Membrane resistance change of the frog taste cells in response to water and Nacl

Enhancement of Gustatory Neural Responses by Parasympathetic Nerve in the Frog

The autonomic nervous system affects the gustatory responses in animals. Frog glossopharyngeal nerve (GPN) contains the parasympathetic nerve. We checked the effects of electrical stimulation (ES) of the parasympathetic nerves on the gustatory neural responses. The gustatory neural impulses of the GPNs were recorded using bipolar AgCl wires under normal blood circulation and integrated with a time constant of 1 s. Electrical stimuli were applied to the proximal side of the GPN with a pair of AgCl wires. The parasympathetic nerves of the GPN were strongly stimulated for 10 s with 6 V at 30 Hz before taste stimulation. The integrated neural responses to 0.5 M NaCl, 2.5 mM CaCl₂, water, and 1 M sucrose were enhanced to 130-140% of the controls. On the other hand, the responses for 1 mM Q-HCl and 0.3 mM acetic acid were not changed by the preceding applied ES. After hexamethonium (a blocker of nicotinic ACh receptor) was intravenously injected, ES of the parasympathetic nerve did not modulate the responses for all six taste stimuli. The mechanism for enhancement of the gustatory neural responses is discussed.

Chemosensory function of amphibian skin: integrating epithelial transport, capillary blood flow and behaviour

Terrestrial anuran amphibians absorb water across specialized regions of skin on the posterioventral region of their bodies. Rapid water absorption is mediated by the insertion of aquaporins into the apical membrane of the outermost cell layer. Water moves out of the epithelium via aquaglyceroporins in the basolateral membrane and into the circulation in conjunction with increased capillary blood flow to the skin and aquaporins in the capillary endothelial cells. These physiological responses are activated by intrinsic stimuli relating to the animals' hydration status and extrinsic stimuli relating to the detection of osmotically available water. The integration of these processes has been studied using behavioural observations in conjunction with neurophysiological recordings and studies of epithelial transport. These studies have identified plasma volume and urinary bladder stores as intrinsic stimuli that activate the formation of angiotensin II (AII) to stimulate water absorption behaviour. The coordinated increase in water permeability and capillary blood flow appears to be mediated primarily by sympathetic stimulation of beta adrenergic receptors, although the neurohypopyseal hormone arginine vasotocin (AVT) may also play a role. Extrinsic stimuli relate primarily to the ionic and osmotic properties of hydration sources. Toads avoid NaCl solutions that have been shown to be harmful in acute exposure, approx. 200-250 mm. The avoidance is partially attenuated by amiloride raising the hypothesis that the mechanism for salt detection by toads resembles that for salt taste in mammals that take in water by mouth. In this model, depolarization of the basolateral membrane of taste cells is coupled to afferent neural stimulation. In toad skin we have identified innervation of skin epithelial cells by branches of spinal nerves and measured neural responses to NaCl solutions that elicit behavioural avoidance. These same concentrations produce depolarization of the basolateral membrane in isolated epithelial preparations. As with salt taste in mammals, the neural responses and depolarization of basolateral membrane potential are partially inhibited by amiloride. In addition, toads are more tolerant of sodium gluconate solution which is consistent with the phenomenon in mammalian taste physiology termed the anion paradox in which sodium salts with larger molecular weight anions produce a reduced intensity of salt taste. Finally, toads also avoid concentrated solutions of a non-electrolyte, mannitol, which differs from NaCl solutions in not affecting transepithelial conductance and requires a longer time to depolarize the basolateral membrane. Osmotic stimuli may mediate sensory processes for longer term detection of conditions with low water potential while ionic stimuli are more important for shorter term analysis of rehydration sources.

The receptor potential of frog taste cells in response to cold and warm stimuli

Temperature sensitivity of frog taste cells was studied. The taste cell designated Type thermosensitive (TS) I cell was depolarized by warm stimulus at 30 degrees C and hyperpolarized by cold stimulus at 10 degrees C. The taste cell designated Type TS II cell was depolarized by the cold stimulus and hyperpolarized by the warm stimulus. Menthol solution at 20 degrees C, which selectively activates transient receptor potential (TRP) M8 channels sensitive to cold stimuli, depolarized Type TS II cells but not Types TS I cells. Thermal stimuli-induced receptor potentials were all blocked by a nonselective cation channel blocker flufenamic acid. The results indicate that Type TS I cells have warm sensor channels alone, Type TS II cells have cold sensor channels alone and both the channels are a nonselective cation channel. The candidate of cold sensor channel in Type TS II cells is a TRPM8 channel and that of warm sensor channel in Type TS I cells is likely to be a TRPM4-like channel from the published data. In a subset of taste cells, Types TS III and TS IV cells were found. The former was depolarized by both cold and warm stimuli, but the latter was hyperpolarized by both stimuli. Types TS III and TS IV cells might have both TRPM4-like and TRPM8 channels. It is supposed that depolarizations induced by both cold and warm stimuli were dominant in Type TS III cells and hyperpolarizations induced by both the thermal stimuli were dominant in Type TS IV cells.

