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.     

Afferent and efferent components of the facial nerve in the bullfrog (Rana catesbeiana).

The afferent and efferent components of the facial nerve were traced within the brain stem of Rana catesbeiana, using three different neuroanatomical techniques. Primary afferent fibers could be traced to the spinal tract of trigeminal nerve and to fasciculus solitarius as far caudally as the first or second spinal segment, using silver degeneration methods. Cobalt filling of of the entire nerve showed the same distribution of afferent fibers, as well as the filling of the cells within the mesencephalic nucleus of trigeminal, indicating the origin of a proprioceptive component of the facial nerve. Cobalt iontophoresis and horseradish perioxidase experiments showed that the motor nucleus of the facial nerve was located just ventral to the fourth ventricle, and caudal to the motor nucleus of trigeminal. The distribution of afferent fibers to fasciculus solitarius and the spinal tract of trigeminal is similar in some respects to the distribution of afferent fibers from the trigeminal and vagal nerves in the bullfrog. The afferent fibers from the three cranial nerves are found as far caudally in the brain stem as the second spinal segment.     

Innervation of developing human taste buds. An immunohistochemical study

 Morphological changes in developing human gustatory papillae during the 6th to the 23rd postovulatory week have been studied. The general innervation pattern of taste papillae and taste bud primordia was revealed immunohistochemically using antibodies against protein gene product 9.5 (PGP9.5), neurofilament H (NFH), neurofilament L (NFL), neurone-specific enolase (NSE), and tubulin. The autonomic and somatosensory nerve supply has been investigated using antibodies against substance P (SP), calcitonin gene-related peptide (CGRP), tyrosine hydroxylase (TH), neuropeptide Y (NPY), the neuronal form of nitric oxide synthase (n-NOS), and, enzyme histochemically, NADPH-diaphorase. Nerve fibers approach the basal membrane of the lingual epithelium around the 7th postovulatory week and invade the epithelium of papilla-like structures at the 8th week, but some also penetrate the basal membrane of the non-papillary epithelium. They are in close contact with slender epithelial cells that are considered to be the taste bud’s progenitor cells. Early human taste buds situated at the anterior part of the tongue do not necessarily require a dermal (later fungiform) papilla. The NADPH-diaphorase reaction revealed positive results in dermal nerve fibers, but the immunohistochemical reaction against n-NOS was negative. Immunohistochemical detection of neuropeptides and vasoactive substances rendered negative results for developmental stages of 7–18 postovulatory weeks. By the 18th week, only SP was detected in dermal papillae, but not in the vicinity of taste buds’ primordia. Thus, autonomic and somatosensory nerves seem not to play a key role in formation and maintenance of early human taste buds. Accepted: 31 July 1997     

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.     

Splenic primary sensory afferents in the guinea pig demonstrated with anterogradely transported wheat-germ agglutinin conjugated to horseradish peroxidase

Summary The distribution of primary visceral afferents to the spleen of the guinea pig was studied after injections of wheat-germ agglutinin conjugated to horseradish peroxidase (HRP) into the left dorsal root ganglia at levels T7–T12. After anterograde transport of the tracer, labeled fibers were found in the nerves around the splenic artery in the hilus region and in the splenic parenchyma. The majority of labeled fibers in the spleen were detected in the white pulp. HRP-positive fibers were also observed in the red pulp and in the trabeculae. The distribution of the HRP-labeled fibers was in part similar to those of substance P-immunoreactive and calcitonin gene-related peptide-immunoreactive nerve structures. The results show that the anterograde tracing technique can be used successfully to investigate splenic primary afferent innervation.     

Mechanical sensitivity of the facial nerve fibers innervating the anterior palate of the puffer,Fugu pardalis,and their central projection to the primary taste center

