Your search keyword '"Roper SD"' showing total 107 results

1. Membrane properties of two types of basal cells in Necturus taste buds

Author

Delay, RJ, primary, Mackay-Sim, A, additional, and Roper, SD, additional

Published

1994

2. Bidirectional synaptic transmission in Necturus taste buds

Author

Ewald, DA, primary and Roper, SD, additional

Published

1994

3. The microphysiology of peripheral taste organs

Author

Roper, SD, primary

Published

1992

4. The taste of monosodium glutamate (MSG), L -aspartic acid, and N -methyl-D -aspartate (NMDA) in rats: are NMDA receptors involved in MSG taste?

Author

Stapleton, JR, Roper, SD, and Delay, ER

Subjects

*MONOSODIUM glutamate, *TASTE, *METHYL aspartate

Abstract

Monosodium glutamate (MSG) is believed to elicit a unique taste perception known as umami. We have used conditioned taste aversion assays in rats to compare taste responses elicited by the glutamate receptor agonists MSG, L -aspartic acid (L -Asp), and N -methyl-D -aspartate (NMDA), and to determine if these compounds share a common taste quality. This information could shed new light upon the receptor mechanisms of glutamate taste transduction. Taste aversions to either MSG, L -Asp or NMDA were produced by injecting rats with LiCl after they had ingested one of these stimuli. Subsequently, rats were tested to determine whether they would ingest any of the above compounds. The results clearly show that a conditioned aversion to MSG generalized to L -Asp in a dose-dependent manner. Conversely, rats conditioned to avoid L -Asp also avoided MSG. Conditioned aversions to MSG or L -Asp generalized to sucrose when amiloride was included in all solutions. Importantly, aversions to MSG or L -Asp did not generalize to NMDA, NaCl or KCl, and aversions to NMDA did not generalize to MSG, L -Asp, sucrose or KCl. These data indicate that rats perceive MSG and L -Asp as similar tastes, whereas NMDA, NaCl and KCl elicit other tastes. The results do not support a dominant role for the NMDA subtype of glutamate receptors in taste transduction for MSG (i.e. umami) in rats. [ABSTRACT FROM AUTHOR]

Published

1999

5. Dye-coupling in taste buds in the mudpuppy, Necturus maculosus

Author

Yang, J, primary and Roper, SD, additional

Published

1987

6. Encoding Taste: From Receptors to Perception.

Author

Roper SD

Subjects

Action Potentials physiology, Humans, Perception, Sensory Receptor Cells, Taste physiology

Abstract

Taste information is encoded in the gustatory nervous system much as in other sensory systems, with notable exceptions. The concept of adequate stimulus is common to all sensory modalities, from somatosensory to auditory, visual, and so forth. That is, sensory cells normally respond only to one particular form of stimulation, the adequate stimulus, such as photons (photoreceptors in the visual system), odors (olfactory sensory neurons in the olfactory system), noxious heat (nociceptors in the somatosensory system), etc. Peripheral sensory receptors transduce the stimulus into membrane potential changes transmitted to the brain in the form of trains of action potentials. How information concerning different aspects of the stimulus such as quality, intensity, and duration are encoded in the trains of action potentials is hotly debated in the field of taste. At one extreme is the notion of labeled line/spatial coding - information for each different taste quality (sweet, salty, sour, etc.) is transmitted along a parallel but separate series of neurons (a "line") that project to focal clusters ("spaces") of neurons in the gustatory cortex. These clusters are distinct for each taste quality. Opposing this are concepts of population/combinatorial coding and temporal coding, where taste information is encrypted by groups of neurons (circuits) and patterns of impulses within these neuronal circuits. Key to population/combinatorial and temporal coding is that impulse activity in an individual neuron does not provide unambiguous information about the taste stimulus. Only populations of neurons and their impulse firing pattern yield that information., (© 2021. The Author(s), under exclusive license to Springer Nature Switzerland AG.)

Published

2022

7. "Tripartite Synapses" in Taste Buds: A Role for Type I Glial-like Taste Cells.

Author

Rodriguez YA, Roebber JK, Dvoryanchikov G, Makhoul V, Roper SD, and Chaudhari N

Subjects

Animals, Female, Mice, Synapses, Taste physiology, Synaptic Transmission physiology, Taste Buds cytology, Taste Buds physiology

Abstract

In mammalian taste buds, Type I cells comprise half of all cells. These are termed "glial-like" based on morphologic and molecular features, but there are limited studies describing their function. We tested whether Type I cells sense chemosensory activation of adjacent chemosensory (i.e., Types II and III) taste bud cells, similar to synaptic glia. Using Gad2 ;;GCaMP3 mice of both sexes, we confirmed by immunostaining that, within taste buds, GCaMP expression is predominantly in Type I cells (with no Type II and ≈28% Type III cells expressing weakly). In dissociated taste buds, GCaMP+ Type I cells responded to bath-applied ATP (10-100 μm) but not to 5-HT (transmitters released by Type II or III cells, respectively). Type I cells also did not respond to taste stimuli (5 μm cycloheximide, 1 mm denatonium). In lingual slice preparations also, Type I cells responded to bath-applied ATP (10-100 μm). However, when taste buds in the slice were stimulated with bitter tastants (cycloheximide, denatonium, quinine), Type I cells responded robustly. Taste-evoked responses of Type I cells in the slice preparation were significantly reduced by desensitizing purinoceptors or by purinoceptor antagonists (suramin, PPADS), and were essentially eliminated by blocking synaptic ATP release (carbenoxolone) or degrading extracellular ATP (apyrase). Thus, taste-evoked release of afferent ATP from type II chemosensory cells, in addition to exciting gustatory afferent fibers, also activates glial-like Type I taste cells. We speculate that Type I cells sense chemosensory activation and that they participate in synaptic signaling, similarly to glial cells at CNS tripartite synapses. SIGNIFICANCE STATEMENT Most studies of taste buds view the chemosensitive excitable cells that express taste receptors as the sole mediators of taste detection and transmission to the CNS. Type I "glial-like" cells, with their ensheathing morphology, are mostly viewed as responsible for clearing neurotransmitters and as the "glue" holding the taste bud together. In the present study, we demonstrate that, when intact taste buds respond to their natural stimuli, Type I cells sense the activation of the chemosensory cells by detecting the afferent transmitter. Because Type I cells synthesize GABA, a known gliotransmitter, and cognate receptors are present on both presynaptic and postsynaptic elements, Type I cells may participate in GABAergic synaptic transmission in the manner of astrocytes at tripartite synapses., (Copyright © 2021 the authors.)

Published

2021

8. Taste: from peripheral receptors to perception.

Author

Chaudhari N and Roper SD

Published

2021

9. Chemical and electrical synaptic interactions among taste bud cells.

Author

Roper SD

Abstract

Chemical synapses between taste cells were first proposed based on electron microscopy of fish taste buds. Subsequently, researchers found considerable evidence for electrical coupling in fish, amphibian, and possibly mammalian taste buds. The development lingual slice and isolated cell preparations allowed detailed investigations of cell-cell interactions, both chemical and electrical, in taste buds. The identification of serotonin and ATP as taste neurotransmitters focused attention onto chemical synaptic interactions between taste cells and research on electrical coupling faded. Findings from Ca 2+ imaging, electrophysiology, and molecular biology indicate that several neurotransmitters, including ATP, serotonin, GABA, acetylcholine, and norepinephrine, are secreted by taste cells and exert paracrine interactions in taste buds. Most work has been done on interactions between Type II and Type III taste cells. This brief review follows the trail of studies on cell-cell interactions in taste buds, from the initial ultrastructural observations to the most recent optogenetic manipulations., Competing Interests: I declare I have no conflicts.

Published

2021

10. The Role of the Anion in Salt (NaCl) Detection by Mouse Taste Buds.

Author

Roebber JK, Roper SD, and Chaudhari N

Subjects

Amiloride pharmacology, Animals, Anions pharmacology, Calcium Signaling drug effects, Choline pharmacology, Female, Ion Channels drug effects, Ion Channels physiology, Male, Mice, Nucleotides, Cyclic analysis, Saccharin pharmacology, Taste Buds drug effects, Chlorides pharmacology, Flavoring Agents pharmacology, Sodium Chloride pharmacology, Taste physiology, Taste Buds physiology

Abstract

How taste buds detect NaCl remains poorly understood. Among other problems, applying taste-relevant concentrations of NaCl (50-500 mm) onto isolated taste buds or cells exposes them to unphysiological (hypo/hypertonic) conditions. To overcome these limitations, we used the anterior tongue of male and female mice to implement a slice preparation in which fungiform taste buds are in a relatively intact tissue environment and stimuli are limited to the taste pore. Taste-evoked responses were monitored using confocal Ca 2+ imaging via GCaMP3 expressed in Type 2 and Type 3 taste bud cells. NaCl evoked intracellular mobilization of Ca 2+ in the apical tips of a subset of taste cells. The concentration dependence and rapid adaptation of NaCl-evoked cellular responses closely resembled behavioral and afferent nerve responses to NaCl. Importantly, taste cell responses were not inhibited by the diuretic, amiloride. Post hoc immunostaining revealed that >80% of NaCl-responsive taste bud cells were of Type 2. Many NaCl-responsive cells were also sensitive to stimuli that activate Type 2 cells but never to stimuli for Type 3 cells. Ion substitutions revealed that amiloride-insensitive NaCl responses depended on Cl - rather than Na + Moreover, choline chloride, an established salt taste enhancer, was equally effective a stimulus as sodium chloride. Although the apical transducer for Cl - remains unknown, blocking known chloride channels and cotransporters had little effect on NaCl responses. Together, our data suggest that chloride, an essential nutrient, is a key determinant of taste transduction for amiloride-insensitive salt taste. SIGNIFICANCE STATEMENT Sodium and chloride are essential nutrients and must be regularly consumed to replace excreted NaCl. Thus, understanding salt taste, which informs salt appetite, is important from a fundamental sensory perspective and forms the basis for interventions to replace/reduce excess Na + consumption. This study examines responses to NaCl in a semi-intact preparation of mouse taste buds. We identify taste cells that respond to NaCl in the presence of amiloride, which is significant because much of human salt taste also is amiloride-insensitive. Further, we demonstrate that Cl - , not Na + , generates these amiloride-insensitive salt taste responses. Intriguingly, choline chloride, a commercial salt taste enhancer, is also a highly effective stimulus for these cells., (Copyright © 2019 the authors.)