Electrical properties and gustatory responses of various taste disk cells of frog fungiform papillae

We compared the electrical properties and gustatory response profiles of types Ia cell (mucus cell), Ib cell (wing cell), and II/III cell (receptor cell) in the taste disks of the frog fungiform papillae. The large depolarizing responses of all types of cell induced by 1 M NaCl were accompanied by a large decrease in the membrane resistance and had the same reversal potential of approximately +5 mV. The large depolarizing responses of all cell types for 1 mM acetic acid were accompanied by a small decrease in the membrane resistance. The small depolarizing responses of all cell types for 10 mM quinine-HCl (Q-HCl) were accompanied by an increase in the membrane resistance, but those for 1 M sucrose were accompanied by a decrease in the membrane resistance. The reversal potential of sucrose responses in all cell types were approximately +12 mV. Taken together, depolarizing responses of Ia, Ib, and II/III cells for each taste stimulus are likely to be generated by the same mechanisms. Gustatory depolarizing response profiles indicated that 1) each of Ia, Ib, and II/III cells responded 100% to 1 M NaCl and 1 mM acetic acid with depolarizing responses, 2) approximately 50% of each cell type responded to 10 mM Q-HCl with depolarizations, and 3) each approximately 40% of Ia and Ib cells and approximately 90% of II/III cells responded to 1 M sucrose with depolarizations. These results suggest that the receptor molecules for NaCl, acid, and Q-HCl stimuli are equivalently distributed on all cell types, but the receptor molecules for sugar stimuli are richer on II/III cells than on Ia and Ib cells. Type III cells having afferent synapses may play a main role in gustatory transduction and transmission.

Chemosensory function of salt and water transport by the amphibian skin

Solute and water transport mechanisms of anuran skin mediate chemosensory functions that permit evaluation of ionic and osmotic properties of hydration sources in a manner similar to taste receptors in the mammalian tongue. Histochemical observations demonstrated apparent connections between spinal nerve endings and epithelial cells of the skin and we used neural and behavioral responses as measures of coupling between transport and chemosensation. The inhibition of transcellular Na+ transport by amiloride partially reduced the neural response and the avoidance of hyperosmotic NaCl but not KCl solutions. Cetylpyridinium chloride (CPC) reduced the neural response to hyperosmotic salt solutions, suggesting a chemosensory role for vanilloid receptors in the skin. Avoidance of hyperosmotic salt solutions was reduced by impermeant anions suggesting paracellular conductance is important for chemosensation. The effects of blocking the transcellular and paracellular pathways was additive but did not eliminate the avoidance of osmotically unfavorable solutions by dehydrated toads. The timing of the neural response to deionized water was similar to the onset of water absorption behavior and increased blood flow to the pelvic skin. Water absorption from 50 mM NaCl was greater than from deionized water when toads were fully immersed, but not when contact was limited to the ventral surface.

Electrophysiology of Necturus taste cells

Taste buds are sensory end organs that detect chemical substances occurring in foodstuffs and relay the relative information to the brain. The mechanisms by which the chemical stimuli are converted into biological signals represent a central issue in taste research. Our understanding of how taste buds accomplish this operation relies on the detailed knowledge of the biological properties of taste bud cells-the taste cells-and of the functional processes occurring in these cells during chemostimulation. The amphibian Necturus maculosus (mudpuppy) has proven to be a very useful model for studying basic cellular processes of vertebrate taste reception, some of which are still awaiting to be explored in mammals. The main advantages offered by Necturus are the large size of its taste cells and the relative accessibility of its taste buds, which can therefore be handled easily for experimental manipulations. In this review, I summarize the functional properties of Necturus taste cells studied with electrophysiological techniques (intracellular recordings and patch-clamp recordings). My focus is on ion channels in taste cells and on their role in signal transduction, as well as on the functional relationships among the cells inside Necturus taste buds. This information has revealed to be well suited to outline some of the general physiological processes occurring during taste reception in vertebrates, including mammals, and may represent a useful framework for understanding how taste buds work.

Coding in taste receptor cells. The early years of intracellular recordings

In the gustatory system, the mechanism of coding-the process of relaying the identity and intensity of the stimulus to the central nervous system-begins with the taste receptor cells. Ironically, although these are the first cells of the gustatory system to contact stimuli, they were the last from which neurophysiological recordings were obtained. How taste receptor cells decipher stimulus identity remains the subject of active research; its origins began with a series of intracellular studies. Prior to the first intracellular recording, it was unknown if taste receptor cells would be specialists, responding to only a single class of taste stimulus, or generalists, responding to multiple stimuli. The first reports established several major aspects of these cells' physiology. Taste receptor cells have varying response profiles to basic stimuli; they have obvious conductance changes during stimulation; they have low resting potentials. It became evident that multiple transduction schemes must underlie these responses, although the identity of these transduction schemes remained elusive. Additionally, these early recordings missed a major phenomenon-the presence of regenerative electrical events (i.e., the action potential) was not observed due to the low input resistance that accompanied this technique. Although intracellular recordings are essentially no longer used to study taste receptor cells, replaced by the superior method of patch-clamp recording, these early articles provided key insights into the then unknown electrical responses of taste receptor cells.

The frog taste disc: a prototype of the vertebrate gustatory organ

The frog taste disc (TD) is apparently the largest gustatory organ found in vertebrates and seems to differentiate into a specialized variety of the prototypic scheme of the taste bud. An explanation for this unusual organization is lacking although it is possible to speculate the existence of environmental and nutritional requirements. Up to the present time, the most common model of the TD was based on two main cell types (sensory and sustentacular). This model may oversimplify the morphology of this structure since more numerous cell types have been described. We now propose a new model of the TD, based on comprehensive data on the ultrastructure of the organ obtained in the last 20 years. The main conclusions are the following: (1) the TD is a pluristratified epithelium with a general organization similar to that of the olfactory and vomeronasal epithelium; (2) it has skeleton composed of three different types of epithelial cells; (3) the chemoreceptorial surface is covered by different microenvironments; (4) three different types of neuro-epithelial systems are present; the type II is an 'open' sensory cell with axonal contacts devoid of vesicles; the type III is an 'open' sensory cell with synaptic-like junctions; the type i.v. is a 'closed' sensory cell with a 'Merkel-neurite complex'; (5) the nerve fibers in the basal plexus are mostly cholinergic while the peridiscal nerve fibers are mostly peptidergic. The presence of several cell types in the TD must be considered using these large receptors in electrophysiological studies or as a source of isolated cells, and their complexity must induce caution in the interpretation of the data. Text books of histology usually describe the peripheral structures associated with taste as very simple: an idea that probably must be revised. A taste organ is a highly complex structure composed of several sensory systems and a comparative approach can aid comprehension of its general organization. The study of the 'large taste organs' present in some species of amphibians can provide useful data for knowledge of the gustatory system of vertebrates.

