste-guided behavior. Surprisingly, when only the CT was allowed to regenerate, avoidance behavior was severely impaired and was not different from that of rats in which regeneration of both nerves was prevented. Taking into account prior findings, it appears that the absence of the GL in the presence of an intact CT is fundamentally different from the absence of the GL in the presence of a regenerated CT with respect to some taste functions. This represents the first reported instance to our knowledge in which the capacity of a regenerated nerve to maintain taste-guided behavior was distinctly different from that of an intact nerve in a rodent model.     

Developmental changing of rat taste responses from chorda tympani nerve

In order to clarify developmental changing of gustatory system, histological and electrophysiological experiments were performed in the rat. Histological examination on the anterior tongue innervated by chorda tympani nerve showed that the ratio of matured taste buds which possess a taste pore were only 9% of all taste buds observed at 1 week of postnatal age, and 81.3% at 3 weeks of age. Recording integrated responses from the chorda tympani nerve reveals that taste buds with a pore at 1 week of age responded to NaCl, HCl, and quinine-HCl as well as in adult rats, which suggests that these relatively young taste buds are matured functionally for these three stimuli. However, the response magnitudes for various sugars at 1 week of age were smaller compared to those in the adult rat, reached to the maximum at 3 weeks of age, then decreased gradually with age. Also, results from the experiment of cross-adaptation among different sugars, effects of pronase-E treatment of the tongue, analysis of correlation between on- and off-responses to sugars, showed that qualitative changes for sugar responses continues after 3 weeks of age. These results suggest that functional changes occur in the gustatory processing of sugars during postnatal development in the rat chorda tympani nerve.     

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     

Calbindin D28k-like immunoreactivity in the developing and regenerating circumvallate papilla of the rat

The distribution of calbindin D28k (CB)-like immunoreactivity (-LI) in the circumvallate papilla (CVP) was examined during development and regeneration following bilateral crush injury to the glossopharyngeal nerve in the rat. In the adult CVP, CB-like immunoreactive (-IR) nerve fibers were observed in the subgemmal region and some penetrated into the taste buds. CB-LI was also detected in the cytoplasm of the spindle-shaped gustatory cells in the lower half of the trench epithelium, which contained numerous synaptic vesicles and bundles of intermediate filaments. These CB-IR gustatory cells made synapse-like contacts with CB-IR nerve terminals. Some CB-IR nerve terminals made contacts with the gustatory cells negative for CB-LI. At least three developmental stages were defined with regard to the developmental changes in the distribution of CB-LI: (1) Stage I (embryonic day (E) 18–postnatal day (P)5): CB-IR nerve fibers appeared in the lamina propria just beneath the newly-formed CVP at E18, but the gustatory epithelium of the CVP contained no CB-IR structures. Taste buds with taste pores appeared at P1. (2) Stage II (P5–10): thin CB-IR nerve fibers began entering the trench epithelium, but no CB-IR cells were observed. (3) Stage III (P10–adult): in addition to the intragemmal and perigemmal CB-IR nerve fibers, very few CB-IR cells appeared in the taste buds around P10, and their numbers increased progressively. The changes in the distribution of taste buds and CB-LI following glossopharyngeal nerve injury were similar to those observed during development. On post-operative day (PO) 4, the taste buds and CB-IR cells decreased markedly in number. These CB-IR cells became round in shape, and the number of CB-IR nerve fibers decreased markedly. On PO8, both taste buds and CB-IR cells disappeared completely. The regenerated taste buds were first observed on PO12, increased rapidly in number by PO20, and increased slowly thereafter. CB-IR nerve fibers accumulated at the subgemmal region and began penetrating into the trench wall epithelium around PO16. CB-IR cells appeared between PO20 and PO24, and their numbers increased progressively and reached the normal level on PO40. The topographical localizations of the taste buds and CB-IR cells during development and regeneration were comparable to those of normal animals. The delay of the time courses for appearance of CB-IR nerve fibers and CB-IR cells compared to the appearance of taste buds during development and regeneration suggests that CB in the gustatory epithelium may participate in the survival of the taste bud cells rather than in the induction of the taste buds.     

