関: phenylthiocarbamide

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出典(authority):フリー百科事典『ウィキペディア（Wikipedia）』「2015/12/30 13:21:50」(JST)

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Phenylthiocarbamide (PTC), also known as phenylthiourea (PTU), is an organosulfur thiourea containing a phenyl ring.

It has the unusual property that it either tastes very bitter or is virtually tasteless, depending on the genetic makeup of the taster. The ability to taste PTC is often treated as a dominant genetic trait, although inheritance and expression of this trait are somewhat more complex.^[1]^[2]

PTC also inhibits melanogenesis and is used to grow transparent fish.^[3]

About 70% of people can taste PTC, varying from a low of 58% for indigenous peoples of Australia and New Guinea to 98% for indigenous peoples of the Americas.^[4] One study has found that non-smokers and those not habituated to coffee or tea have a statistically higher percentage of tasting PTC than the general population.^[5]^[6] PTC does not occur in food, but related chemicals do, and food choice is related to a person's ability to taste PTC.^[5]^[7]

History

The genetic taste phenomenon of PTC was discovered in 1931 when a DuPont chemist named Arthur Fox accidentally released a cloud of a fine crystalline PTC. A nearby colleague complained about the bitter taste, while Fox, who was closer and should have received a strong dose, tasted nothing. Fox then continued to test the taste buds of assorted family and friends, setting the groundwork for future genetic studies. The genetic correlation was so strong that it was used in paternity tests before the advent of DNA matching.^[8]

The PTC taste test has been widely used in school and college practical teaching as an example of Mendelian polymorphism in human populations. Based on a taste test, usually of a piece of paper soaked in PTC (or the less toxic PROP), students are divided into taster and non-taster groups. By assuming that PTC tasting is determined by a dominant allele at a single autosomal gene, and that the class is an unbiased sample from a population in Hardy-Weinberg equilibrium, students then estimate allele and genotype frequencies within the broader population. While this interpretation is broadly consistent with numerous studies on this trait, it is worth noting that other genes, sex, age and environmental factors all influence sensitivity to PTC.^[1]^[2] Also, there are several alleles segregating at the major gene determining the taste of PTC, particularly in African populations, and the common "taster" allele is incompletely dominant (homozygotes for this allele are more sensitive to PTC than are heterozygotes).^[2]^[9] Additionally, PTC is toxic and sensitivity to the substitute, PROP, does not show a strong association with the gene controlling ability to taste PTC.^[2]

Role in taste

There is a large body of evidence linking the ability to taste thiourea compounds and dietary habits. Much of this work has focused on 6-propyl-2-thiouracil (PROP), a compound related to PTC that has lower toxicity.^[4] A supertaster has more of an ability to taste PTC. On the other hand, heavy cigarette smokers are more likely to have high PTC and PROP thresholds (i.e. are relatively insensitive).

In 1976, an inverse relationship between taster status for PTC and for a bitter component of the fruit of the tree Antidesma bunius was discovered.^[10] Research on the implications still continues.

Ability to taste PTC may be correlated with a dislike of plants in the Brassica genus, presumably due to chemical similarities. However, studies in Africa show a poor correlation between PTC tasting and dietary differences.^[9]

Genetics

Much of the variation in tasting of PTC is associated with polymorphism at the TAS2R38 taste receptor gene.^[11] In humans, there are three SNPs (single nucleotide polymorphisms) along the gene that may render its proteins unresponsive.^[12] There is conflicting evidence as to whether the inheritance of this trait is dominant or incompletely dominant.^[2] Any person with a single functional copy of this gene can make the protein and is sensitive to PTC.^{[citation needed]} Some studies have shown that homozygous tasters experience a more intense bitterness than people that are heterozygous; other studies have indicated that another gene may determine taste sensitivity.^[1]

The frequency of PTC taster and non-taster alleles vary in different human populations.^[13] The widespread occurrence of non-taster alleles at intermediate frequencies, much more common than recessive alleles conferring genetic disease, across many isolated populations, suggests that this polymorphism may have been maintained through balancing selection.^[9]

Chimpanzees and orangutans also vary in their ability to taste PTC, with the proportions of tasters and non-tasters similar to that in humans.^[14] The ability to taste PTC is an ancestral trait of hominids that has been independently lost in humans and chimpanzees, through distinct mutations at TAS2R38.^[15]