Receptor potential of the frog taste cell in response to bitter stimuli

Molecular mechanisms of generation of the receptor potential in the bullfrog taste cell for bitter stimuli were investigated with an intracellular recording technique. During generation of the receptor potential in response to bitter stimuli, the input resistance of the taste cell increased slightly. We could not find the reversal potential for the depolarizing receptor potential induced by quinine-HCl(Q-HCl). The Q-HCl-induced response was increased with decreasing Cl- concentration in the superficial fluid. The Q-HCl response was greatly reduced by interstitial furosemide, as a blocker of Na+/Cl- cotransport, indicating that a Na+/Cl- cotransport occurs through the basolateral membrane of Q-HCl sensitive taste cells. Therefore it is concluded that the receptor potential for Q-HCl stimulation is produced by an active secretion of intracellularly accumulated Cl- through Cl- pumps of the apical receptive membrane.

Application of serial sectioning and three-dimensional reconstruction to the study of taste bud ultrastructure and organization

The lingual taste buds of mammals are complex organs containing dozens of cells of varying morphology and numerous nerve fibers that are intermingled among the cellular processes. Some of the taste bud cells form synaptic contacts with these nerve fibers. Important questions remain to be answered regarding the structure and function of the cells of various types within taste buds and the means by which responses to gustatory stimuli are transmitted to the nerve fibers that communicate with the brain. Using both conventional and high voltage electron microscopy, we have examined serially sectioned taste buds from the tongues of mice and rabbits in order to address these issues and to obtain more complete information than that available from sampling of sections. The technique of computer-assisted 3-D reconstruction was used to generate models of whole taste buds and individual cellular and neural elements within taste buds from the serial sections. Analysis of serially sectioned taste buds from mice and rabbits has revealed that in both of these species relatively few (30% or less) of the cells within the taste buds form synaptic contacts with nerve fibers. In the foliate taste buds of rabbits, all of the cells that are presynaptic to nerve fibers are of a single morphological type (type III). The cells that are presynaptic to nerve fibers within the taste buds of mice are morphologically diverse. A pattern of synaptic connectivity exists within murine taste buds such that a given nerve fiber receives synaptic input only from taste cells that are ultrastructurally similar. In the taste buds of both mice and rabbits, we have observed both divergence and convergence of synaptic input from the putative taste receptor cells onto nerve fibers, suggesting that at the level of the taste bud there is some integration of the information generated by individual receptor cells. In addition to typical chemical synapses, other cytoplasmic specializations (such as subsurface cisternae and atypical mitochondria) may be involved in interactions between taste bud cells and nerve fibers.

The sense of taste: neurobiology, aging, and medication effects

The sense of taste is an oral chemical sense in mammals that is involved in the choice of foods. Initial transduction of taste stimuli occurs in taste buds, which are distributed in four discrete fields in the oral cavity. Medications can affect the taste buds and ion channels in taste-bud cell membranes involved in stimulus transduction. The sense of taste gradually declines with aging, with bitter taste most affected. Neural circuits that mediate taste in primates include cranial nerves VII, IX, and X, the solitary nucleus in the brain stem, the ventroposteromedial nucleus of the thalamus, and the insular-opercular cortex. The central taste pathways process taste information about sweet, salty, sour, and bitter stimuli serially and in parallel. Medications associated with "metallic" dysgeusia and taste losses affect the taste system via unknown mechanisms.

Morphology and distribution of the glossopharyngeal nerve afferent and efferent neurons in the Mexican salamander, axolotl: a cobaltic-lysine study

Cobaltic-lysine complex was used to label the afferent and efferent components of the glossopharyngeal nerve in the ganglion and brainstem of the Mexican salamander, axolotl (Ambystoma mexicanum). The distribution of afferent cell bodies in the combined glossopharyngeal-vagus ganglion (the IX-X ganglion) was reconstructed from serial sections, and the sizes of the cell bodies were measured. The central projection of afferents and the location of efferent cell bodies were determined by the tracer. The afferent cell bodies in the ganglion were medium-sized (ca. 25 microns). Cell bodies with a single process were seen. The ganglion was not clearly divided into superior and inferior ganglia, as is observed in mammals and frogs, but comprised a single ganglion. Labelled cells were diffusely distributed in the rostral part of the IX-X ganglion. A few labelled cells also were seen in the caudal part, where the vagus nerve fibers and cell bodies were mainly distributed. Double labellings of the glossopharyngeal and vagus nerves with HRP and cobaltic-lysine demonstrated that the ganglion cells of each nerve are not clearly separated in the IX-X ganglion. In the brainstem, the majority of afferent fibers formed thick ascending and descending limbs in the solitary fasciculus. The remaining afferent fibers formed a thin bundle in the spinal tract of the trigeminal nerve, which had a short ascending limb and a long descending limb. These two bundles had terminal areas in the ipsilateral brainstem: in the dorsal gray matter for the solitary fasciculus and in the lateral funiculus for the spinal tract of the trigeminal nerve, respectively. The cell bodies of the efferent neurons possessed developed dendritic arborizations in the ventrolateral white matter, and formed a longitudinal cell column in the ventrolateral margin of the gray matter. Thus, the glossopharyngeal nerve system in the axolotl assumes a primordial form in its ganglions, but its topographical organization in the brainstem is basically similar to that in anurans.