Effect of food deprivation on histomorphology and cholinesterase activity of taste buds in ratst

The histomorphology and cholinesterase activity of the taste buds and the gustatory nerve fibre sin well-fed, in protein and protein-calorie deficient rats have been investigated. The nerve fibre arborisation in the taste buds is predominantly nonmyelinated and shows degenerative changes ranging from initial swelling to disintegration, fragmentation and finally complete disappearance with the increasing degree and duration of food deprivation. Coincident with these changes in the nerve fibre, the taste bud also shows various stages of degeneration. By contrast, the cholinesterase activity in the gustatory papillae shows an initial increase during the first week followed by a decline in the activity during the succeeding weeks; a second peak of cholinesterase activity appears during 4–6 weeks. The cholinesterase activity is barely detectable after the 8th week. In the more severely protein calorie restricted groups, the cholinesterase changes are more pronounced and abrupt in onset and show a total disappearance by 4–5 weeks.     

Changes in the cell population of taste buds during degeneration and regeneration of their sensory innervation

Summary Taste buds of rabbit foliate papillae were observed in control, after denervation and during reinnervation by the glossopharyngeal nerve. In control, taste bud cells could be divided into three groups according to their shapes and staining characteristics. Most of the cells were identified as either dark (corresponding to gustatory) or light (corresponding to supporting) cells. However, some cells were encountered which could not readily be placed in either group; they have been termed intermediate cells. Nine to twelve hours after axotomy, wandering cells were observed in many of the taste buds. Thereafter taste buds gradually decreased in size and disappeared, for the most part, by the 14th postoperative day. It was found that dark cells disappeared first, then at a later stage the light cells also disappeared. During reinnervation, dark cells were first to appear about 40 days after the operation and light cells were not seen till about 9 days later.From the observations, it is concluded that the dark cells of the taste bud differentiate from epithelial cells under the influence of nerves and mature into light cells through intermediate cells.     

Different responsiveness of the chorda tympani and glossopharyngeal nerves to L-lysine in mice

Differential taste responsiveness and functional role of thetwo taste nerves, the chorda tympani (CT) and die glossopharyngeal(GL), were studied in mice by examining neural and behavioralresponses to an essential amino acid, L-lysine (Lys). Relativeresponses to Lys were larger in the GL than in the CT nerve.The neural threshold for the Lys response was about 2.5 logunits lower in the GL (about 1.0 µM) than in the CT nerve(about 300 µM). An analysis of concentration-responserelationships suggests a possibility that there are two differentreceptors (high and low affinity types) for Lys showing differentdissociation constants. The posterior tongue region possessesboth types, while the anterior region possesses only the lowaffinity type. Behavioral aversion threshold for Lys in intact mice, measuredby use of a single bottle test, was about 1.0 µM. Thisthreshold was the same as its neural threshold in the GL nerve.Animals whose bilateral GL nerves were sectioned showed a higheraversion threshold (about 300 µM) which was the same asthe neural threshold in the CT nerve. An aversion conditionedto Lys significantly generalized to L-arginine in the intactand CT-denervated mice, and L-arginine and L-histidine in theGL-denervated mice, but the generalization pattern across varioustaste stimuli including the four basic taste stimuli (NaCl,HCl, quinine HCl and sucrose) did not prominently differ amongthe intact, the GL-denervated and CT-denervated mice. These results suggest that taste sensitivity to Lys is higherin the GL than in the CT nerve, but taste quality informationfor Lys conveyed by two taste nerves is not largely different.     

Building sensory receptors on the tongue

Neurotrophins, neurotrophin receptors and sensory neurons are required for the development of lingual sense organs. For example, neurotrophin 3 sustains lingual somatosensory neurons. In the traditional view, sensory axons will terminate where neurotrophin expression is most pronounced. Yet, lingual somatosensory axons characteristically terminate in each filiform papilla and in each somatosensory prominence within a cluster of cells expressing the p75 neurotrophin receptor (p75NTR), rather than terminating among the adjacent cells that secrete neurotrophin 3. The p75NTR on special specialized clusters of epithelial cells may promote axonal arborization in vivo since its over-expression by fibroblasts enhances neurite outgrowth from overlying somatosensory neurons in vitro. Two classical observations have implicated gustatory neurons in the development and maintenance of mammalian taste buds—the early arrival times of embryonic innervation and the loss of taste buds after their denervation in adults. In the modern era more than a dozen experimental studies have used early denervation or neurotrophin gene mutations to evaluate mammalian gustatory organ development. Necessary for taste organ development, brain-derived neurotrophic factor sustains developing gustatory neurons. The cardinal conclusion is readily summarized: taste buds in the palate and tongue are induced by innervation. Taste buds are unstable: the death and birth of taste receptor cells relentlessly remodels synaptic connections. As receptor cells turn over, the sensory code for taste quality is probably stabilized by selective synapse formation between each type of gustatory axon and its matching taste receptor cell. We anticipate important new discoveries of molecular interactions among the epithelium, the underlying mesenchyme and gustatory innervation that build the gustatory papillae, their specialized epithelial cells, and the resulting taste buds.     