Published

2019

11. Recognizing Taste: Coding Patterns Along the Neural Axis in Mammals.

Author

Ohla K, Yoshida R, Roper SD, Di Lorenzo PM, Victor JD, Boughter JD, Fletcher M, Katz DB, and Chaudhari N

Subjects

Animals, Humans, Stimulation, Chemical, Neurons physiology, Recognition, Psychology physiology, Taste physiology, Taste Buds physiology

Abstract

The gustatory system encodes information about chemical identity, nutritional value, and concentration of sensory stimuli before transmitting the signal from taste buds to central neurons that process and transform the signal. Deciphering the coding logic for taste quality requires examining responses at each level along the neural axis-from peripheral sensory organs to gustatory cortex. From the earliest single-fiber recordings, it was clear that some afferent neurons respond uniquely and others to stimuli of multiple qualities. There is frequently a "best stimulus" for a given neuron, leading to the suggestion that taste exhibits "labeled line coding." In the extreme, a strict "labeled line" requires neurons and pathways dedicated to single qualities (e.g., sweet, bitter, etc.). At the other end of the spectrum, "across-fiber," "combinatorial," or "ensemble" coding requires minimal specific information to be imparted by a single neuron. Instead, taste quality information is encoded by simultaneous activity in ensembles of afferent fibers. Further, "temporal coding" models have proposed that certain features of taste quality may be embedded in the cadence of impulse activity. Taste receptor proteins are often expressed in nonoverlapping sets of cells in taste buds apparently supporting "labeled lines." Yet, taste buds include both narrowly and broadly tuned cells. As gustatory signals proceed to the hindbrain and on to higher centers, coding becomes more distributed and temporal patterns of activity become important. Here, we present the conundrum of taste coding in the light of current electrophysiological and imaging techniques at several levels of the gustatory processing pathway., (© The Author(s) 2019. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2019

12. Oral thermosensing by murine trigeminal neurons: modulation by capsaicin, menthol and mustard oil.

Author

Leijon SCM, Neves AF, Breza JM, Simon SA, Chaudhari N, and Roper SD

Subjects

Animals, Cold Temperature, Female, Green Fluorescent Proteins, Hot Temperature, Male, Mice, Mustard Plant, Transient Receptor Potential Channels physiology, Calcium-Binding Proteins metabolism, Capsaicin pharmacology, Menthol pharmacology, Neurons drug effects, Plant Oils pharmacology, Thermosensing physiology, Trigeminal Nerve cytology

Abstract

Key Points: Orosensory thermal trigeminal afferent neurons respond to cool, warm, and nociceptive hot temperatures with the majority activated in the cool range. Many of these thermosensitive trigeminal orosensory afferent neurons also respond to capsaicin, menthol, and/or mustard oil (allyl isothiocyanate) at concentrations found in foods and spices. There is significant but incomplete overlap between afferent trigeminal neurons that respond to oral thermal stimulation and to the above chemesthetic compounds. Capsaicin sensitizes warm trigeminal thermoreceptors and orosensory nociceptors; menthol attenuates cool thermoresponses., Abstract: When consumed with foods, mint, mustard, and chili peppers generate pronounced oral thermosensations. Here we recorded responses in mouse trigeminal ganglion neurons to investigate interactions between thermal sensing and the active ingredients of these plants - menthol, allyl isothiocyanate (AITC), and capsaicin, respectively - at concentrations found in foods and commercial hygiene products. We carried out in vivo confocal calcium imaging of trigeminal ganglia in which neurons express GCaMP3 or GCAMP6s and recorded their responses to oral stimulation with thermal and the above chemesthetic stimuli. In the V3 (oral sensory) region of the ganglion, thermoreceptive neurons accounted for ∼10% of imaged neurons. We categorized them into three distinct classes: cool-responsive and warm-responsive thermosensors, and nociceptors (responsive only to temperatures ≥43-45 °C). Menthol, AITC, and capsaicin also elicited robust calcium responses that differed markedly in their latencies and durations. Most of the neurons that responded to these chemesthetic stimuli were also thermosensitive. Capsaicin and AITC increased the numbers of warm-responding neurons and shifted the nociceptor threshold to lower temperatures. Menthol attenuated the responses in all classes of thermoreceptors. Our data show that while individual neurons may respond to a narrow temperature range (or even bimodally), taken collectively, the population is able to report on graded changes of temperature. Our findings also substantiate an explanation for the thermal sensations experienced when one consumes pungent spices or mint., (© 2019 The Authors. The Journal of Physiology © 2019 The Physiological Society.)

Published

2019

13. Transcriptomes and neurotransmitter profiles of classes of gustatory and somatosensory neurons in the geniculate ganglion.

Author

Dvoryanchikov G, Hernandez D, Roebber JK, Hill DL, Roper SD, and Chaudhari N

Subjects

Animals, Ear Auricle innervation, Geniculate Ganglion cytology, Homeodomain Proteins genetics, Mice, Nerve Tissue Proteins genetics, Receptors, Purinergic P2X2 genetics, Receptors, Purinergic P2X3 genetics, Sequence Analysis, RNA, Single-Cell Analysis, Sodium-Potassium-Exchanging ATPase genetics, Synaptosomal-Associated Protein 25 genetics, Taste, Taste Buds, Tongue innervation, Touch, Transcription Factors genetics, Geniculate Ganglion metabolism, Neurotransmitter Agents metabolism, Sensory Receptor Cells metabolism, Transcriptome

Abstract

Taste buds are innervated by neurons whose cell bodies reside in cranial sensory ganglia. Studies on the functional properties and connectivity of these neurons are hindered by the lack of markers to define their molecular identities and classes. The mouse geniculate ganglion contains chemosensory neurons innervating lingual and palatal taste buds and somatosensory neurons innervating the pinna. Here, we report single cell RNA sequencing of geniculate ganglion neurons. Using unbiased transcriptome analyses, we show a pronounced separation between two major clusters which, by anterograde labeling, correspond to gustatory and somatosensory neurons. Among the gustatory neurons, three subclusters are present, each with its own complement of transcription factors and neurotransmitter response profiles. The smallest subcluster expresses both gustatory- and mechanosensory-related genes, suggesting a novel type of sensory neuron. We identify several markers to help dissect the functional distinctions among gustatory neurons and address questions regarding target interactions and taste coding.Characterization of gustatory neural pathways has suffered due to a lack of molecular markers. Here, the authors report single cell RNA sequencing and unbiased transcriptome analyses to reveal major distinctions between gustatory and somatosensory neurons and subclusters of gustatory neurons with unique molecular and functional profiles.

Published

2017

14. Taste buds: cells, signals and synapses.

Author

Roper SD and Chaudhari N

Subjects

Animals, Cell Communication physiology, Humans, Afferent Pathways physiology, Synaptic Transmission, Taste Buds cytology, Taste Buds physiology

Abstract

The past decade has witnessed a consolidation and refinement of the extraordinary progress made in taste research. This Review describes recent advances in our understanding of taste receptors, taste buds, and the connections between taste buds and sensory afferent fibres. The article discusses new findings regarding the cellular mechanisms for detecting tastes, new data on the transmitters involved in taste processing and new studies that address longstanding arguments about taste coding.

Published

2017

15. Breadth of tuning in taste afferent neurons varies with stimulus strength.

Author

Wu A, Dvoryanchikov G, Pereira E, Chaudhari N, and Roper SD

Subjects

Animals, Calcium Signaling physiology, Green Fluorescent Proteins, Mice, Mice, Transgenic, Microscopy, Confocal, Neurons, Afferent physiology, Optical Imaging, Physical Stimulation, Sensory Receptor Cells physiology, Sodium Chloride, Evoked Potentials physiology, Geniculate Ganglion physiology, Taste physiology, Taste Buds physiology

Abstract

Gustatory stimuli are detected by taste buds and transmitted to the hindbrain via sensory afferent neurons. Whether each taste quality (sweet, bitter and so on) is encoded by separate neurons ('labelled lines') remains controversial. We used mice expressing GCaMP3 in geniculate ganglion sensory neurons to investigate taste-evoked activity. Using confocal calcium imaging, we recorded responses to oral stimulation with prototypic taste stimuli. Up to 69% of neurons respond to multiple tastants. Moreover, neurons tuned to a single taste quality at low concentration become more broadly tuned when stimuli are presented at higher concentration. Responses to sucrose and monosodium glutamate are most related. Although mice prefer dilute NaCl solutions and avoid concentrated NaCl, we found no evidence for two separate populations of sensory neurons that encode this distinction. Altogether, our data suggest that taste is encoded by activity in patterns of peripheral sensory neurons and challenge the notion of strict labelled line coding.