Water response of frog olfactory system is induced by a decrease in osmotic pressure

The frog olfactory response to deionized water (water response) was recorded from the olfactory bulb. The water response was suppressed by both electrolytes and non-electrolytes as a function of osmolarity, while the water response in taste cells was not suppressed by non-electrolytes. It was concluded that a decrease in osmotic pressure induced by application of deionized water is the origin of the water response in the frog olfactory system.

Mechanisms of chemosensory transduction in taste cells

The application of new techniques to the study of taste cells has revealed much about both the basic physiology of these cells and also about the mechanisms of taste transduction. The taste cells are electrically excitable cells with a variety of voltage-dependent ion currents. These ionic currents have an important role in the transduction of salt taste in mammals and frogs. In mudpuppies different ion channels are involved in the transduction of acidic-sour stimuli. The role of ion currents in the transduction of sweet taste is less clear. Some proposed mechanisms suggest an important role for ion currents and others suggest that the transduction process may be a biochemical event involving cell surface receptors and intracellular second messengers, possibly cAMP. The transduction of bitter taste seems to be a biochemical event involving cell surface receptors and intracellular second messengers in the inositol trisphosphate pathway. Thus, one cannot talk about "the mechanism" of taste transduction. Different taste modalities are transduced by different mechanisms. A corollary to this is that taste cells are not a homogeneous population of cells. In order to provide animals with the ability to discriminate between different taste modalities the taste cells consist of distinct subpopulations of cells based on their primary taste modality. The primary taste modality in a given cell is determined by the receptors and transduction mechanism(s) expressed in that cell. Evidence suggests that modality-specific receptors are expressed in a segregated manner in distinct subpopulations of taste cells. Secondary responses observed in gustatory axons may arise due to a lack of absolute specificity in the transduction processes and nonspecific effects of low pH and high ionic strength and osmolarity on the taste cells. An interesting area for future work will be to elucidate the mechanism(s) by which basal cells become committed to a given taste modality and how the gustatory neurons influence this process of differentiation. The involvement of the gustatory neurons is critical as they must synapse with taste cells of the correct taste modality to preserve the integrity of the information transferred to the CNS. This process of synaptogenesis is presumably mediated by the expression of taste-modality-specific, cell surface antigens on the basolateral domain of a taste cell and receptors on the appropriate neurons, but much work will be necessary to elucidate this process.(ABSTRACT TRUNCATED AT 400 WORDS)

Electrical responses of supporting cells in the frog taste organ to chemical stimuli

1. The mean resting potential of supporting cells in the frog taste organ was -19.1 mV. The supporting cells responded to the four basic taste stimuli with a depolarization but responded to water with a depolarization or a hyperpolarization. 2. The membrane resistances of supporting cells decreased during stimulation with sucrose, NaCl and acetic acid, but increased during stimulation with Q-HCl and water. 3. Reversal potential of the depolarizing response for 0.5 M NaCl in supporting cells was +7.6 mV. The depolarizing responses for Q-HCl and acetic acid were independent of the membrane potential level. 4. These results suggest that the characteristics of taste responses in supporting cells are similar to those in taste cells.

Mechanism of the water response in frog gustation: possible significance of surface potential

The frog taste response to deionized water (water response) after adaptation of the tongue to salts was recorded from the glossopharyngeal nerve under various conditions. It was found that the frog water response exhibits different behavior from the carp water response examined in a previous paper13. (a) The frog water response did not decline during stimulation and lasted for at least 3 min, while the carp water response declined within 10 s after stimulation to a spontaneous level. (b) The frog water response was practically independent of species and concentrations of salts in adapting solutions when the tongue was adapted to salts of monovalent cations, while the carp water response was highly dependent of salt concentration in adapting solution. (c) The water response was increased with an increase of CaCl2 concentration in adapting solution, while it was decreased with an increase of MgCl2 concentration. (d) The water response was suppressed by the presence of electrolytes in stimulating solution: the data obtained with different species of salts were described by a single curve as a function of the ionic strength. (e) The mechanism of the frog water response together with the carp water response was explained in terms of the surface potential.

Ionic basis of salt-induced receptor potential in frog taste cells

1. The ionic basis of the receptor potential elicited by salt stimuli in a frog taste cell was studied with intracellular microelectrodes and lingual artery perfusion. 2. The amplitudes of the receptor potentials induced by salts were decreased by 32-60% when interstitial Na+ and Ca2+ were replaced with choline+, tetramethylammonium+ and tetraethyl-ammonium+. 3. After removal of Na+ and Ca2+ from both interstitial and superficial fluids, the reversal potentials of NaCl induced receptor potentials changed depending upon the stimulus concentrations. 4. These results indicate that the direct influx of Na+ across the receptor membrane, as well as the influx of interstitial Na+ across the basolateral membrane, occurs during NaCl stimulation.

Ionic basis of receptor potential of frog taste cells induced by acid stimuli

1. The ionic mechanism underlying the receptor potential in frog taste cells induced by acid stimuli was studied with single microelectrodes by replacing superficial and interstitial fluids of the tongue with modified saline solutions. 2. The removal of Na+, Ca2+ and Cl- from the normal interstitial fluid did not affect the receptor potential induced by acid stimuli. Interstitial 100 mM-K+ saline did not affect the acid response. 3. The receptor potential was reduced greatly when Ca2+ was removed from the superficial saline, but was increased when the Ca2+ concentration was elevated. The removal of superficial Cl- did not affect the receptor potential. The receptor potential elicited by superficial Ca2+-free saline was partly due to Na+. Li+, K+, NH4+ or choline + substituted for Na+ in producing the receptor potential. The amiloride-sensitive Na+ channel on the receptor membrane did not contribute to the receptor potential. With pure water adaptation of the tongue surface, the mean magnitude of the acid response was 35% of the control. 4. The receptor potential was unaffected by superficial tetrodotoxin (TTX) but was blocked by superficial Ca2+ antagonists such as Co2+ and Cd2+. Sr2+ substituted for Ca2+ in generating the receptor potential. 5. The receptor potentials observed under various concentrations of superficial Ca2+ became smaller when Na+ was present in the superficial fluid, indicating a competition between Ca2+ and Na+. 6. It is concluded that a large portion of the receptor potential induced by acid stimuli is produced by cations passing through a tastant-gated Ca2+ channel on the taste receptor membrane. Both divalent (Ca2+, Sr2+) and monovalent (Na+, Li+, K+, NH4+, choline+) cations can pass through the Ca2+ channel. The other mechanism responsible for the remaining part of the receptor potential is discussed.