Mechanical and chemical sensitivity of the palatine nerve, ramus palatinus facialis, innervating the anterior palate of the puffer, Fugu pardalis, and their central projection to the primary taste center were investigated. Application of horseradish peroxidase (HRP) to the central cut end of the palatine nerve resulted in retrogradely labeled neurons in the geniculate ganglion but no such neurons in the trigeminal ganglion, suggesting that the palatine nerve is represented only by the facial component. Tracing of the facial sensory root in serial histological sections of the brain stem suggested that the facial sensory nerve fibers project only to the visceral sensory column of the medulla. Peripheral recordings from the palatine nerve bundle showed that both mechanical and chemical stimuli caused marked responses. Mechanosensitive fibers were rather uniformly distributed in the nerve bundle. Intra-cranial recordings from the trigeminal and facial nerves at their respective roots revealed that tactile information produced in the anterior palate was carried by the facial nerve fibers. Elimination of the sea water current over the receptive field also caused a marked response in the palatine nerve bundle or facial nerve root while this did not cause any detectable responses in the trigeminal nerve root. Single fiber analyses of the mechanical responsiveness of the palatine nerve were performed by recording unit responses of 106 single fibers to mechanical stimuli (water flow), HCl (0.005 M), uridine-5'-monophosphate (UMP, 0.001 M), proline (0.01 M), CaCl2 (0.5 M), and NaSCN (0.5 M). All these fibers responded well to one of the above stimuli; however, most taste fibers did not respond well to the inorganic salts. The palatine fibers (n = 36), identified as mechanosensitive, never responded to any of the chemical stimuli, whereas chemosensitive fibers (n = 70) did not respond to mechanical stimuli at all. The chemosensitive units showed a high specificity to the above stimuli: they tended to respond selectively to hydrochloric acid, UMP, or proline. The responses of the mechanosensitive units consisted of phasic and tonic impulse trains and the sensitivity of the units varied considerably. The results reveal that the facial nerve fibers innervating the anterior palate of the puffer contain two kinds of afferent fibers, chemosensory and mechanosensory respectively, and suggest that the convergence of the tactile and gustatory information first occurs in the neurons of the primary gustatory center in the medulla.     

Participation of the fibers of the lingual nerve in the transmission of mechanosensitive information from the tongue and oral cavity of the cat]

The role of the lingual nerve fibers in the transmission of mechanosensory information from the receptors of the tongue and oral cavity of a cat was studied. A chart of the afferent innervation of both mechanosensory surfaces of the tongue (dorsal and ventral surfaces) with fibers of the anterior medial and posterior branches of the lingual nerve was drawn up on the basis of the experimental material. Different ratios of the mechanoreceptor reactions were described.     

Rat gustatory neurons in the geniculate ganglion express glutamate receptor subunits

Taste receptor cells are innervated by primary gustatory neurons that relay sensory information to the central nervous system. The transmitter(s) at synapses between taste receptor cells and primary afferent fibers is (are) not yet known. By analogy with other sensory organs, glutamate might a transmitter in taste buds. We examined the presence of AMPA and NMDA receptor subunits in rat gustatory primary neurons in the ganglion that innervates the anterior tongue (geniculate ganglion). AMPA and NMDA type subunits were immunohistochemically detected with antibodies against GluR1, GluR2, GluR2/3, GluR4 and NR1 subunits. Gustatory neurons were specifically identified by retrograde tracing with fluorogold from injections made into the anterior portion of the tongue. Most gustatory neurons in the geniculate ganglion were strongly immunoreactive for GluR2/3 (68%), GluR4 (78%) or NR1 (71%). GluR1 was seen in few cells (16%). We further examined if glutamate receptors were present in the peripheral terminals of primary gustatory neurons in taste buds. Many axonal varicosities in fungiform and vallate taste buds were immunoreactive for GluR2/3 but not for NR1. We conclude that gustatory neurons express glutamate receptors and that glutamate receptors of the AMPA type are likely targeted to synapses within taste buds.     

Lingual taste buds following application of colchicine to the glossopharyngeal nerve in the rat

Dissection of the glossopharyngeal nerve and application to it of colchicine that blocks axoplasmic drug transport were performed to study the effect of the nerves on the taste buds of foliate lingual papillae. It was observed that colchicine application to the nerve gave rise to destruction of the taste buds. The process of destruction proceeded more slowly as compared to that induced by nerve dissection. Colchicine application led to changes in the protein spectrum of the epithelium of foliate papillae. The absence of changes in the protein spectrum of the epithelium of foliate papillae and the presence of nerve fibers in the epithelium of the taste buds on exposure to colchicine provide evidence against its direct toxic effect on the taste buds, giving rise to their destruction. The changes seen in the taste buds result from the blocked transport of factors that participate in neurotropic control of the taste buds.     

The origin of slow potentials on the tongue surface induced by frog glossopharyngeal efferent fiber stimulation

When the glossopharyngeal (GP) nerve of the frog was stimulated electrically, electropositive slow potentials were recorded from the tongue surface and depolarizing slow potentials from taste cells in the fungiform papillae. The amplitude of the slow potentials was stimulus strength- and the frequency-dependent. Generation of the slow potentials was not related to antidromic activity of myelinated afferent fibers in the GP nerve, but to orthodromic activity of autonomic post-ganglionic C fibers in the GP nerve. Intravenous injection of atropine abolished the positive and depolarizing slow potentials evoked by GP nerve stimulation, suggesting that the slow potentials were induced by the activity of parasympathetic post-ganglionic fibers. The amplitude and polarity of the slow potentials depended on the concentration of adapting NaCl solutions applied to the tongue surface. These results suggest that the slow potentials recorded from the tongue surface and taste cells are due to the liquid junction potential generated between saliva secreted from the lingual glands by GP nerve stimulation and the adapting solution on the tongue surface.     