The frequency of "nontaster" phenotype (%) in selected populations

Discrimination method: Harris and Kalmus (1949)^[16]

Population	N	"Nontaster" (%)	References
Bosnia and Herzegovina	7.362	32,02	Hadžiselimović et al. (1982)
Croatia	200	27,5	Grünwald, Pfeifer (1962)
Czech Republic	785	32,7	Kubičkova, Dvořaková (1968)
Denmark	251	32,7	Harrison et al. (1964)
England	441	31,5	Harrison et al. (1964)
Hungary	436	32,2	Forai, Bankovi (1967)
Italia	1.031	29,19	Floris et al. (1976)
Montenegro	256	28,20	Hadžiselimović et al. (1982)
Serbia - Užice	1.129	16,65	Hadžiselimović et al. (1982)^[17]
Serbia - Voivodina	600	26,3	Božić, Gavrilović (1973)
Russia	486	36,6	Boyd (1950)
Slovenia	126	37,3	Brodar (1970)
Spain	203	25,6	Harrison et al. (1964)

References

^ ^a ^b ^c Guo; Reed, D. R. (2001). "The genetics of phenylthiocarbamide perception". Annals of Human Biology 28 (2): 111–142. doi:10.1080/03014460151056310. PMC 3349222. PMID 11293722.
^ ^a ^b ^c ^d ^e McDonald, John H. "PTC tasting: The Myth". Myths of Human Genetics. Retrieved 11 May 2015.
^ Karlsson, Johnny; von Hofsten, Jonas; Olsson, Per-Erik (2001). "Generating Transparent Zebrafish: A Refined Method to Improve Detection of Gene Expression During Embryonic Development". Marine Biotechnology 3 (6): 522–527. doi:10.1007/s1012601-0053-4. PMID 14961324.
^ ^a ^b Kim U, Wooding S, Ricci D, Jorde LB, Drayna D; Wooding; Ricci; Jorde; Drayna (2005). "Worldwide haplotype diversity and coding sequence variation at human bitter taste receptor loci". Human Mutation 26 (3): 199–204. doi:10.1002/humu.20203. PMID 16086309. Retrieved 29 April 2015.
^ ^a ^b Fischer, R., Griffin, F. and Kaplan, A. R. (1963). "Taste thresholds, cigarette smoking, and food dislikes". Medicina experimentalis. International journal of experimental medicine 9 (3): 151–67. doi:10.1159/000135346. PMID 14083335.
^ Kaplan AR, Glanville EV, Fischer R; Glanville; Fischer (1964). "Taste thresholds for bitterness and cigarette smoking". Nature 202 (4939): 1366. Bibcode:1964Natur.202.1366K. doi:10.1038/2021366a0. PMID 14210998.
^ Forrai G, Bánkövi G; Bánkövi (1984). "Taste perception for phenylthiourea and food choice—a Hungarian twin study". Acta Physiol Hung 64 (1): 33–40. PMID 6541419.
^ Lee Phillips M (15 July 2003). "Scientists Find Bitter Taste Gene". Retrieved 5 December 2009.
^ ^a ^b ^c Campbell; et al. (2012). "Evolution of Functionally Diverse Alleles Associated with PTC Bitter Taste Sensitivity in Africa". Molecular Biology and Evolution 29 (4): 1141–1153. doi:10.1093/molbev/msr293. PMC 3341826. PMID 22130969.
^ Henkin, R.I. and W.T. Gillis (1977). "Divergent taste responsiveness to fruit of the tree Antidesma bunius". Nature 265 (5594): 536–537. Bibcode:1977Natur.265..536H. doi:10.1038/265536a0. PMID 834304.
^ Drayna, Dennis (2005). "Human Taste Genetics". Annual Review of Genomics and Human Genetics 6: 217–235. doi:10.1146/annurev.genom.6.080604.162340. PMID 16124860.
^ Kim UK, Jorgenson E, Coon H, Leppert M, Risch N, Drayna D; Jorgenson; Coon; Leppert; Risch; Drayna (2003). "Positional cloning of the human quantitative trait locus underlying taste sensitivity to phenylthiocarbamide". Science 299 (5610): 1221–1225. Bibcode:2003Sci...299.1221K. doi:10.1126/science.1080190. PMID 12595690.
^ Fareed, M.; Shah, A.; Hussain, R.; Afzal, M. (2012). "Genetic study of phenylthiocarbamide (PTC) taste perception among six human populations of Jammu and Kashmir (India)". Egypt J Med Hum Genet 13 (2): 161–166. doi:10.1016/j.ejmhg.2012.01.003.
^ Fisher, Ford & Huxley, R. A.; Ford, E. B.; Huxley, Julian (28 October 1939). "Taste-testing the Anthropoid Apes". Nature 144 (750): 750. Bibcode:1939Natur.144..750F. doi:10.1038/144750a0.
^ Wooding, Stephen; et al. (2006). "Independent evolution of bitter-taste sensitivity in humans and chimpanzees". Nature 440 (7086): 930–934. Bibcode:2006Natur.440..930W. doi:10.1038/nature04655. PMID 16612383.
^ Harris, H.; Kalmus, H. (1949). "The measurement of taste sensitivity to phenylthiourea (PTC)". Ann. Eugen 15: 24–31. doi:10.1111/j.1469-1809.1949.tb02419.x. PMID 15403125.
^ Hadžiselimović R., Novosel, V., Bukvić, S., Vrbić, N. (1982): Distribucija praga nadražaja za ukus feniltiokarbamida (PTC) u tri uzorka stanovništva Jugoslavije. God. Biol. inst. Univ. u Sarajevu, 35: 72-80.