Ionic mechanism of generation of receptor potential in response to quinine in frog taste cell

The ionic mechanism of generation of the receptor potential in a frog taste cell elicited by quinine-HCl (Q-HCl) was studied with an intracellular recording technique by replacing the superficial and interstitial fluids of the tongue with various saline solutions. The taste cells whose receptor membranes were adapted to normal saline and deionized water generated depolarizing receptor potentials at Q-HCl concentrations higher than 2 and 0.01 mM, respectively. The input resistance of taste cell during Q-HCl stimulation scarcely changed. The receptor potential did not change even when the membrane potential level was broadly changed. The magnitude of the receptor potential was increased by reducing the concentration of superficial Cl- on the taste receptor membrane, but was independent to the concentration of superficial Na+. Injection of Cl- into a taste cell increased the receptor potential to 170%. The magnitude of receptor potential was decreased to 20-30% by removing interstitial Na+ or Cl- or both surrounding the basolateral membrane of taste cell. Furosemide (1 mM) added to the interstitial fluid decreased the receptor potential to 15%, while interstitial ouabain (0.1 mM) and superficial SITS (0.1 mM) did not influence it. From these results, we conclude: (1) an electroneutral Na+/Cl- cotransport occurs through the basolateral membrane of a taste cell in the resting state, so that Cl- accumulates inside the cell. (2) Q-HCl stimulation induces the active secretion of Cl- across the taste receptor membrane, resulting in a depolarizing receptor potential.

Membrane properties of isolated frog taste cells: three types of responsivity to electrical stimulation

The whole cell clamp technique was applied to an isolated frog taste cell to examine the detailed membrane properties. The electrical responses could be classified into 3 types. The taste cells of the active type generated a large spike potential under current clamp and a large early inward current followed by a small outward current. The taste cells of the inactive type did not generate a spike but showed a small inward current followed by a large outward current. The distribution of each type was 15, 70 and 15%, respectively.

Characteristics of the water response across the dorsal epithelium of frog tongue

1. Dorsal epithelium of the frog tongue produced a change in potential difference across the tissue in response to removal of NaCl from the adapting Ringer solution on the mucosa. 2. The response was not caused by an osmotic decrease in the stimulus, and its profile was in many respects similar to that of the receptor potential in frog taste cells. 3. In conclusion, the response may influence or modify water reception in frogs.

Depolarization induced by injection of cyclic nucleotides into frog taste cell

In order to identify the intracellular transmitter involved in the taste transduction process, cyclic nucleotides were iontophoretically injected into the frog taste cells while membrane potentials were recorded intracellularly. Injection of either cyclic GMP or cyclic AMP induced a depolarization response of about 5 mV in the taste cells, but injection of Cl- had no effect. The rate of a repolarization after the depolarization elicited by cyclic GMP was larger than that after cyclic AMP. The possible role of cyclic nucleotide in the taste transduction was discussed.

Patch-clamp study of isolated taste receptor cells of the frog

Taste discs were dissected from the tongue of R. ridibunda and their cells dissociated by a collagenase/low Ca/mechanical agitation protocol. The resulting cell suspension contained globular epithelial cells and, in smaller number, taste receptor cells. These were identified by staining properties and by their preserved apical process, the tip of which often remained attached to an epithelial (associated) cell. When the patch pipette contained 110 mM KCl and the cells were superfused with NaCl Ringer's during whole-cell recording, the mean zero-current potential of 22 taste receptor cells was -65.2 mV and the slope resistance 150 to 750 M omega. Pulse-depolarization from a holding voltage of -80 mV activated a transient TTX-blockable inward Na current. Activation became noticeable at -25 mV and was half-maximal at -8 mV. Steady-state inactivation was half-maximal at -67 mV and complete at -50 mV. Peak Na current averaged -0.5 nA/cell. The Ca-ionophore A23187 shifted the activation and inactivation curve to more negative voltages. Similar shifts occurred when the pipette Ca was raised. External Ni (5 mM) shifted the activation curve towards positive voltages by 10 mV. Pulse depolarization also activated outward K currents. Activation was slower than that of Na current and inactivation slower still. External TEA (7.5 mM) and 4-amino-pyridine (1 mM) did not block, but 5 mM Ba blocked the K currents. K-tail currents were seen on termination of depolarizing voltage pulses. A23187 shifted the IK(V)-curve to more negative voltages. Action potentials were recorded when passing pulses of depolarizing outward current. Of the frog gustatory stimulants, 10 mM Ca caused a reversible 5- to 10-mV depolarization in the current-clamp mode. Quinine (0.1 mM, bitter) produced a reversible depolarization accompanied by a full block of Na current and, with slower time-course, a partial block of K currents. Cyclic AMP (5 mM in the external solution or 0.5 microM in the pipette) caused reversible depolarization (to -40 to -20 mV) due to partial blockage of K currents, but only if ATP was added to the pipette solution. Similar responses were elicited by stimulating the adenylate cyclase with forskolin. Blockage of cAMP-phosphodiesterase enhanced the response to cAMP. These results suggest that cAMP may be one of the cytosolic messengers in taste receptor cells. Replacement of ATP by AMP-PNP in the pipette abolished the depolarizing response to cAMP.(ABSTRACT TRUNCATED AT 400 WORDS)