Published

2015

16. Leptin's effect on taste bud calcium responses and transmitter secretion.

Author

Meredith TL, Corcoran A, and Roper SD

Subjects

Adenosine Triphosphate metabolism, Animals, Cricetulus, Female, Male, Mice, Mice, Inbred C57BL, Ovary cytology, Ovary drug effects, Ovary metabolism, Serotonin metabolism, Synaptic Transmission drug effects, Calcium metabolism, Leptin pharmacology, Neurotransmitter Agents metabolism, Taste drug effects, Taste Buds drug effects, Taste Buds metabolism

Abstract

Leptin, a peptide hormone released by adipose tissue, acts on the hypothalamus to control cravings and appetite. Leptin also acts to decrease taste responses to sweet substances, though there is little detailed information regarding where leptin acts in the taste transduction cascade. The present study examined the effects of leptin on sweet-evoked responses and neuro transmitter release from isolated taste buds. Our results indicate that leptin moderately decreased sweet-evoked calcium mobilization in isolated mouse taste buds. We also employed Chinese hamster ovary biosensor cells to examine taste transmitter release from isolated taste buds. Leptin reduced ATP and increased serotonin release in response to sweet stimulation. However, leptin has no effect on bitter-evoked transmitter release, further showing that the action of leptin is sweet specific. Our results support those of previous studies, which state that leptin acts on taste tissue via the leptin receptor, most likely on Type II (Receptor) cells, but also possibly on Type III (Presynaptic) cells., (© The Author 2014. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2015

17. The taste of table salt.

Author

Roper SD

Subjects

Animals, Epithelial Sodium Channels metabolism, Humans, Sodium metabolism, Taste Buds drug effects, Taste Buds metabolism, Taste Buds physiology, Sodium Chloride, Dietary metabolism, Taste, Taste Perception

Abstract

Solutions of table salt (NaCl) elicit several tastes, including of course saltiness but also sweet, sour, and bitter. This brief review touches on some of the mileposts concerning what is known about taste transduction for the Na(+) ion, the main contributor to saltiness. Electrophysiological recordings, initially from single gustatory nerve fibers, and later, integrated impulse activity from gustatory nerves led researchers to predict that Na(+) ions interacted with a surface molecule. Subsequent studies have resolved that this molecule is likely to be an epithelial sodium channel, ENaC. Other Na(+) transduction mechanisms are also present in taste buds but have not yet been identified. The specific type(s) of taste cells responsible for salt taste also remains unknown.

Published

2015

18. A permeability barrier surrounds taste buds in lingual epithelia.

Author

Dando R, Pereira E, Kurian M, Barro-Soria R, Chaudhari N, and Roper SD

Subjects

Animals, Dimethyl Sulfoxide pharmacology, Enzymes metabolism, Epithelial Cells drug effects, Fluoresceins chemistry, Fluoresceins metabolism, Fluorescent Dyes chemistry, Fluorescent Dyes metabolism, Membrane Potentials, Mice, Inbred C57BL, Molecular Weight, Permeability, Solvents pharmacology, Stimulation, Chemical, Taste Buds cytology, Taste Buds drug effects, Tight Junctions drug effects, Epithelial Cells metabolism, Taste, Taste Buds metabolism, Tight Junctions metabolism, Tongue innervation

Abstract

Epithelial tissues are characterized by specialized cell-cell junctions, typically localized to the apical regions of cells. These junctions are formed by interacting membrane proteins and by cytoskeletal and extracellular matrix components. Within the lingual epithelium, tight junctions join the apical tips of the gustatory sensory cells in taste buds. These junctions constitute a selective barrier that limits penetration of chemosensory stimuli into taste buds (Michlig et al. J Comp Neurol 502: 1003-1011, 2007). We tested the ability of chemical compounds to permeate into sensory end organs in the lingual epithelium. Our findings reveal a robust barrier that surrounds the entire body of taste buds, not limited to the apical tight junctions. This barrier prevents penetration of many, but not all, compounds, whether they are applied topically, injected into the parenchyma of the tongue, or circulating in the blood supply, into taste buds. Enzymatic treatments indicate that this barrier likely includes glycosaminoglycans, as it was disrupted by chondroitinase but, less effectively, by proteases. The barrier surrounding taste buds could also be disrupted by brief treatment of lingual tissue samples with DMSO. Brief exposure of lingual slices to DMSO did not affect the ability of taste buds within the slice to respond to chemical stimulation. The existence of a highly impermeable barrier surrounding taste buds and methods to break through this barrier may be relevant to basic research and to clinical treatments of taste., (Copyright © 2015 the American Physiological Society.)

Published

2015

19. Sensory end-organs: signal processing in the periphery: a symposium presented at the 2013 Annual Meeting of the Society for Neuroscience, San Diego, CA, USA.

Author

Roper SD

Subjects

Sensory Receptor Cells metabolism, Congresses as Topic, Sensory Receptor Cells physiology, Synaptic Transmission

Published

2014

20. TRPs in taste and chemesthesis.

Author

Roper SD

Subjects

Animals, Humans, Taste Buds cytology, Chemoreceptor Cells physiology, Taste physiology, Transient Receptor Potential Channels physiology

Abstract

TRP channels are expressed in taste buds, nerve fibers, and keratinocytes in the oronasal cavity. These channels play integral roles in transducing chemical stimuli, giving rise to sensations of taste, irritation, warmth, coolness, and pungency. Specifically, TRPM5 acts downstream of taste receptors in the taste transduction pathway. TRPM5 channels convert taste-evoked intracellular Ca(2+) release into membrane depolarization to trigger taste transmitter secretion. PKD2L1 is expressed in acid-sensitive (sour) taste bud cells but is unlikely to be the transducer for sour taste. TRPV1 is a receptor for pungent chemical stimuli such as capsaicin and for several irritants (chemesthesis). It is controversial whether TRPV1 is present in the taste buds and plays a direct role in taste. Instead, TRPV1 is expressed in non-gustatory sensory afferent fibers and in keratinocytes of the oronasal cavity. In many sensory fibers and epithelial cells lining the oronasal cavity, TRPA1 is also co-expressed with TRPV1. As with TRPV1, TRPA1 transduces a wide variety of irritants and, in combination with TRPV1, assures that there is a broad response to noxious chemical stimuli. Other TRP channels, including TRPM8, TRPV3, and TRPV4, play less prominent roles in chemesthesis and no known role in taste, per se. The pungency of foods and beverages is likely highly influenced by the temperature at which they are consumed, their acidity, and, for beverages, their carbonation. All these factors modulate the activity of TRP channels in taste buds and in the oronasal mucosa.

Published

2014

21. Taste buds as peripheral chemosensory processors.

Author

Roper SD

Subjects

Animals, Cell Communication, Humans, Receptors, Cell Surface metabolism, Signal Transduction, Taste Buds anatomy & histology, Taste Buds metabolism

Abstract

Taste buds are peripheral chemosensory organs situated in the oral cavity. Each taste bud consists of a community of 50-100 cells that interact synaptically during gustatory stimulation. At least three distinct cell types are found in mammalian taste buds - Type I cells, Receptor (Type II) cells, and Presynaptic (Type III) cells. Type I cells appear to be glial-like cells. Receptor cells express G protein-coupled taste receptors for sweet, bitter, or umami compounds. Presynaptic cells transduce acid stimuli (sour taste). Cells that sense salt (NaCl) taste have not yet been confidently identified in terms of these cell types. During gustatory stimulation, taste bud cells secrete synaptic, autocrine, and paracrine transmitters. These transmitters include ATP, acetylcholine (ACh), serotonin (5-HT), norepinephrine (NE), and GABA. Glutamate is an efferent transmitter that stimulates Presynaptic cells to release 5-HT. This chapter discusses these transmitters, which cells release them, the postsynaptic targets for the transmitters, and how cell-cell communication shapes taste bud signaling via these transmitters., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2013

22. Introduction to signal processing in peripheral sensory organs.

Author

Roper SD

Subjects

Humans, Sensory Receptor Cells metabolism, Sense Organs metabolism, Signal Transduction

Published

2013

23. Acetylcholine is released from taste cells, enhancing taste signalling.

Author

Dando R and Roper SD

Subjects

Animals, CHO Cells, Calcium physiology, Cricetinae, Cricetulus, In Vitro Techniques, Mice, Mice, Inbred C57BL, Mice, Transgenic, Microscopy, Confocal, Signal Transduction, Acetylcholine physiology, Taste physiology, Taste Buds physiology

Abstract

Acetylcholine (ACh), a candidate neurotransmitter that has been implicated in taste buds, elicits calcium mobilization in Receptor (Type II) taste cells. Using RT-PCR analysis and pharmacological interventions, we demonstrate that the muscarinic acetylcholine receptor M3 mediates these actions. Applying ACh enhanced both taste-evoked Ca2+ responses and taste-evoked afferent neurotransmitter (ATP) secretion from taste Receptor cells. Blocking muscarinic receptors depressed taste-evoked responses in Receptor cells, suggesting that ACh is normally released from taste cells during taste stimulation. ACh biosensors confirmed that, indeed, taste Receptor cells secrete acetylcholine during gustatory stimulation. Genetic deletion of muscarinic receptors resulted in significantly diminished ATP secretion from taste buds. The data demonstrate a new role for acetylcholine as a taste bud transmitter. Our results imply specifically that ACh is an autocrine transmitter secreted by taste Receptor cells during gustatory stimulation, enhancing taste-evoked responses and afferent transmitter secretion.

Published

2012

24. Real-time detection of acetylcholine release from the human endocrine pancreas.

Author

Rodriguez-Diaz R, Dando R, Huang YA, Berggren PO, Roper SD, and Caicedo A

Subjects

Animals, CHO Cells, Calcium analysis, Calcium metabolism, Cricetinae, Cricetulus, Fluorescent Dyes analysis, Fura-2 analysis, Humans, Receptor, Muscarinic M3 genetics, Receptor, Muscarinic M3 metabolism, Acetylcholine analysis, Biosensing Techniques methods, Islets of Langerhans metabolism

Abstract

Neurons, sensory cells and endocrine cells secrete neurotransmitters and hormones to communicate with other cells and to coordinate organ and system function. Validation that a substance is used as an extracellular signaling molecule by a given cell requires a direct demonstration of its secretion. In this protocol we describe the use of biosensor cells to detect neurotransmitter release from endocrine cells in real-time. Chinese hamster ovary cells expressing the muscarinic acetylcholine (ACh) receptor M3 were used as ACh biosensors to record ACh release from human pancreatic islets. We show how ACh biosensors loaded with the Ca(2+) indicator Fura-2 and pressed against isolated human pancreatic islets allow the detection of ACh release. The biosensor approach is simple; the Ca(2+) signal generated in the biosensor cell reflects the presence (release) of a neurotransmitter. The technique is versatile because biosensor cells expressing a variety of receptors can be used in many applications. The protocol takes ∼3 h.