Taste placodes are primary targets of geniculate but not trigeminal sensory axons in mouse developing tongue

Tongue embryonic taste buds begin to differentiate before the onset of gustatory papilla formation in murine. In light of this previous finding, we sought to reexamine the developing sensory innervation as it extends toward the lingual epithelium between E 11.5 and 14.5. Nerve tracings with fluorescent lipophilic dyes followed by confocal microscope examination were used to study the terminal branching of chorda tympani and lingual nerves. At E11.5, we confirmed that the chorda tympani nerve provided for most of the nerve branching in the tongue swellings. At E12.5, we show that the lingual nerve contribution to the overall innervation of the lingual swellings increased to the extent that its ramifications matched those of the chorda tympani nerve. At E13.0, the chorda tympani nerve terminal arborizations appeared more complex than those of the lingual nerve. While the chorda tympani nerve terminal branching appeared close to the lingual epithelium that of the trigeminal nerve remained rather confined to the subepithelial mesenchymal tissue. At E13.5, chorda tympani nerve terminals projected specifically to an ordered set of loci on the tongue dorsum corresponding to the epithelial placodes. In contrast, the lingual nerve terminals remained subepithelial with no branches directed towards the placodes. At E14.5, chorda tympani nerve filopodia first entered the apical epithelium of the developing fungiform papilla. The results suggest that there may be no significant delay between the differentiation of embryonic taste buds and their initial innervation.     

Are there efferent synapses in fish taste buds?

In fish, nerve fibers of taste buds are organized within the bud's nerve fiber plexus. It is located between the sensory epithelium consisting of light and dark elongated cells and the basal cells. It comprises the basal parts and processes of light and dark cells that intermingle with nerve fibers, which are the dendritic endings of the taste sensory neurons belonging to the cranial nerves VII, IX or X. Most of the synapses at the plexus are afferent; they have synaptic vesicles on the light (or dark) cells side, which is presynaptic. In contrast, the presumed efferent synapses may be rich in synaptic vesicles on the nerve fibers (presynaptic) side, whereas the cells (postsynaptic) side may contain a subsynaptic cistern; a flat compartment of the smooth endoplasmic reticulum. This structure is regarded as a prerequisite of a typical efferent synapse, as occurring in cochlear and vestibular hair cells. In fish taste buds, efferent synapses are rare and were found only in a few species that belong to different taxa. The significance of efferent synapses in fish taste buds is not well understood, because efferent connections between the gustatory nuclei of the medulla with taste buds are not yet proved.     

Evidence of sensory neurons in the wall of the small intestine revealed by horseradish peroxidase technique

Sensory neurons in the wall of the small intestine were studied by means of retrograde transport of horseradish peroxidase (HRP). After HRP injection into the mesenteric nerve trunks, peroxidase positive nerve cells were observed in the myenteric and submucous plexuses. Labeled cells of different shape and size were compared with neurones impregnated by silver nitrate. On the basis of HRP-labeled neurons it is concluded that some of the myenteric and submucous nerve cells send processes towards the celiac ganglia; these may correspond to afferent neurons in the wall of the small intestine.     

Fibroblast and epidermal growth factors modulate proliferation and neural cell adhesion molecule expression in epithelial cells derived from the adult mouse tongue

Lingual epithelial cells, including those of the taste buds, are regularly replaced by proliferative stem cells. We found that integrin beta(1), a keratinocyte stem cell marker, was expressed at the basal layer and taste buds of adult mouse tongue epithelium. We purified and cultured integrin beta(1)-positive cells (termed KT-1 cells), whose growth was stimulated by epidermal growth factor (EGF) and basic fibroblast growth factor (FGF-2). FGF-2 stimulation induced translocation of the FGF type I receptor (FGFR1) into nuclei, suggesting that the growth-stimulating effect of FGF-2 was mediated through FGFR1. EGF and FGF-2 also regulated cell surface expression of the neural cell adhesion molecule (N-CAM) in KT-1 cells. Anti-N-CAM antibody immunoreactivity was restricted to the gustatory epithelium and the nerves in the tongue epithelium, giving rise to the possibility that KT-1 may contain gustatory epithelial cells. KT-1 cells may thus be useful for analyzing the factors that regulate the growth and differentiation of lingual and gustatory epithelial cells in vitro.     