Passive and active membrane properties of mudpuppy taste receptor cells

1. Intracellular recordings were obtained from taste receptor cells and surface epithelial cells of isolated mudpuppy lingual epithelium. 2. Surface epithelial cells had a mean resting potential of -40.2 +/- 8.9 mV, a mean input resistance of 40.3 +/- 11.3 M omega, and a linear current-voltage (I-V) relationship. Taste receptor cells had a mean resting potential of -61.7 +/- 15 mV, a mean input resistance of 380.3 +/- 177.2 M omega, and the I-V relationship showed pronounced outward rectification; the outward rectification persisted in high-K+ saline, but was abolished by tetraethylammonium bromide (TEA). 3. Surface epithelial cells responded to depolarizing current injection with only passive membrane potential changes. Taste receptor cells responded to brief pulses of depolarizing current injection with regenerative action potentials characterized by an abrupt rising phase, an inflexion on the falling phase, and a prolonged after-potential. 4. The abrupt rising phase of the action potential was blocked by tetrodotoxin (TTX), suggesting that voltage-gated Na+ currents are responsible for the rising phase. 5. Long-duration action potentials were elicited from cells treated with TEA to block outward K+ currents and with TTX to block Na+ currents, and from cells bathed in isotonic CaCl2. These results suggest that the active membrane response contains a significant Ca2+ component. 6. The after-potential was blocked or greatly reduced by the addition of Ca2+ channel blockers to the bathing medium. In contrast, addition of TEA to the bathing medium greatly enhanced the after-potential. These data suggest that a significant portion of the after-potential is Ca2+ mediated. 7. The mean reversal potential for the after-potential (-76.8 +/- 6.0 mV) was significantly different from the mean reversal potential for the undershoot of the action potential (-86 +/- 5.6 mV). Superfusion with TEA reduced the reversal potential of the after-potential to -42.3 +/- 8.2 mV and abolished the undershoot. These results suggest that the after-potential results from at least two conductances, one which is blocked by TEA and the other which is Ca2+ dependent and involves ions other than, or in addition to K+. 8. Our data suggest that taste receptor cells, unlike surface epithelial cells, possess voltage-gated Na+, Ca2+, and K+ channels, as well as Ca2+-mediated channels. The role of the Ca2+ channels may be in part to regulate release of transmitter onto nerve terminals. The role of the other conductances in taste transduction is unknown.

Electrical response to hypotonic NaCl Ringer solution across the dorsal epithelium of the tongue of the frog, Rana catesbeiana

Stimulation with hypotonic NaCl Ringer solution produced a change in potential across the epithelium, which was not caused by decreased osmotic pressure. The potential profile resembled the receptor potential of frog taste cells and so may be related to water reception.

Different receptor sites for Ca2+ and Na+ in single water fibers of the frog glossopharyngeal nerve

Unitary discharges were recorded from single water-sensitive fibers (water fibers) of the frog glossopharyngeal nerve during stimulation of the tongue with chemical stimuli. Low CaCl2 (1 mM CaCl2) and relatively high NaCl (500 mM NaCl) are effective stimuli which excite water fibers. To learn whether or not Ca2+ and Na+ react with different receptor sites, a proteolytic enzyme was topically applied to the tongue dorsum. After treatment of the tongue with 0.05% pronase E, the magnitude of the NaCl response remained unchanged, but the magnitude of the CaCl2 response markedly decreased. The selective elimination by the pronase E treatment indicates that there exist different receptor sites for Ca2+ and Na+ in single water fibers of the frog glossopharyngeal nerve. The effect of pronase E treatment was due to the proteolytic action. The results suggest that the Ca2+ receptor site may be composed of a protein.

Electrical response to acid across the dorsal epithelium of the frog tongue

Acid stimulation produced a change in trans-epithelial potential difference across isolated dorsal epithelium of frog tongue. The responses to acetic acid, tartaric acid and citric acid were significantly greater than those to hydrochloric acid and nitric acid at the same pH. Metabolic inhibitors had no effect on the response, but local anaesthetics reversibly depressed it. The induced response was associated with a decrease in tissue resistance. Positive polarization on the mucosa increased the response, which was decreased or reversed under negative polarization. These responses may be caused by diffusion of H-ions through the tissue, and may influence sour reception in the frog.

Ultrastructure of mouse vallate taste buds. I. Taste cells and their associated synapses

The ultrastructural features of murine vallate taste bud cells and their associated synapses have been examined in thin and thick sections with conventional transmission electron microscopy and high-voltage electron microscopy. Computer-assisted reconstructions from serial sections were utilized to aid in visualization of taste bud cell-nerve fiber synapses. We have classified taste bud cells on the basis of previously established criteria-namely, size of the nucleus, shape and density of chromatin, density of cytoplasm, and presence or absence of dense-cored or clear vesicles, other cytoplasmic organelles, and synaptic foci. Both dark cells and light cells are present, as well as cells with intermediate morphological characteristics. Synapses were observed from taste bud cells onto nerve fiber processes. In virtually all instances, synapses are associated with the nuclear region of the taste cell. These synapses are characterized by the presence of 40-70 nm clear vesicles embedded in a thickened presynaptic membrane separated from the postsynaptic membrane by a 16-30 nm cleft. Synapses are not unique to any particular cell type. Dark, intermediate, and light cells all synapse onto nerve fibers. Two general types of synapses exist: spot (or macular) and fingerlike. In the latter, the postsynaptic region of the neuronal process protrudes into an invagination of the taste cell membrane. Differences in synaptic morphology are not correlated with taste cell type. In some cases a single taste cell was observed to possess both macular and fingerlike synapses adjacent to one another, forming a synaptic complex onto a single neuronal process. On the basis of the presence of synaptic contacts, we conclude that both "dark" and "light" cells are gustatory receptors.