Published

2012

25. Adenosine enhances sweet taste through A2B receptors in the taste bud.

Author

Dando R, Dvoryanchikov G, Pereira E, Chaudhari N, and Roper SD

Subjects

Adenosine pharmacology, Animals, CHO Cells, Cricetinae, Cricetulus, Female, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Mice, Transgenic, Organ Culture Techniques methods, Receptor, Adenosine A2B drug effects, Receptor, Adenosine A2B genetics, Sweetening Agents pharmacology, Taste drug effects, Taste Buds drug effects, Adenosine physiology, Adenosine Triphosphate metabolism, Receptor, Adenosine A2B physiology, Taste physiology, Taste Buds metabolism

Abstract

Mammalian taste buds use ATP as a neurotransmitter. Taste Receptor (type II) cells secrete ATP via gap junction hemichannels into the narrow extracellular spaces within a taste bud. This ATP excites primary sensory afferent fibers and also stimulates neighboring taste bud cells. Here we show that extracellular ATP is enzymatically degraded to adenosine within mouse vallate taste buds and that this nucleoside acts as an autocrine neuromodulator to selectively enhance sweet taste. In Receptor cells in a lingual slice preparation, Ca(2+) mobilization evoked by focally applied artificial sweeteners was significantly enhanced by adenosine (50 μM). Adenosine had no effect on bitter or umami taste responses, and the nucleoside did not affect Presynaptic (type III) taste cells. We also used biosensor cells to measure transmitter release from isolated taste buds. Adenosine (5 μM) enhanced ATP release evoked by sweet but not bitter taste stimuli. Using single-cell reverse transcriptase (RT)-PCR on isolated vallate taste cells, we show that many Receptor cells express the adenosine receptor, Adora2b, while Presynaptic (type III) and Glial-like (type I) cells seldom do. Furthermore, Adora2b receptors are significantly associated with expression of the sweet taste receptor subunit, Tas1r2. Adenosine is generated during taste stimulation mainly by the action of the ecto-5'-nucleotidase, NT5E, and to a lesser extent, prostatic acid phosphatase. Both these ecto-nucleotidases are expressed by Presynaptic cells, as shown by single-cell RT-PCR, enzyme histochemistry, and immunofluorescence. Our findings suggest that ATP released during taste reception is degraded to adenosine to exert positive modulation particularly on sweet taste.

Published

2012

26. Knocking out P2X receptors reduces transmitter secretion in taste buds.

Author

Huang YA, Stone LM, Pereira E, Yang R, Kinnamon JC, Dvoryanchikov G, Chaudhari N, Finger TE, Kinnamon SC, and Roper SD

Subjects

Adenosine Triphosphatases metabolism, Animals, Calcium metabolism, Connexins metabolism, Male, Mice, Mice, Inbred Strains, Mice, Knockout, Nerve Tissue Proteins metabolism, Potassium Chloride pharmacology, Receptors, G-Protein-Coupled metabolism, Receptors, Purinergic P2X genetics, Synaptic Transmission genetics, TRPM Cation Channels metabolism, Taste physiology, Taste Buds drug effects, Taste Buds ultrastructure, Adenosine Triphosphate metabolism, Receptors, Purinergic P2X biosynthesis, Receptors, Purinergic P2X2 biosynthesis, Synaptic Transmission physiology, Taste Buds metabolism

Abstract

In response to gustatory stimulation, taste bud cells release a transmitter, ATP, that activates P2X2 and P2X3 receptors on gustatory afferent fibers. Taste behavior and gustatory neural responses are largely abolished in mice lacking P2X2 and P2X3 receptors [P2X2 and P2X3 double knock-out (DKO) mice]. The assumption has been that eliminating P2X2 and P2X3 receptors only removes postsynaptic targets but that transmitter secretion in mice is normal. Using functional imaging, ATP biosensor cells, and a cell-free assay for ATP, we tested this assumption. Surprisingly, although gustatory stimulation mobilizes Ca(2+) in taste Receptor (Type II) cells from DKO mice, as from wild-type (WT) mice, taste cells from DKO mice fail to release ATP when stimulated with tastants. ATP release could be elicited by depolarizing DKO Receptor cells with KCl, suggesting that ATP-release machinery remains functional in DKO taste buds. To explore the difference in ATP release across genotypes, we used reverse transcriptase (RT)-PCR, immunostaining, and histochemistry for key proteins underlying ATP secretion and degradation: Pannexin1, TRPM5, and NTPDase2 (ecto-ATPase) are indistinguishable between WT and DKO mice. The ultrastructure of contacts between taste cells and nerve fibers is also normal in the DKO mice. Finally, quantitative RT-PCR show that P2X4 and P2X7, potential modulators of ATP secretion, are similarly expressed in taste buds in WT and DKO taste buds. Importantly, we find that P2X2 is expressed in WT taste buds and appears to function as an autocrine, positive feedback signal to amplify taste-evoked ATP secretion.

Published

2011

27. Alpha cells secrete acetylcholine as a non-neuronal paracrine signal priming beta cell function in humans.

Author

Rodriguez-Diaz R, Dando R, Jacques-Silva MC, Fachado A, Molina J, Abdulreda MH, Ricordi C, Roper SD, Berggren PO, and Caicedo A

Subjects

Acetylcholine physiology, Alkenes pharmacology, Animals, Dose-Response Relationship, Drug, Glucagon-Secreting Cells drug effects, Glucagon-Secreting Cells physiology, Glucose metabolism, Humans, Insulin metabolism, Insulin Secretion, Insulin-Secreting Cells drug effects, Insulin-Secreting Cells metabolism, Mice, Physostigmine pharmacology, Piperidines pharmacology, Receptors, Cholinergic physiology, Secretory Vesicles physiology, Signal Transduction physiology, Vesicular Acetylcholine Transport Proteins physiology, Acetylcholine metabolism, Glucagon-Secreting Cells metabolism, Insulin-Secreting Cells physiology

Abstract

Acetylcholine is a neurotransmitter that has a major role in the function of the insulin-secreting pancreatic beta cell. Parasympathetic innervation of the endocrine pancreas, the islets of Langerhans, has been shown to provide cholinergic input to the beta cell in several species, but the role of autonomic innervation in human beta cell function is at present unclear. Here we show that, in contrast to the case in mouse islets, cholinergic innervation of human islets is sparse. Instead, we find that the alpha cells of human islets provide paracrine cholinergic input to surrounding endocrine cells. Human alpha cells express the vesicular acetylcholine transporter and release acetylcholine when stimulated with kainate or a lowering in glucose concentration. Acetylcholine secretion by alpha cells in turn sensitizes the beta cell response to increases in glucose concentration. Our results demonstrate that in human islets acetylcholine is a paracrine signal that primes the beta cell to respond optimally to subsequent increases in glucose concentration. Cholinergic signaling within islets represents a potential therapeutic target in diabetes, highlighting the relevance of this advance to future drug development.

Published

2011

28. GABA, its receptors, and GABAergic inhibition in mouse taste buds.

Author

Dvoryanchikov G, Huang YA, Barro-Soria R, Chaudhari N, and Roper SD

Subjects

Animals, CHO Cells, Calcium metabolism, Cricetinae, Cricetulus, Image Processing, Computer-Assisted, Immunohistochemistry, In Vitro Techniques, Mice, Mice, Inbred C57BL, Mice, Transgenic, Microscopy, Fluorescence, Neurotransmitter Agents metabolism, RNA genetics, Receptors, GABA genetics, Receptors, Presynaptic drug effects, Reverse Transcriptase Polymerase Chain Reaction, Signal Transduction drug effects, Signal Transduction physiology, Taste drug effects, gamma-Aminobutyric Acid pharmacology, GABA Antagonists pharmacology, Receptors, GABA physiology, Taste Buds drug effects, gamma-Aminobutyric Acid physiology

Abstract

Taste buds consist of at least three principal cell types that have different functions in processing gustatory signals: glial-like (type I) cells, receptor (type II) cells, and presynaptic (type III) cells. Using a combination of Ca2+ imaging, single-cell reverse transcriptase-PCR and immunostaining, we show that GABA is an inhibitory transmitter in mouse taste buds, acting on GABA(A) and GABA(B) receptors to suppress transmitter (ATP) secretion from receptor cells during taste stimulation. Specifically, receptor cells express GABA(A) receptor subunits β2, δ, and π, as well as GABA(B) receptors. In contrast, presynaptic cells express the GABA(A) β3 subunit and only occasionally GABA(B) receptors. In keeping with the distinct expression pattern of GABA receptors in presynaptic cells, we detected no GABAergic suppression of transmitter release from presynaptic cells. We suggest that GABA may serve function(s) in taste buds in addition to synaptic inhibition. Finally, we also defined the source of GABA in taste buds: GABA is synthesized by GAD65 in type I taste cells as well as by GAD67 in presynaptic (type III) taste cells and is stored in both those two cell types. We conclude that GABA is an inhibitory transmitter released during taste stimulation and possibly also during growth and differentiation of taste buds.