Developmental time course of peripheral cross‐modal sensory interaction of the trigeminal and gustatory systems

Few sensory modalities appear to engage in cross‐modal interactions within the peripheral nervous system, making the integrated relationship between the peripheral gustatory and trigeminal systems an ideal model for investigating cross‐sensory support. The present study examined taste system anatomy following unilateral transection of the trigeminal lingual nerve (LX) while leaving the gustatory chorda tympani intact. At 10, 25, or 65 days of age, rats underwent LX with outcomes assessed following various survival times. Fungiform papillae were classified by morphological feature using surface analysis. Taste bud volumes were calculated from histological sections of the anterior tongue. Differences in papillae morphology were evident by 2 days post‐transection of P10 rats and by 8 days post in P25 rats. When transected at P65, animals never exhibited statistically significant morphological changes. After LX at P10, fewer taste buds were present on the transected side following 16 and 24 days survival time and remaining taste buds were smaller than on the intact side. In P25 and P65 animals, taste bud volumes were reduced on the denervated side by 8 and 16 days postsurgery, respectively. By 50 days post‐transection, taste buds of P10 animals had not recovered in size; however, all observed changes in papillae morphology and taste buds subsided in P25 and P65 rats. Results indicate that LX impacts taste receptor cells and alters epithelial morphology of fungiform papillae, particularly during early development. These findings highlight dual roles for the lingual nerve in the maintenance of both gustatory and non‐gustatory tissues on the anterior tongue. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 76: 626–641, 2016     

Effects of antidromic activity in gustatory nerve fibers on taste disc cells of the frog tongue

Summary Antidromic electrical stimulation of the lingual branch of the glossopharyngeal (IX) nerve of the frog was carried out while recording intracellular potentials of taste disc cells.Antidromic activation of sensory fibers resulted in depolarization of cells of the upper layer of the disc and most commonly in hyperpolarization of the cells in the lower layer. These changes in potential exhibited latencies greater than 1 s (Fig. 3), and thus cannot be due to electrotonic effects of action potentials in terminals of IX nerve fibers, which have much shorter conduction times. These cell potentials also showed summation, adaptation and post-stimulus rebound (Figs. 3, 4).Depending upon the chemical stimulus used, antidromic activity produced either depression or enhancement of gustatory fiber discharge in response to taste stimuli (Fig. 5).Alteration of the resting membrane potential by current injection did not significantly modify the antidromically evoked potentials (Fig. 8), whereas chemical stimulation of the tongue did (Fig. 7), indicating that these potential changes are not the result of passive electrical processes.These experimental results indicate that the membrane potential of taste disc cells can be modified by antidromic activity in their afferent nerves. This mechanism may be responsible for peripheral interactions among gustatory units of the frog tongue.The research was supported in part by NIH grant NS-09168.     

Distribution of the facial nerve to taste receptors in the rat

The distribution of facial sensory axons to the tongue and palateof the rat was determined in relation to the spatial distributionof taste buds. Gross dissections and serial reconstruction ofsilverstained material revealed five divisions of the chorda-lingualnerve in the tongue and four divisions of the greater petrosalnerve in the palate. Axon counts were made in normal and de-efferentedchorda tympani and greater petrosal nerves from montages ofelectron micrographs. De-efferented facial nerves were preparedby intracranial section of the nervus intermedius and motorroot prior to sacrifice. Cell bodies were counted in the geniculateganglion and the total number of axon profiles in the chordatympani and greater petrosal nerves exceeded the number of ganglioncells by 30%. The greater petrosal nerves contained about threetimes as many profiles as the chorda tympani nerves with theprincipal disparity among unmyelinated axons. Taste bud numberson the palate and anterior tongue were nearly equivalent; however,their densities per unit of surface area varied 150 fold betweenregions. On the tongue, taste bud density seemed not to be correlatedwith the number of axons directed to a region as there was anearly linear distribution of axons from the base to the apex.     

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.     

Advances in Optical Tools to Study Taste Sensation

Taste sensation is the process of converting chemical identities in food into a neural code of the brain. Taste information is initially formed in the taste buds on the tongue, travels through the afferent gustatory nerves to the sensory ganglion neurons, and finally reaches the multiple taste centers of the brain. In the taste field, optical tools to observe cellular-level functions play a pivotal role in understanding how taste information is processed along a pathway. In this review, we introduce recent advances in the optical tools used to study the taste transduction pathways.