Arterial perfusion of frog tongue for intracellular recording of taste cell receptor potential

The frog tongue was perfused through its artery with a Ringer solution using a peristaltic pump, and a method was developed to record stable intracellular receptor potentials of taste cells. Perfusing at 0.05 ml/min with a Ringer solution containing 5% dextran did not cause tongue edema, but perfusing at the same rate with Ringer without dextran caused edema. After perfusion at 0.05 ml/min with 100 mM K Ringer, the membrane potential of taste cells gradually decreased and reached a constant level in about 30 min, indicating that the intercellular fluid of the tongue could be replaced within this time period. While the artery of the frog tongue was perfused at 0.05 ml/min with Ringer containing 5% dextran, intracellular receptor potentials of taste cells elicited by four basic taste stimuli (1 M NaCl, 10 mM quinine-HCl (Q-HCl), 1 mM acetic acid and 1 M galactose) were similar to those obtained from the control taste cells under normal blood flow.

Mechanism of the water response in carp gustatory receptors: independent generation of the water response from the salt response

The carp gustatory responses to various salts and those to distilled water after adaptation of the receptors to the salts were recorded from the palatine nerve under varying conditions. (a) As far as Na4Fe(CN)6 solution prepared freshly was used, any peak in the dose-response curve was not observed, while the solution stored overnight induced a large peak response at the low concentration region as Konishi reported. The magnitude of the water response after adaptation to the stored solution was practically equal to that after adaptation to the fresh solution, suggesting that the receptor site for the water response is different from that for the dilute salts. (b) The responses to salts depended largely on the species of both cations and anions of the salts. The responses were deceased with an increase in the lyotropic number of the anions and increased with an increase in the number above 11. The response to distilled water was practically independent of the species of both monovalent cations and anions of the salts used for the adaptation. The pH dependence of the response to 10 mM NaCl was largely different from that to distilled water after adaptation to 10 mM NaCl. (c) The water response was suppressed by the presence of electrolytes in stimulating solution; the data obtained with different species of salts were described by a single curve as a function of the ionic strength. (d) The mechanism to explain how distilled water leads to depolarization of the taste cell was discussed in terms of the electric double-layer potential.

Regenerative impulses in taste cells

Taste cells and nongustatory epithelial cells in the isolated lingual mucosa from the mud puppy Necturus maculosus were impaled with microelectrodes. The taste cells, but not surrounding epithelial cells, were electrically excitable when directly stimulated with current passed through the recording electrode. Action potentials produced by taste cells had both a sodium and a calcium component.

Neural basis of developing salt taste sensation: response changes in fetal, postnatal, and adult sheep

To learn whether salt taste responses change during mammalian development, we recorded from multifiber preparations of the chorda tympani while stimulating the anterior tongue in sheep fetuses, lambs, and adults. Stimuli were 0.5 M NH4Cl, KCl, NaCl, and LiCl, and 0.05-0.75 M concentration series of the first three salts. Ultrastructural studies were made of taste buds at different ages to determine whether morphological elements such as microvilli and tight junctions are present in young fetuses. Substantial changes occur in relative salt taste responses, throughout development. In fetuses that are beginning the last third of gestation, NaCl and LiCl elicit much smaller response magnitudes than NH4Cl and KCl. Throughout the rest of gestation and postnatally, the NaCl and LiCl responses gradually increase in magnitude relative to NH4Cl and KCl. In adults, NaCl, LiCl, and NH4Cl all elicit similar response magnitudes and KCl is less effective as a taste stimulus. At ages when response ratios for the 0.5 M salts are changing, there are no changes in shapes of the response/concentration functions for individual salts. Furthermore, microvilli are present on taste bud cell apices and tight junctions are found between cells in the youngest fetuses studied. Therefore, initial stimulus-receptor membrane contacts are probably similar to those in adults. Our data suggest that different membrane components interact with the various monochloride salts and that taste receptors contain different proportions of these various membrane components at different developmental stages. Therefore young taste bud cells do not have the same salt response characteristics as mature cells, and a changing neural substrate underlies development of salt taste function, both pre- and postnatally.

Voltage-dependent Ca2+ channel and Na+ channel in frog taste cells

Frog taste cells were hyperpolarized by injecting an inward current pulse, and regenerative anode-break potentials were observed at the termination of the current pulse. The results obtained are as follows. 1) The magnitude of the anode-break potentials increased with the extent of hyperpolarization of taste cells and reached a saturation level around -200 mV. 2) The magnitudes of the anode-break potentials observed in 80 different taste cells hyperpolarized to about -200 mV were distributed widely from cell to cell. The average magnitude was 39 mV. 3) The anode-break potentials were recorded after the lingual artery was perfused with artificial solutions containing various channel blockers. The results indicated that the anode-break potentials are composed of Na+ and Ca2+ components. 4) The slope of the current-voltage relation obtained with cells hyperpolarized to 100 mV was appreciably decreased above -50 mV by application of tetrodotoxin to the perfusing solution. Discussion was made on possible roles of the voltage-dependent Na+ and Ca2+ channels in the electrotonic spreading of the depolarization at the receptor membranes to the synaptic area and in releasing a chemical transmitter.