Published

2011

29. Acid stimulation (sour taste) elicits GABA and serotonin release from mouse taste cells.

Author

Huang YA, Pereira E, and Roper SD

Subjects

Acids pharmacology, Animals, Biosensing Techniques, CHO Cells, Cricetinae, Cricetulus, Female, Male, Mice, Receptors, GABA-B genetics, Receptors, GABA-B metabolism, Synapses drug effects, Synapses metabolism, Taste Buds drug effects, Neurotransmitter Agents metabolism, Serotonin metabolism, Taste drug effects, Taste Buds cytology, Taste Buds metabolism, gamma-Aminobutyric Acid metabolism

Abstract

Several transmitter candidates including serotonin (5-HT), ATP, and norepinephrine (NE) have been identified in taste buds. Recently, γ-aminobutyric acid (GABA) as well as the associated synthetic enzymes and receptors have also been identified in taste cells. GABA reduces taste-evoked ATP secretion from Receptor cells and is considered to be an inhibitory transmitter in taste buds. However, to date, the identity of GABAergic taste cells and the specific stimulus for GABA release are not well understood. In the present study, we used genetically-engineered Chinese hamster ovary (CHO) cells stably co-expressing GABA(B) receptors and Gαqo5 proteins to measure GABA release from isolated taste buds. We recorded robust responses from GABA biosensors when they were positioned against taste buds isolated from mouse circumvallate papillae and the buds were depolarized with KCl or a stimulated with an acid (sour) taste. In contrast, a mixture of sweet and bitter taste stimuli did not trigger GABA release. KCl- or acid-evoked GABA secretion from taste buds was Ca(2+)-dependent; removing Ca(2+) from the bathing medium eliminated GABA secretion. Finally, we isolated individual taste cells to identify the origin of GABA secretion. GABA was released only from Presynaptic (Type III) cells and not from Receptor (Type II) cells. Previously, we reported that 5-HT released from Presynaptic cells inhibits taste-evoked ATP secretion. Combined with the recent findings that GABA depresses taste-evoked ATP secretion, the present results indicate that GABA and 5-HT are inhibitory transmitters in mouse taste buds and both likely play an important role in modulating taste responses.

Published

2011

30. The cell biology of taste.

Author

Chaudhari N and Roper SD

Subjects

Animals, Brain physiology, Humans, Taste Buds cytology, Taste Buds physiology, Cell Biology, Taste physiology

Abstract

Taste buds are aggregates of 50-100 polarized neuroepithelial cells that detect nutrients and other compounds. Combined analyses of gene expression and cellular function reveal an elegant cellular organization within the taste bud. This review discusses the functional classes of taste cells, their cell biology, and current thinking on how taste information is transmitted to the brain.

Published

2010

31. Oxytocin signaling in mouse taste buds.

Author

Sinclair MS, Perea-Martinez I, Dvoryanchikov G, Yoshida M, Nishimori K, Roper SD, and Chaudhari N

Subjects

Animals, Calcium metabolism, Dose-Response Relationship, Drug, Eating, Gene Expression Regulation, Gene Knock-In Techniques, Mice, Mice, Transgenic, Neuroglia cytology, Oxytocin pharmacology, Receptors, Oxytocin antagonists & inhibitors, Receptors, Oxytocin deficiency, Receptors, Oxytocin genetics, Reverse Transcriptase Polymerase Chain Reaction, Taste Buds cytology, Taste Buds drug effects, Oxytocin metabolism, Receptors, Oxytocin metabolism, Signal Transduction, Taste Buds metabolism

Abstract

Background: The neuropeptide, oxytocin (OXT), acts on brain circuits to inhibit food intake. Mutant mice lacking OXT (OXT knockout) overconsume salty and sweet (i.e. sucrose, saccharin) solutions. We asked if OXT might also act on taste buds via its receptor, OXTR., Methodology/principal Findings: Using RT-PCR, we detected the expression of OXTR in taste buds throughout the oral cavity, but not in adjacent non-taste lingual epithelium. By immunostaining tissues from OXTR-YFP knock-in mice, we found that OXTR is expressed in a subset of Glial-like (Type I) taste cells, and also in cells on the periphery of taste buds. Single-cell RT-PCR confirmed this cell-type assignment. Using Ca2+ imaging, we observed that physiologically appropriate concentrations of OXT evoked [Ca2+]i mobilization in a subset of taste cells (EC50 approximately 33 nM). OXT-evoked responses were significantly inhibited by the OXTR antagonist, L-371,257. Isolated OXT-responsive taste cells were neither Receptor (Type II) nor Presynaptic (Type III) cells, consistent with our immunofluorescence observations. We also investigated the source of OXT peptide that may act on taste cells. Both RT-PCR and immunostaining suggest that the OXT peptide is not produced in taste buds or in their associated nerves. Finally, we also examined the morphology of taste buds from mice that lack OXTR. Taste buds and their constituent cell types appeared very similar in mice with two, one or no copies of the OXTR gene., Conclusions/significance: We conclude that OXT elicits Ca2+ signals via OXTR in murine taste buds. OXT-responsive cells are most likely a subset of Glial-like (Type I) taste cells. OXT itself is not produced locally in taste tissue and is likely delivered through the circulation. Loss of OXTR does not grossly alter the morphology of any of the cell types contained in taste buds. Instead, we speculate that OXT-responsive Glial-like (Type I) taste bud cells modulate taste signaling and afferent sensory output. Such modulation would complement central pathways of appetite regulation that employ circulating homeostatic and satiety signals.

Published

2010

32. Intracellular Ca(2+) and TRPM5-mediated membrane depolarization produce ATP secretion from taste receptor cells.

Author

Huang YA and Roper SD

Subjects

Action Potentials drug effects, Animals, CHO Cells, Cell Membrane metabolism, Cell Separation, Cricetinae, Cricetulus, Electric Stimulation, Electrophysiology, Female, Male, Mice, Mice, Inbred C57BL, Neurotransmitter Agents metabolism, Taste physiology, Taste Buds cytology, Adenosine Triphosphate metabolism, Calcium physiology, Cell Membrane physiology, TRPM Cation Channels physiology, Taste Buds physiology

Abstract

ATP is a transmitter secreted from taste bud receptor (Type II) cells through ATP-permeable gap junction hemichannels most probably composed of pannexin 1. The elevation of intracellular Ca(2+) and membrane depolarization are both believed to be involved in transmitter secretion from receptor cells, but their specific roles have not been fully elucidated. In the present study, we show that taste-evoked ATP secretion from mouse vallate receptor cells is evoked by the combination of intracellular Ca(2+) release and membrane depolarization. Unexpectedly, ATP secretion is not blocked by tetrodotoxin, indicating that transmitter release from these cells still takes place in the absence of action potentials. Taste-evoked ATP secretion is absent in receptor cells isolated from TRPM5 knockout mice or in taste cells from wild type mice where current through TRPM5 channels has been eliminated. These findings suggest that membrane voltage initiated by TRPM5 channels is required for ATP secretion during taste reception. Nonetheless, even in the absence of TRPM5 channel activity, ATP release could be triggered by depolarizing cells with KCl. Collectively, the findings indicate that taste-evoked elevation of intracellular Ca(2+) has a dual role: (1) Ca(2+) opens TRPM5 channels to depolarize receptor cells and (2) Ca(2+) plus membrane depolarization opens ATP-permeable gap junction hemichannels.

Published

2010

33. Cell-to-cell communication in intact taste buds through ATP signalling from pannexin 1 gap junction hemichannels.

Author

Dando R and Roper SD

Subjects

Animals, In Vitro Techniques, Mice, Mice, Inbred C57BL, Mice, Transgenic, Adenosine Triphosphate metabolism, Cell Communication physiology, Connexins metabolism, Gap Junctions metabolism, Nerve Tissue Proteins metabolism, Signal Transduction physiology

Abstract

Isolated taste cells, taste buds and strips of lingual tissue from taste papillae secrete ATP upon taste stimulation. Taste bud receptor (Type II) cells have been identified as the source of ATP secretion. Based on studies on isolated taste buds and single taste cells, we have postulated that ATP secreted from receptor cells via pannexin 1 hemichannels acts within the taste bud to excite neighbouring presynaptic (Type III) cells. This hypothesis, however, remains to be tested in intact tissues. In this report we used confocal Ca(2+) imaging and lingual slices containing intact taste buds to test the hypothesis of purinergic signalling between taste cells in a more integral preparation. Incubating lingual slices with apyrase reversibly blocked cell-to-cell communication between receptor cells and presynaptic cells, consistent with ATP being the transmitter. Inhibiting pannexin 1 gap junction hemichannels with CO(2)-saturated buffer or probenecid significantly reduced cell-cell signalling between receptor cells and presynaptic cells. In contrast, anandamide, a blocker of connexin gap junction channels, had no effect of cell-to-cell communication in taste buds. These findings are consistent with the model for peripheral signal processing via ATP and pannexin 1 hemichannels in mammalian taste buds.

Published

2009

34. Autocrine and paracrine roles for ATP and serotonin in mouse taste buds.

Author

Huang YA, Dando R, and Roper SD

Subjects

Animals, CHO Cells, Cricetinae, Cricetulus, Female, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Mice, Transgenic, Taste physiology, Adenosine Triphosphate physiology, Autocrine Communication physiology, Paracrine Communication physiology, Serotonin physiology, Taste Buds physiology

Abstract

Receptor (type II) taste bud cells secrete ATP during taste stimulation. In turn, ATP activates adjacent presynaptic (type III) cells to release serotonin (5-hydroxytryptamine, or 5-HT) and norepinephrine (NE). The roles of these neurotransmitters in taste buds have not been fully elucidated. Here we tested whether ATP or 5-HT exert feedback onto receptor (type II) cells during taste stimulation. Our previous studies showed NE does not appear to act on adjacent taste bud cells, or at least on receptor cells. Our data show that 5-HT released from presynaptic (type III) cells provides negative paracrine feedback onto receptor cells by activating 5-HT(1A) receptors, inhibiting taste-evoked Ca(2+) mobilization in receptor cells, and reducing ATP secretion. The findings also demonstrate that ATP exerts positive autocrine feedback onto receptor (type II) cells by activating P2Y1 receptors and enhancing ATP secretion. These results begin to sort out how purinergic and aminergic transmitters function within the taste bud to modulate gustatory signaling in these peripheral sensory organs.