External links

Dennis Drayna's home page. Drayna has done extensive studies of PTC in various populations
Population Study and Applications Using PTC Paper
Classroom activity description using PTC paper
Online 'Mendelian Inheritance in Man' (OMIM) 171200 Thiourea tasting

UpToDate Contents

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1. 薬理ゲノム学の概要 overview of pharmacogenomics

English Journal

Influence of the alkylsulfonylamino substituent located at the 6-position of 2,2-dimethylchromans structurally related to cromakalim: from potassium channel openers to calcium entry blockers?

Florence X1, Desvaux V2, Goffin E3, de Tullio P3, Pirotte B3, Lebrun P4.
European journal of medicinal chemistry.Eur J Med Chem.2014 Jun 10;80:36-46. doi: 10.1016/j.ejmech.2014.04.024. Epub 2014 Apr 13.
The present study described the synthesis of original R/S-6-alkylsulfonylamino-3,4-dihydro-2,2-dimethyl-2H-1-benzopyrans bearing a 3- or 4-substituted phenylthiourea or phenylurea moiety at the 4-position. Their biological effects were evaluated both on insulin-secreting and smooth muscle cells and
PMID 24763361

Rhododendrol, a depigmentation-inducing phenolic compound, exerts melanocyte cytotoxicity via a tyrosinase-dependent mechanism.

Sasaki M1, Kondo M, Sato K, Umeda M, Kawabata K, Takahashi Y, Suzuki T, Matsunaga K, Inoue S.
Pigment cell & melanoma research.Pigment Cell Melanoma Res.2014 May 29. doi: 10.1111/pcmr.12269. [Epub ahead of print]
Rhododendrol, an inhibitor of melanin synthesis developed for lightening/whitening cosmetics, was recently reported to induce a depigmentary disorder principally at the sites of repeated chemical contact. Rhododendrol competitively inhibited mushroom tyrosinase and served as a good substrate, while
PMID 24890809

Assessment of Cuscuta chinensis seeds׳ effect on melanogenesis: comparison of water and ethanol fractions in vitro and in vivo.