Response characteristics of rat taste cells to potassium benzoate

The rat taste cells responded to K-benzoate solutions higher than the threshold concentrations (0.03-0.3 M) with a depolarizing receptor potential, but they responded to K-benzoate lower than the thresholds with a hyperpolarizing receptor potential. In either depolarizing or hyperpolarizing receptor potentials the rise time decreased with increasing amplitude, but the fall time increased with increasing amplitude. During generation of either depolarizing or hyperpolarizing receptor potentials the input resistance of taste cells decreased with increasing amplitude. Application of the mixtures of various concentrations of NaCl and 0.05 M K-benzoate resulted in a reduction of receptor potential amplitude, as compared with that evoked by application of NaCl alone. It is concluded that a depression of gustatory neural impulse frequency by low concentrations of K-benzoate is mainly due to the hyperpolarizing receptor potential of taste cells elicited by the K-benzoate solutions.

Dependence of gustatory neural response on depolarizing and hyperpolarizing receptor potentials of taste cells in the rat

The rat taste cells responded to the four basic taste stimuli (0.5 M NaCl, 0.02 M quinine-HCl (Q-HCl), 0.01 M HCl and 0.5 M sucrose) with depolarizing or hyperpolarizing receptor potentials. The rates of obtaining hyperpolarizing responses under 41.1 mM NaCl adaptation were 3% for NaCl, 42% for Q-HCl, 21% for HCl and 37% for sucrose. Most of the taste cells responded to more than two kinds of taste stimuli. The ratio of mean magnitudes of depolarizing and hyperpolarizing responses for the four basic taste stimuli under 41.4 mM NaCl was as follows: NaCl:Q-HCl:HCl:sucrose = 100:9:48:2. The ratio of mean magnitudes of tonic chorda tympani nerve responses for the four basic taste stimuli under 41.4 mM NaCl was: NaCl:Q-HCl:HCl:sucrose = 100:5:37:2. Comparison of both taste cell and nerve responses suggests that the depolarization of a taste cell is concerned with a generation of gustatory neural impulses, and that the hyperpolarization is concerned with a depression of the impulses.

Topographical difference in taste organ density and its sensitivity of frog tongue

Distribution density of the taste disks of the fungiform papillae in the frog tongue was larger at the proximal portion than at the apical and middle portions. The number of myelinated afferent nerve fibres and taste cells per cm2 area of the tongue increased in the order of proximal greater than middle greater than apical portion. The amplitudes of gustatory neural responses for 0.5 M NaCl, 0.5 M KCl, 0.5 M NH4Cl, 0.05 M CaCl2, 1 mM acetic acid and 1 mM quinine-HCl (Q-HCl) were significantly larger with lingual stimulation of the proximal region than with the stimulation of the apical region. With these stimuli the mean ratio of the apical response to the proximal response was 1.00:1.54. On the other hand, this ration with deionized water was 1.00:5.00. The mean magnitudes of receptor potentials in taste cells for 1 mM acetic acid and 10 mM Q-HCl were the same among the apical, middle and proximal portions of the tongue. The mean magnitudes of receptor potentials for 0.5 M NaCl were significantly larger at the apical portion than at the other portions, whereas those for deionized water tended to be the largest at the proximal portion. It is concluded that the larger magnitude of the gustatory neural responses at the proximal portion of the tongue is due to morphological and physiological properties of the taste organ.

The response characteristics of rat taste cells to four basic taste stimuli

1. The shapes of receptor potentials of rat taste cells in response to the four basic taste stimuli (0.5 M NaCl, 0.02 M quinine-HCl (Q-HCl), 0.01 M HCl and 0.5 M sucrose) were classified into three types, i.e. (1) a depolarization alone, (2) a depolarization preceded by a transient hyperpolarization and (3) hyperpolarization alone. 2. The rise and fall times of depolarizing responses to NaCl were much shorter than those to the other three stimuli. The fall time of depolarization evoked by HCl was the longest. The rise and fall times of all hyperpolarizing responses were shorter than those of all depolarizing responses. 3. The input resistance of taste cells decreased during depolarizations elicited by NaCl stimulation, but increased during depolarizations and hyperpolarizations elicited by stimulation with Q-HCl, HCl and sucrose. 4. The taste stimulus-induced input resistance change returned faster to the control in the order of NaCl greater than sucrose greater than Q-HCl greater than HCl when the stimulus was rinsed from the tongue. 5. From these response characteristics the rat taste cells responding to each of the four basic taste stimuli are largely divided into two types, low-sensitive taste cell and high-sensitive taste cell.

Receptor potential of rat taste cell to potassium benzoate

Rat taste cells responded to relatively low concentrations of K-benzoate with a hyperpolarization and to the high concentrations with a depolarization. During both responses the membrane resistance of a taste cell decreased. Depolarization elicited by application of a combination of 0.25 M NaCl and 0.05 M K-benzoate was smaller than that by the NaCl alone, indicating a depressant action of K-benzoate.

Taste responses to deuterium oxide

Substitution of deuterium oxide (D2O) as the solvent in taste stimuli elicits neural responses which differ from ordinary water (H2O). Previous reports have shown that D2O is toxic to many animals and rats avoid drinking it when offered H2O simultaneously. In the current study, summated responses were recorded from the chorda tympani nerves of rats after NaCl, KCl, sucrose and quinine were applied to the tongue in solutions of either D2O or H2O. Both solvents were used as the adapting or rinse solution in separate series. On tongues adapted to H2O, D2O elicited mean responses which were equivalent to 29% of the response to 0.1 M NaCl. The threshold concentration of D2O in H2O was between 25% and 50%. Solutes in D2O yielded responses which were greater than corresponding solutions of H2O when adapting rinse was H2O. Adaptation to D2O diminished the responses to D2O solutions of NaCl, KCl and sucrose but not quinine. This observation suggests that some portion of the augmented response to stimuli in D2O is due to the solvent itself. The taste of water has been examined by both electrophysiological methods and by behavior, but none of the mechanisms espoused for its effect seem adequate to explain the response to D2O. Water structure at the interface between molecular components of the cell membrane and the bulk phase of the surrounding medium is considered as a locus for disparity in the taste responses to D2O and H2O in the rat.