Published

2009

35. Taste receptors for umami: the case for multiple receptors.

Author

Chaudhari N, Pereira E, and Roper SD

Subjects

Amino Acids physiology, Animals, Mice, Mice, Knockout, RNA, Messenger analysis, Rats, Receptors, G-Protein-Coupled genetics, Receptors, G-Protein-Coupled metabolism, Receptors, Metabotropic Glutamate genetics, Receptors, Metabotropic Glutamate metabolism, Taste genetics, Taste Buds metabolism, Taste Buds physiology, Receptors, G-Protein-Coupled physiology, Receptors, Metabotropic Glutamate physiology, Taste physiology

Abstract

Umami taste is elicited by many small molecules, including amino acids (glutamate and aspartate) and nucleotides (monophosphates of inosinate or guanylate, inosine 5'-monophosphate and guanosine-5'-monophosphate). Mammalian taste buds respond to these diverse compounds via membrane receptors that bind the umami tastants. Over the past 15 y, several receptors have been proposed to underlie umami detection in taste buds. These receptors include 2 glutamate-selective G protein-coupled receptors, mGluR4 and mGluR1, and the taste bud-expressed heterodimer T1R1+T1R3. Each of these receptors is expressed in small numbers of cells in anterior and posterior taste buds. The mGluRs are activated by glutamate and certain analogs but are not reported to be sensitive to nucleotides. In contrast, T1R1+T1R3 is activated by a broad range of amino acids and displays a strongly potentiated response in the presence of nucleotides. Mice in which the Grm4 gene is knocked out show a greatly enhanced preference for umami tastants. Loss of the Tas1r1 or Tas1R3 genes is reported to depress but not eliminate neural and behavioral responses to umami. When intact mammalian taste buds are apically stimulated with umami tastants, their functional responses to umami tastants do not fully resemble the responses of a single proposed umami receptor. Furthermore, the responses to umami tastants persist in the taste cells of T1R3-knockout mice. Thus, umami taste detection may involve multiple receptors expressed in different subsets of taste cells. This receptor diversity may underlie the complex perception of umami, with different mixtures of amino acids, peptides, and nucleotides yielding subtly distinct taste qualities.

Published

2009

36. Parallel processing in mammalian taste buds?

Author

Roper SD

Subjects

Animals, CHO Cells, Calcium metabolism, Cell Communication, Cricetinae, Cricetulus, Humans, Neurons classification, Neurotransmitter Agents metabolism, Mammals anatomy & histology, Neural Pathways physiology, Neurons physiology, Taste Buds cytology

Abstract

ROPER, S.D. Parallel processing in mammalian taste buds? Physiol Behav XXX(Y) 000-000, 2009. There is emerging evidence that two parallel lines of gustatory information are generated in taste buds. One pathway leads to higher cortical centers and is involved in discriminating basic taste qualities (sweet, bitter, sour, salty, umami) and perceiving flavors. The other pathway may conduct information involved in physiological reflexes such as swallowing, salivation, and cephalic phase digestion. If this notion is true, the existence of two populations of taste bud cells that have different functional characteristics may lie at the origins of the two pathways. This speculative concept is explored in this review of taste signal processing in mammalian taste buds.

Published

2009

37. Processing umami and other tastes in mammalian taste buds.

Author

Roper SD and Chaudhari N

Subjects

Animals, Models, Biological, Synaptic Transmission, Taste Buds cytology, Taste, Taste Buds physiology

Abstract

Neuroscientists are now coming to appreciate that a significant degree of information processing occurs in the peripheral sensory organs of taste prior to signals propagating to the brain. Gustatory stimulation causes taste bud cells to secrete neurotransmitters that act on adjacent taste bud cells (paracrine transmitters) as well as on primary sensory afferent fibers (neurocrine transmitters). Paracrine transmission, representing cell-cell communication within the taste bud, has the potential to shape the final signal output that taste buds transmit to the brain. The following paragraphs summarize current thinking about how taste signals generally, and umami taste in particular, are processed in taste buds.

Published

2009

38. Interaction between the second messengers cAMP and Ca2+ in mouse presynaptic taste cells.

Author

Roberts CD, Dvoryanchikov G, Roper SD, and Chaudhari N

Subjects

1-Methyl-3-isobutylxanthine pharmacology, Animals, Calcium metabolism, Calcium Channel Blockers pharmacology, Calcium Channels, L-Type drug effects, Calcium Channels, L-Type physiology, Calcium Channels, P-Type drug effects, Calcium Channels, P-Type physiology, Calcium Channels, Q-Type drug effects, Calcium Channels, Q-Type physiology, Calcium Signaling drug effects, Calcium Signaling genetics, Calcium Signaling physiology, Colforsin pharmacology, Cyclic AMP-Dependent Protein Kinases metabolism, Glutamate Decarboxylase biosynthesis, Glutamate Decarboxylase genetics, Image Processing, Computer-Assisted, Mice, Mice, Inbred C57BL, Phosphodiesterase Inhibitors pharmacology, Receptors, G-Protein-Coupled physiology, Receptors, Presynaptic drug effects, Receptors, Presynaptic genetics, Reverse Transcriptase Polymerase Chain Reaction, Second Messenger Systems drug effects, Second Messenger Systems genetics, Taste Buds drug effects, Calcium physiology, Cyclic AMP physiology, Receptors, Presynaptic physiology, Second Messenger Systems physiology, Taste Buds physiology

Abstract

The second messenger, 3',5'-cyclic adenosine monophosphate (cAMP), is known to be modulated in taste buds following exposure to gustatory and other stimuli. Which taste cell type(s) (Type I/glial-like cells, Type II/receptor cells, or Type III/presynaptic cells) undergo taste-evoked changes of cAMP and what the functional consequences of such changes are remain unknown. Using Fura-2 imaging of isolated mouse vallate taste cells, we explored how elevating cAMP alters Ca(2+) levels in identified taste cells. Stimulating taste buds with forskolin (Fsk; 1 microm) + isobutylmethylxanthine (IBMX; 100 microm), which elevates cellular cAMP, triggered Ca(2+) transients in 38% of presynaptic cells (n = 128). We used transgenic GAD-GFP mice to show that cAMP-triggered Ca(2+) responses occur only in the subset of presynaptic cells that lack glutamic acid decarboxylase 67 (GAD). We never observed cAMP-stimulated responses in receptor cells, glial-like cells or GAD-expressing presynaptic cells. The response to cAMP was blocked by the protein kinase A inhibitor H89 and by removing extracellular Ca(2+). Thus, the response to elevated cAMP is a PKA-dependent influx of Ca(2+). This Ca(2+) influx was blocked by nifedipine (an inhibitor of L-type voltage-gated Ca(2+) channels) but was unperturbed by omega-agatoxin IVA and omega-conotoxin GVIA (P/Q-type and N-type channel inhibitors, respectively). Single-cell RT-PCR on functionally identified presynaptic cells from GAD-GFP mice confirmed the pharmacological analyses: Ca(v)1.2 (an L-type subunit) is expressed in cells that display cAMP-triggered Ca(2+) influx, while Ca(v)2.1 (a P/Q subunit) is expressed in all presynaptic cells, and underlies depolarization-triggered Ca(2+) influx. Collectively, these data demonstrate cross-talk between cAMP and Ca(2+) signalling in a subclass of taste cells that form synapses with gustatory fibres and may integrate tastant-evoked signals.

Published

2009

39. Norepinephrine is coreleased with serotonin in mouse taste buds.

Author

Huang YA, Maruyama Y, and Roper SD

Subjects

Adrenergic alpha-Antagonists pharmacology, Animals, CHO Cells, Chemoreceptor Cells drug effects, Cricetinae, Cricetulus, Cycloheximide pharmacology, Fura-2, Indicators and Reagents, Mice, Mice, Inbred C57BL, Mice, Transgenic, Norepinephrine pharmacology, Potassium Chloride pharmacology, Quaternary Ammonium Compounds pharmacology, Receptors, Adrenergic, alpha-1 genetics, Saccharin pharmacology, Synaptic Transmission drug effects, Taste drug effects, Taste physiology, Taste Buds drug effects, Tongue innervation, Chemoreceptor Cells metabolism, Norepinephrine metabolism, Serotonin metabolism, Synaptic Transmission physiology, Taste Buds metabolism, Tongue physiology

Abstract

ATP and serotonin (5-HT) are neurotransmitters secreted from taste bud receptor (type II) and presynaptic (type III) cells, respectively. Norepinephrine (NE) has also been proposed to be a neurotransmitter or paracrine hormone in taste buds. Yet, to date, the specific stimulus for NE release in taste buds is not well understood, and the identity of the taste cells that secrete NE is not known. Chinese hamster ovary cells were transfected with alpha(1A) adrenoceptors and loaded with fura-2 ("biosensors") to detect NE secreted from isolated mouse taste buds and taste cells. Biosensors responded to low concentrations of NE (>or=10 nm) with a reliable fura-2 signal. NE biosensors did not respond to stimulation with KCl or taste compounds. However, we recorded robust responses from NE biosensors when they were positioned against mouse circumvallate taste buds and the taste buds were stimulated with KCl (50 mm) or a mixture of taste compounds (cycloheximide, 10 microm; saccharin, 2 mm; denatonium, 1 mm; SC45647, 100 microm). NE biosensor responses evoked by stimulating taste buds were reversibly blocked by prazosin, an alpha(1A) receptor antagonist. Together, these findings indicate that taste bud cells secrete NE when they are stimulated. We isolated individual taste bud cells to identify the origin of NE release. NE was secreted only from presynaptic (type III) taste cells and not receptor (type II) cells. Stimulus-evoked NE release depended on Ca(2+) in the bathing medium. Using dual biosensors (sensitive to 5-HT and NE), we found all presynaptic cells secrete 5-HT and 33% corelease NE with 5-HT.