Wang TJ1, An J2, Chen XH3, Deng QD4, Yang L5.
Journal of ethnopharmacology.J Ethnopharmacol.2014 May 28;154(1):240-8. doi: 10.1016/j.jep.2014.04.016. Epub 2014 Apr 16.
ETHNOPHARMACOLOGICAL RELEVANCE: Cuscuta chinensis seeds have traditionally been used to treat freckles and melasma in Asia, although recent reports have revealed that Semen cuscutae is a promoter of melanogenesis. The present study aims to investigate the mechanism of this opposite effect of Semen c
PMID 24746484

Japanese Journal

Depigmentation of Melanocytes by Isopanduratin A and 4-Hydroxypanduratin A Isolated from Kaempferia pandurata ROXB(Biopharmacy)

Yoon Ji-Hoon,Shim Jae-Seok,Cho Yumi [他],BAEK Nam-In,LEE Chan-Woo,KIM Han-Sung,HWANG Jae-Kwan
Biological & pharmaceutical bulletin 30(11), 2141-2145, 2007-11-01
… Compared with phenylthiourea (IC_<50>=34.3μM) as a positive control, the depigmentation IC_<50> … values of isopanduratin A and 4-hydroxypanduratin A for tyrosinase were 10.5μM and >30μM, respectively, while that of phenylthiourea was 47.6μM. …
NAID 110006473496

Regulation of Melanin Synthesis by Selenium-Containing Carbohydrates

Ahn Sang Joon,Koketsu Mamoru,Ishihara Hideharu [他],LEE Soo Min,HA Sang Keun,LEE Kun Ho,KANG Tong Ho,KIM Sun Yeou
Chemical & pharmaceutical bulletin 54(3), 281-286, 2006-03-01
… At 10μM, SG-3 inhibited melanin synthesis in the melan-a cells, and the effect was similar to phenylthiourea, which is a well-known inhibitor of melanin synthesis. …
NAID 110004820378

Structure-Activity Relationship of S-Benzylisothiourea Derivatives to Induce Spherical Cells in Escherichia coli

Iwai Noritaka,Ebata Takuma,Nagura Hirokatsu [他],KITAZUME Tomoya,NAGAI Kazuo,WACHI Masaaki
Bioscience, biotechnology, and biochemistry 68(11), 2265-2269, 2004-11-23
… <I>S</I>-Ethylisothiourea, benzylthiocyanate, benzylisocyanate, and <I>N</I>-phenylthiourea did not show any activity under the present experimental conditions. …
NAID 130000030913

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★リンクテーブル★

リンク元	「フェニルチオ尿素」「phenylthiocarbamide」

「フェニルチオ尿素」

Phenylthiocarbamide
Names
	IUPAC name Phenylthiourea
	Other names N-Phenylthiourea; 1-Phenylthiourea
Identifiers
CAS Number	103-85-5
ChEBI	CHEBI:46261
ChemSpider	589165
Jmol interactive 3D	Image
MeSH	Phenylthiourea
PubChem	676454
UNII	6F82C6Q54C
	InChI InChI=1S/C7H8N2S/c8-7(10)9-6-4-2-1-3-5-6/h1-5H,(H3,8,9,10) Key: FULZLIGZKMKICU-UHFFFAOYSA-N ; InChI=1/C7H8N2S/c8-7(10)9-6-4-2-1-3-5-6/h1-5H,(H3,8,9,10) Key: FULZLIGZKMKICU-UHFFFAOYAW ;
	SMILES C1=CC=C(C=C1)NC(=S)N ;
Properties
Chemical formula	C7H8N2S
Molar mass	152.22 g·mol−1
Appearance	White to slightly yellow powder
Density	1.294 g/cm3
Melting point	145 to 150 °C (293 to 302 °F; 418 to 423 K)
Solubility in water	Soluble in boiling water
Hazards
EU classification (DSD)	T+
NFPA 704	1 4 0
	Lethal dose or concentration (LD, LC):
LD50 (Median dose)	3 mg/kg (oral, rat)
	Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
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	Infobox references

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英: phenylthiourea PTU
関: フェニルチオカルバミド phenyl thiocarbamide PTC

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「phenylthiocarbamide」

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関: phenylthiourea

[Guo_.26_Reed-1] Guo; Reed, D. R. (2001). "The genetics of phenylthiocarbamide perception". Annals of Human Biology 28 (2): 111–142. doi:10.1080/03014460151056310. PMC 3349222. PMID 11293722.

[Myths_of_Human_Genetics-2] McDonald, John H. "PTC tasting: The Myth". Myths of Human Genetics. Retrieved 11 May 2015.

[3] Karlsson, Johnny; von Hofsten, Jonas; Olsson, Per-Erik (2001). "Generating Transparent Zebrafish: A Refined Method to Improve Detection of Gene Expression During Embryonic Development". Marine Biotechnology 3 (6): 522–527. doi:10.1007/s1012601-0053-4. PMID 14961324.