Phagocytic Cells in the Taste Buds of Rat Circumvallate Papillae after Denervation

Phagocytic cells in the taste buds of rat circumvallate papillaeafter the sectioning of bilateral glossopharyngeal nerves wereexamined by electron microscopy and immunohistochemistry. Electronmicrographs taken 1 day after denervation revealed that flat-shapedcells were present just beneath the taste buds and that theircellular processes extended toward the debris from the degeneratingtaste buds. At 2–6 days after denervation, long and thinprocesses of the flat cells surrounded the debris and appearedto have taken them up into the cytoplasm as small vesicles.Evidence for phagocytosis by the flat cells was seen up to 9days after denervation and again at 24 and 40 days, in correlationto the degeneration and regeneration of the taste buds. Pre-embeddingimmunohistochemistry using anti-vimentin antibody showed thatflat cells strongly reacted with vimentin. Light microscopicimmunohistochemistry using anti-macrophage antibodies (ED1,ED2) showed that throughout the post-operative days macrophageswere not present underneath or within the taste buds. Most ofthe ED2-immunoreactive resident macrophages were located inthe deep layer of connective tissue, and a few were found inthe nerve bundle. ED1-immunoreactive cells were seen in theduct cells of von Ebner's glands and a few were in the trenchwall of circumvallate papillae; however, they were also immunoreactivefor anti-OX62 antibody, which recognizes dendritic cells. Theresults indicate that the phagocytic cells of the taste budsare fibroblasts, not macrophages. Moreover, resident macrophagesparticipate in phagocytosis of degenerated nerves together withSchwann cells. Chem. Senses. 21: 467–476, 1996.     

Effect of sensory and sympathetic denervation of the frog tongue on the catecholamine containing cells of the taste buds]

The structure of catecholamine-containing dumb-bell shaped cells of the taste buds was studied by luminescent microscopy in the epithelial layer of the frog's tongue (Rana temporaria). On the unilateral section of the lingual nerve, a maintained adrenergic innervation of vessels and of the epithelium was observed, a decreased number of dumb-bell shaped cells in the taste bud, and their significant enlargement, and increased cathecholamine luminescence. With desympathization, no adrenergic nerves were observed on the vessels and the epithelium of the tongue. The size of the taste buds in desympathized cells of the tongue is sharply decreased and their number is increased. There is a tendency to grouping of the dumbbell shaped cells into 3--4 taste buds in one fungiform papillina. The experiments with sensory and sympathetic denervation of the frog tongue distinctly showed the trophic action of sensory and sympathetic nerves on the taste organ of the frog.     

Chorda tympani nerve transection at different developmental ages produces differential effects on taste bud volume and papillae morphology in the rat

Chorda tympani nerve transection (CTX) results in morphological changes to fungiform papillae and associated taste buds. When transection occurs during neonatal development in the rat, the effects on fungiform taste bud and papillae structure are markedly more severe than observed following a comparable surgery in the adult rat. The present study examined the potential "sensitive period" for morphological modifications to tongue epithelium following CTX. Rats received unilateral transection at 65, 30, 25, 20, 15, 10, or 5 days of age. With each descending age at the time of transection, the effects on the structural integrity of fungiform papillae were more severe. Significant losses in total number of taste buds and filiform-like papillae were observed when transection occurred 5-30 days of age. Significant reduction in the number of taste pores was indicated at every age of transection. Another group of rats received chorda tympani transection at 10, 25, or 65 days of age to determine if the time course of taste bud degeneration differed depending on the age of the rat at the time of transection. Taste bud volumes differed significantly from intact sides of the tongue at 2, 8, and 50 days post-transection after CTX at 65 days of age. Volume measurements did not differ 2 days post-transection after CTX at 10 or 25 days of age, but were significantly reduced at the other time points. Findings demonstrate a transitional period throughout development wherein fungiform papillae are highly dependent upon the chorda tympani for maintenance of morphological integrity.