Published

2008

40. ATP release through connexin hemichannels and gap junction transfer of second messengers propagate Ca2+ signals across the inner ear.

Author

Anselmi F, Hernandez VH, Crispino G, Seydel A, Ortolano S, Roper SD, Kessaris N, Richardson W, Rickheit G, Filippov MA, Monyer H, and Mammano F

Subjects

Animals, Cations, Divalent metabolism, Connexin 26, Connexin 30, Connexins genetics, Connexins metabolism, Fluoresceins metabolism, HeLa Cells, Humans, Inositol 1,4,5-Trisphosphate metabolism, Light, Mice, Nucleotidases metabolism, Tissue Culture Techniques, Adenosine Triphosphate metabolism, Calcium metabolism, Ear, Inner cytology, Ear, Inner metabolism, Gap Junctions metabolism, Second Messenger Systems physiology, Signal Transduction physiology

Abstract

Extracellular ATP controls various signaling systems including propagation of intercellular Ca(2+) signals (ICS). Connexin hemichannels, P2x7 receptors (P2x7Rs), pannexin channels, anion channels, vesicles, and transporters are putative conduits for ATP release, but their involvement in ICS remains controversial. We investigated ICS in cochlear organotypic cultures, in which ATP acts as an IP(3)-generating agonist and evokes Ca(2+) responses that have been linked to noise-induced hearing loss and development of hair cell-afferent synapses. Focal delivery of ATP or photostimulation with caged IP(3) elicited Ca(2+) responses that spread radially to several orders of unstimulated cells. Furthermore, we recorded robust Ca(2+) signals from an ATP biosensor apposed to supporting cells outside the photostimulated area in WT cultures. ICS propagated normally in cultures lacking either P2x7R or pannexin-1 (Px1), as well as in WT cultures exposed to blockers of anion channels. By contrast, Ca(2+) responses failed to propagate in cultures with defective expression of connexin 26 (Cx26) or Cx30. A companion paper demonstrates that, if expression of either Cx26 or Cx30 is blocked, expression of the other is markedly down-regulated in the outer sulcus. Lanthanum, a connexin hemichannel blocker that does not affect gap junction (GJ) channels when applied extracellularly, limited the propagation of Ca(2+) responses to cells adjacent to the photostimulated area. Our results demonstrate that these connexins play a dual crucial role in inner ear Ca(2+) signaling: as hemichannels, they promote ATP release, sustaining long-range ICS propagation; as GJ channels, they allow diffusion of Ca(2+)-mobilizing second messengers across coupled cells.

Published

2008

41. Presynaptic (Type III) cells in mouse taste buds sense sour (acid) taste.

Author

Huang YA, Maruyama Y, Stimac R, and Roper SD

Subjects

Animals, Cells, Cultured, Female, Hydrogen-Ion Concentration, Male, Mice, Mice, Inbred C57BL, Presynaptic Terminals physiology, Presynaptic Terminals ultrastructure, Receptors, Presynaptic physiology, Taste physiology, Taste Buds cytology, Taste Buds physiology, Tongue cytology, Tongue physiology

Abstract

Taste buds contain two types of cells that directly participate in taste transduction - receptor (Type II) cells and presynaptic (Type III) cells. Receptor cells respond to sweet, bitter and umami taste stimulation but until recently the identity of cells that respond directly to sour (acid) tastants has only been inferred from recordings in situ, from behavioural studies, and from immunostaining for putative sour transduction molecules. Using calcium imaging on single isolated taste cells and with biosensor cells to identify neurotransmitter release, we show that presynaptic (Type III) cells specifically respond to acid taste stimulation and release serotonin. By recording responses in cells isolated from taste buds and in taste cells in lingual slices to acetic acid titrated to different acid levels (pH), we also show that the active stimulus for acid taste is the membrane-permeant, uncharged acetic acid moiety (CH(3)COOH), not free protons (H(+)). That observation is consistent with the proximate stimulus for acid taste being intracellular acidification, not extracellular protons per se. These findings may also have implications for other sensory receptors that respond to acids, such as nociceptors.

Published

2008

42. Imaging cyclic AMP changes in pancreatic islets of transgenic reporter mice.

Author

Kim JW, Roberts CD, Berg SA, Caicedo A, Roper SD, and Chaudhari N

Subjects

Amino Acid Substitution, Animals, Bacterial Proteins genetics, Colforsin pharmacology, Cyclic AMP-Dependent Protein Kinases genetics, Fluorescence Resonance Energy Transfer, Genes, Reporter, Glucose physiology, Insulin-Secreting Cells physiology, Luminescent Proteins genetics, Mice, Mice, Transgenic, Signal Transduction physiology, Cyclic AMP metabolism, Islets of Langerhans physiology

Abstract

Cyclic AMP (cAMP) and Ca(2+) are two ubiquitous second messengers in transduction pathways downstream of receptors for hormones, neurotransmitters and local signals. The availability of fluorescent Ca(2+) reporter dyes that are easily introduced into cells and tissues has facilitated analysis of the dynamics and spatial patterns for Ca(2+) signaling pathways. A similar dissection of the role of cAMP has lagged because indicator dyes do not exist. Genetically encoded reporters for cAMP are available but they must be introduced by transient transfection in cell culture, which limits their utility. We report here that we have produced a strain of transgenic mice in which an enhanced cAMP reporter is integrated in the genome and can be expressed in any targeted tissue and with tetracycline induction. We have expressed the cAMP reporter in beta-cells of pancreatic islets and conducted an analysis of intracellular cAMP levels in relation to glucose stimulation, Ca(2+) levels, and membrane depolarization. Pancreatic function in transgenic mice was normal. In induced transgenic islets, glucose evoked an increase in cAMP in beta-cells in a dose-dependent manner. The cAMP response is independent of (in fact, precedes) the Ca(2+) influx that results from glucose stimulation of islets. Glucose-evoked cAMP responses are synchronous in cells throughout the islet and occur in 2 phases suggestive of the time course of insulin secretion. Insofar as cAMP in islets is known to potentiate insulin secretion, the novel transgenic mouse model will for the first time permit detailed analyses of cAMP signals in beta-cells within islets, i.e. in their native physiological context. Reporter expression in other tissues (such as the heart) where cAMP plays a critical regulatory role, will permit novel biomedical approaches.

Published

2008

43. Breadth of tuning and taste coding in mammalian taste buds.

Author

Tomchik SM, Berg S, Kim JW, Chaudhari N, and Roper SD

Subjects

Animals, Glutamate Decarboxylase genetics, Green Fluorescent Proteins genetics, In Vitro Techniques, Mice, Mice, Inbred C57BL, Mice, Transgenic, Phospholipase C beta genetics, Potassium Chloride pharmacology, Presynaptic Terminals drug effects, Presynaptic Terminals physiology, Serotonin metabolism, Sweetening Agents pharmacology, Synaptosomal-Associated Protein 25 metabolism, Neurons, Afferent physiology, Presynaptic Terminals metabolism, Taste physiology, Taste Buds cytology

Abstract

A longstanding question in taste research concerns taste coding and, in particular, how broadly are individual taste bud cells tuned to taste qualities (sweet, bitter, umami, salty, and sour). Taste bud cells express G-protein-coupled receptors for sweet, bitter, or umami tastes but not in combination. However, responses to multiple taste qualities have been recorded in individual taste cells. We and others have shown previously there are two classes of taste bud cells directly involved in gustatory signaling: "receptor" (type II) cells that detect and transduce sweet, bitter, and umami compounds, and "presynaptic" (type III) cells. We hypothesize that receptor cells transmit their signals to presynaptic cells. This communication between taste cells could represent a potential convergence of taste information in the taste bud, resulting in taste cells that would respond broadly to multiple taste stimuli. We tested this hypothesis using calcium imaging in a lingual slice preparation. Here, we show that receptor cells are indeed narrowly tuned: 82% responded to only one taste stimulus. In contrast, presynaptic cells are broadly tuned: 83% responded to two or more different taste qualities. Receptor cells responded to bitter, sweet, or umami stimuli but rarely to sour or salty stimuli. Presynaptic cells responded to all taste qualities, including sour and salty. These data further elaborate functional differences between receptor cells and presynaptic cells, provide strong evidence for communication within the taste bud, and resolve the paradox of broad taste cell tuning despite mutually exclusive receptor expression.

Published

2007

44. Signal transduction and information processing in mammalian taste buds.

Author

Roper SD

Subjects

Acids pharmacology, Adenosine Triphosphate metabolism, Animals, Calcium Signaling drug effects, Calcium Signaling physiology, Cell Communication drug effects, Cell Communication physiology, Epithelial Sodium Channel Agonists, Epithelial Sodium Channels metabolism, Humans, Ion Channels agonists, Ion Channels metabolism, Neurotransmitter Agents metabolism, Receptors, G-Protein-Coupled agonists, Receptors, G-Protein-Coupled physiology, Serotonin metabolism, Sodium Chloride, Dietary administration & dosage, Sodium Glutamate pharmacology, Stimulation, Chemical, Sucrose pharmacology, Taste Buds cytology, Second Messenger Systems physiology, Synaptic Transmission physiology, Taste physiology, Taste Buds physiology

Abstract

The molecular machinery for chemosensory transduction in taste buds has received considerable attention within the last decade. Consequently, we now know a great deal about sweet, bitter, and umami taste mechanisms and are gaining ground rapidly on salty and sour transduction. Sweet, bitter, and umami tastes are transduced by G-protein-coupled receptors. Salty taste may be transduced by epithelial Na channels similar to those found in renal tissues. Sour transduction appears to be initiated by intracellular acidification acting on acid-sensitive membrane proteins. Once a taste signal is generated in a taste cell, the subsequent steps involve secretion of neurotransmitters, including ATP and serotonin. It is now recognized that the cells responding to sweet, bitter, and umami taste stimuli do not possess synapses and instead secrete the neurotransmitter ATP via a novel mechanism not involving conventional vesicular exocytosis. ATP is believed to excite primary sensory afferent fibers that convey gustatory signals to the brain. In contrast, taste cells that do have synapses release serotonin in response to gustatory stimulation. The postsynaptic targets of serotonin have not yet been identified. Finally, ATP secreted from receptor cells also acts on neighboring taste cells to stimulate their release of serotonin. This suggests that there is important information processing and signal coding taking place in the mammalian taste bud after gustatory stimulation.