[SSC-4] Kim U, Wooding S, Ricci D, Jorde LB, Drayna D; Wooding; Ricci; Jorde; Drayna (2005). "Worldwide haplotype diversity and coding sequence variation at human bitter taste receptor loci". Human Mutation 26 (3): 199–204. doi:10.1002/humu.20203. PMID 16086309. Retrieved 29 April 2015.

[Fischer1963-5] Fischer, R., Griffin, F. and Kaplan, A. R. (1963). "Taste thresholds, cigarette smoking, and food dislikes". Medicina experimentalis. International journal of experimental medicine 9 (3): 151–67. doi:10.1159/000135346. PMID 14083335.

[6] Kaplan AR, Glanville EV, Fischer R; Glanville; Fischer (1964). "Taste thresholds for bitterness and cigarette smoking". Nature 202 (4939): 1366. Bibcode:1964Natur.202.1366K. doi:10.1038/2021366a0. PMID 14210998.

[7] Forrai G, Bánkövi G; Bánkövi (1984). "Taste perception for phenylthiourea and food choice—a Hungarian twin study". Acta Physiol Hung 64 (1): 33–40. PMID 6541419.

[8] Lee Phillips M (15 July 2003). "Scientists Find Bitter Taste Gene". Retrieved 5 December 2009.

[Campbell_et_al._2012-9] Campbell; et al. (2012). "Evolution of Functionally Diverse Alleles Associated with PTC Bitter Taste Sensitivity in Africa". Molecular Biology and Evolution 29 (4): 1141–1153. doi:10.1093/molbev/msr293. PMC 3341826. PMID 22130969.

[Henkin_and_Gillis-10] Henkin, R.I. and W.T. Gillis (1977). "Divergent taste responsiveness to fruit of the tree Antidesma bunius". Nature 265 (5594): 536–537. Bibcode:1977Natur.265..536H. doi:10.1038/265536a0. PMID 834304.

[Drayna_2005-11] Drayna, Dennis (2005). "Human Taste Genetics". Annual Review of Genomics and Human Genetics 6: 217–235. doi:10.1146/annurev.genom.6.080604.162340. PMID 16124860.

[Kim_2003-12] Kim UK, Jorgenson E, Coon H, Leppert M, Risch N, Drayna D; Jorgenson; Coon; Leppert; Risch; Drayna (2003). "Positional cloning of the human quantitative trait locus underlying taste sensitivity to phenylthiocarbamide". Science 299 (5610): 1221–1225. Bibcode:2003Sci...299.1221K. doi:10.1126/science.1080190. PMID 12595690.

[13] Fareed, M.; Shah, A.; Hussain, R.; Afzal, M. (2012). "Genetic study of phenylthiocarbamide (PTC) taste perception among six human populations of Jammu and Kashmir (India)". Egypt J Med Hum Genet 13 (2): 161–166. doi:10.1016/j.ejmhg.2012.01.003.

[Fisher.2C_Ford_.26_Huxley-14] Fisher, Ford & Huxley, R. A.; Ford, E. B.; Huxley, Julian (28 October 1939). "Taste-testing the Anthropoid Apes". Nature 144 (750): 750. Bibcode:1939Natur.144..750F. doi:10.1038/144750a0.

[Wooding_et_al._2006-15] Wooding, Stephen; et al. (2006). "Independent evolution of bitter-taste sensitivity in humans and chimpanzees". Nature 440 (7086): 930–934. Bibcode:2006Natur.440..930W. doi:10.1038/nature04655. PMID 16612383.

[16] Harris, H.; Kalmus, H. (1949). "The measurement of taste sensitivity to phenylthiourea (PTC)". Ann. Eugen 15: 24–31. doi:10.1111/j.1469-1809.1949.tb02419.x. PMID 15403125.

[17] Hadžiselimović R., Novosel, V., Bukvić, S., Vrbić, N. (1982): Distribucija praga nadražaja za ukus feniltiokarbamida (PTC) u tri uzorka stanovništva Jugoslavije. God. Biol. inst. Univ. u Sarajevu, 35: 72-80.

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phenylthiourea