The Taste of Monosodium Glutamate: Membrane Receptors in Taste Buds

Chaudhari, Nirupa; Yang, Hui; Lamp, Cynthia; Delay, Eugene R.; Cartford, Claire; Than, Trang; Roper, Stephen D.

doi:10.1523/jneurosci.16-12-03817.1996

Cited by 241 publications

(186 citation statements)

References 64 publications

(59 reference statements)

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“…The sensory innervation of the tongue is particularly interesting because it plays a major role not only in taste perceptions of sweet, sour, salt, bitter or umami (ASTBACK et al, 1995;CHAUDHARI et al, 1996), but also in information about the temperature and consistency of the food or drink. The PGP 9.5 immunoreactive nerve fibers supplying taste buds demonstrated in the present study would generally seem to represent the afferent innervation for those sensations.…”

Section: Methodological Considerationsmentioning

confidence: 99%

Immunohistochemical Studies on Protein Gene Product 9.5, Serotonin and Neuropeptides in Vallate Taste Buds and Related Nerves of the Guinea Pig.

1996

Archives of Histology and Cytology

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Section: Methodological Considerationsmentioning

confidence: 99%

Immunohistochemical Studies on Protein Gene Product 9.5, Serotonin and Neuropeptides in Vallate Taste Buds and Related Nerves of the Guinea Pig.

1996

Archives of Histology and Cytology

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“…Chaudhari et al [93,94] identified a truncated N-terminal version of mGluR4 in rat taste buds and showed that Chinese hamster ovary (CHO) cells expressing this receptor responded to L-glutamate in a concentration range appropriate for umami taste. Yang et al [95] showed by ISH that mGluR4 was expressed in a subset of rat taste bud cells.…”

Section: T2rs Are Gpc Receptors For Bitter Tastementioning

confidence: 99%

Signal transduction and information processing in mammalian taste buds

Roper

2007

Pflugers Arch - Eur J Physiol

261

212

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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 acidsensitive 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.

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“…Many tissues demonstrate Glu, GluR and GluTPs, including but not limited to, CNS 122 , autonomic and sensory ganglia 123 , peripheral nerves-myelinated and unmyelinated 124,125 , vagus and other cholinergic nerves 124 , tachykinin containing sensory nerves and vestibular tissues 1 2 6 , 1 2 7 retinal photoreceptors 1 2 8 -1 3 0 , Muller cells 1 2 8 , 1 3 1 , adrenal medulla 123,133 , pituitary 134 , pineal gland 135 , endocrine pancreas [136][137][138][139][140][141][142][143][144][145][146][147] , immune system 148 , taste buds 149,150 , esophagus 151 , gut 70,100,[152][153][154] , ileal longitudinal muscle [155][156][157] , h e pa to c yt e s 6 8 , 1 5 8 , k i d n e y , s p l e e n s , o v a r i e s 4 8 , 1 5 9 , lungs 60,99,145,148,154,[158][159][160][161][162][163][164][165] , heart …”

Section: ) Glutamatementioning

confidence: 99%

A Review of Glutamate Receptors I: Current Understanding of Their Biology

Rousseaux

2008

J Toxicol Pathol

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Seventy years ago it was discovered that glutamate is abundant in the brain and that it plays a central role in brain metabolism. However, it took the scientific community a long time to realize that glutamate also acts as a neurotransmitter. Glutamate is an amino acid and brain tissue contains as much as 5 -15 mM glutamate per kg depending on the region, which is more than of any other amino acid. The main motivation for the ongoing research on glutamate is due to the role of glutamate in the signal transduction in the nervous systems of apparently all complex living organisms, including man. Glutamate is considered to be the major mediator of excitatory signals in the mammalian central nervous system and is involved in most aspects of normal brain function including cognition, memory and learning. In this review, the basic biology of the excitatory amino acids glutamate, glutamate receptors, GABA, and glycine will first be explored. In the second part of this review, the known pathophysiology and pathology will be described. (J Toxicol Pathol 2008; 21: 25-51)

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The Taste of Monosodium Glutamate: Membrane Receptors in Taste Buds

Cited by 241 publications

References 64 publications

Immunohistochemical Studies on Protein Gene Product 9.5, Serotonin and Neuropeptides in Vallate Taste Buds and Related Nerves of the Guinea Pig.

Immunohistochemical Studies on Protein Gene Product 9.5, Serotonin and Neuropeptides in Vallate Taste Buds and Related Nerves of the Guinea Pig.

Signal transduction and information processing in mammalian taste buds

A Review of Glutamate Receptors I: Current Understanding of Their Biology

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