Published

2007

45. The role of pannexin 1 hemichannels in ATP release and cell-cell communication in mouse taste buds.

Author

Huang YJ, Maruyama Y, Dvoryanchikov G, Pereira E, Chaudhari N, and Roper SD

Subjects

Animals, CHO Cells, Calcium metabolism, Connexins, Cricetinae, Cricetulus, In Situ Hybridization, Mice, Nerve Tissue Proteins genetics, Nerve Tissue Proteins physiology, Reverse Transcriptase Polymerase Chain Reaction, Serotonin metabolism, Adenosine Triphosphate metabolism, Cell Communication physiology, Nerve Tissue Proteins metabolism, Signal Transduction physiology, Taste Buds physiology

Abstract

ATP has been shown to be a taste bud afferent transmitter, but the cells responsible for, and the mechanism of, its release have not been identified. Using CHO cells expressing high-affinity neurotransmitter receptors as biosensors, we show that gustatory stimuli cause receptor cells to secrete ATP through pannexin 1 hemichannels in mouse taste buds. ATP further stimulates other taste cells to release a second transmitter, serotonin. These results provide a mechanism to link intracellular Ca(2+) release during taste transduction to secretion of afferent transmitter, ATP, from receptor cells. They also indicate a route for cell-cell communication and signal processing within the taste bud.

Published

2007

46. Cell communication in taste buds.

Author

Roper SD

Subjects

Adenosine Triphosphate metabolism, Animals, Forecasting, Humans, Neurotransmitter Agents, Receptors, Serotonin metabolism, Serotonin metabolism, Cell Communication, Chemoreceptor Cells physiology, Signal Transduction physiology, Taste Buds physiology

Abstract

Taste bud cells communicate with sensory afferent fibers and may also exchange information with adjacent cells. Indeed, communication between taste cells via conventional and/or novel synaptic interactions may occur prior to signal output to primary afferent fibers. This review discusses synaptic processing in taste buds and summarizes results showing that it is now possible to measure real-time release of synaptic transmitters during taste stimulation using cellular biosensors. There is strong evidence that serotonin and ATP play a role in cell-to-cell signaling and sensory output in the gustatory end organs.

Published

2006

47. Separate populations of receptor cells and presynaptic cells in mouse taste buds.

Author

DeFazio RA, Dvoryanchikov G, Maruyama Y, Kim JW, Pereira E, Roper SD, and Chaudhari N

Subjects

Animals, Calcium physiology, Mice, Mice, Inbred C57BL, Models, Animal, Potassium pharmacology, Potassium Chloride pharmacology, Presynaptic Terminals drug effects, Reverse Transcriptase Polymerase Chain Reaction, Sensory Receptor Cells physiology, Sodium Chloride pharmacology, Presynaptic Terminals physiology, Taste Buds physiology

Abstract

Taste buds are aggregates of 50-100 cells, only a fraction of which express genes for taste receptors and intracellular signaling proteins. We combined functional calcium imaging with single-cell molecular profiling to demonstrate the existence of two distinct cell types in mouse taste buds. Calcium imaging revealed that isolated taste cells responded with a transient elevation of cytoplasmic Ca2+ to either tastants or depolarization with KCl, but never both. Using single-cell reverse transcription (RT)-PCR, we show that individual taste cells express either phospholipase C beta2 (PLCbeta2) (an essential taste transduction effector) or synaptosomal-associated protein 25 (SNAP25) (a key component of calcium-triggered transmitter exocytosis). The two functional classes revealed by calcium imaging mapped onto the two gene expression classes determined by single-cell RT-PCR. Specifically, cells responding to tastants expressed PLCbeta2, whereas cells responding to KCl depolarization expressed SNAP25. We demonstrate this by two methods: first, through sequential calcium imaging and single-cell RT-PCR; second, by performing calcium imaging on taste buds in slices from transgenic mice in which PLCbeta2-expressing taste cells are labeled with green fluorescent protein. To evaluate the significance of the SNAP25-expressing cells, we used RNA amplification from single cells, followed by RT-PCR. We show that SNAP25-positive cells also express typical presynaptic proteins, including a voltage-gated calcium channel (alpha1A), neural cell adhesion molecule, synapsin-II, and the neurotransmitter-synthesizing enzymes glutamic acid decarboxylase and aromatic amino acid decarboxylase. No synaptic markers were detected in PLCbeta2 cells by either amplified RNA profiling or by immunocytochemistry. These data demonstrate the existence of at least two molecularly distinct functional classes of taste cells: receptor cells and synapse-forming cells.

Published

2006

48. Umami responses in mouse taste cells indicate more than one receptor.

Author

Maruyama Y, Pereira E, Margolskee RF, Chaudhari N, and Roper SD

Subjects

Animals, Cells, Cultured, Dose-Response Relationship, Drug, Mice, Mice, Inbred C57BL, Phospholipase C beta, Taste drug effects, Taste Buds drug effects, Calcium Signaling physiology, Glutamic Acid administration & dosage, Isoenzymes metabolism, Receptors, Cell Surface metabolism, Taste physiology, Taste Buds physiology, Type C Phospholipases metabolism

Abstract

A number of gustatory receptors have been proposed to underlie umami, the taste of L-glutamate, and certain other amino acids and nucleotides. However, the response profiles of these cloned receptors have not been validated against responses recorded from taste receptor cells that are the native detectors of umami taste. We investigated umami taste responses in mouse circumvallate taste buds in an intact slice preparation, using confocal calcium imaging. Approximately 5% of taste cells selectively responded to L-glutamate when it was focally applied to the apical chemosensitive tips of receptor cells. The concentration-response range for L-glutamate fell approximately within the physiologically relevant range for taste behavior in mice, namely 10 mm and above. Inosine monophosphate enhanced taste cell responses to L-glutamate, a characteristic feature of umami taste. Using pharmacological agents, ion substitution, and immunostaining, we showed that intracellular pathways downstream of receptor activation involve phospholipase C beta2. Each of the above features matches those predicted by studies of cloned and expressed receptors. However, the ligand specificity of each of the proposed umami receptors [taste metabotropic glutamate receptor 4, truncated metabotropic glutamate receptor 1, or taste receptor 1 (T1R1) and T1R3 dimers], taken alone, did not appear to explain the taste responses observed in mouse taste cells. Furthermore, umami responses were still observed in mutant mice lacking T1R3. A full explanation of umami taste transduction may involve novel combinations of the proposed receptors and/or as-yet-undiscovered taste receptors.

Published

2006

49. PLCbeta2-independent behavioral avoidance of prototypical bitter-tasting ligands.

Author

Dotson CD, Roper SD, and Spector AC

Subjects

Animals, Dose-Response Relationship, Drug, Ligands, Mice, Mice, Knockout, Nerve Tissue Proteins deficiency, Phosphoinositide Phospholipase C, Quaternary Ammonium Compounds administration & dosage, Quinine administration & dosage, Sensory Thresholds, Signal Transduction, Stimulation, Chemical, Sucrose administration & dosage, Type C Phospholipases deficiency, Avoidance Learning physiology, Nerve Tissue Proteins physiology, Taste, Type C Phospholipases physiology

Abstract

Using a brief-access taste assay, we show in the present report that although phospholipase C beta2 knockout (PLCbeta2 KO) mice are unresponsive to low- and midrange concentrations of quinine and denatonium, they do significantly avoid licking higher concentrations of these aversive compounds. PLCbeta2 KO mice displayed no concentration-dependent licking of the prototypical sweetener sucrose but were similar to wild-type mice in their responses to citric acid and NaCl, notwithstanding some interesting exceptions. Although these findings confirm an essential role for PLCbeta2 in taste responsiveness to sucrose and to low- to midrange concentrations of quinine and denatonium in mice as previously reported, they importantly suggest that higher concentrations of the latter two compounds, which are bitter to humans, can engage a PLCbeta2-independent taste transduction pathway.

Published

2005

50. Using biosensors to detect the release of serotonin from taste buds during taste stimulation.

Author

Huang YJ, Maruyama Y, Lu KS, Pereira E, Plonsky I, Baur JE, Wu D, and Roper SD

Subjects

Adenosine Triphosphate metabolism, Adenosine Triphosphate pharmacology, Animals, CHO Cells, Calcium Signaling drug effects, Calcium Signaling physiology, Cell Communication drug effects, Cell Communication physiology, Cricetinae, Epithelial Cells metabolism, Female, Fura-2, Indicators and Reagents, Mice, Organ Culture Techniques, Receptors, Serotonin drug effects, Receptors, Serotonin metabolism, Serotonin pharmacology, Signal Transduction drug effects, Synaptic Transmission drug effects, Taste Buds drug effects, Biosensing Techniques methods, Serotonin metabolism, Signal Transduction physiology, Synaptic Transmission physiology, Taste physiology, Taste Buds metabolism

Abstract

CHO cells transfected with high-affinity 5HT receptors were used to detect and identify the release of serotonin from taste buds. Taste cells release 5HT when depolarized or when stimulated with bitter, sweet, or sour tastants. Sour- and depolarization-evoked release of 5HT from taste buds is triggered by Ca2+ influx from the extracellular fluid. In contrast, bitter- and sweet-evoked release of 5HT is triggered by Ca2+ derived from intracellular stores.

Published

2005