Dopamine receptor D₂

Dopamine receptor D2
Rendering based on PDB 1I15.
有效结构 PDB 直系同源检索：PDBe, RCSB PDB查询代码列表 1I15, 5AER
标识
代号	DRD2; D2DR; D2R
扩展标识	遗传学：126450 鼠基因：94924 同源基因：22561 IUPHAR:  D2 ChEMBL: 217 GeneCards: DRD2 Gene
基因本体论描述 分子功能 · dopamine neurotransmitter receptor activity, coupled via Gi/Go · adrenergic receptor activity · protein binding · drug binding · potassium channel regulator activity · dopamine binding · ionotropic glutamate receptor binding · identical protein binding · protein homodimerization activity · protein heterodimerization activity 细胞成分 · acrosomal vesicle · intracellular · cytosol · plasma membrane · integral component of plasma membrane · postsynaptic density · lateral plasma membrane · endocytic vesicle · axon · dendrite · synaptic vesicle membrane · nonmotile primary cilium · sperm flagellum · dendritic spine · perikaryon · axon terminus · ciliary membrane 生物过程 · temperature homeostasis · response to hypoxia · synaptic transmission, dopaminergic · response to amphetamine · neurological system process involved in regulation of systemic arterial blood pressure · regulation of heart rate · regulation of sodium ion transport · G-protein coupled receptor internalization · positive regulation of neuroblast proliferation · positive regulation of receptor internalization · cellular calcium ion homeostasis · negative regulation of adenylate cyclase activity · adenylate cyclase-inhibiting dopamine receptor signaling pathway · neuron-neuron synaptic transmission · axonogenesis · synapse assembly · sensory perception of smell · long-term memory · grooming behavior · locomotory behavior · adult walking behavior · feeding behavior · protein localization · negative regulation of cell proliferation · associative learning · visual learning · response to light stimulus · response to toxic substance · response to iron ion · regulation of dopamine secretion · response to inactivity · Wnt signaling pathway · striatum development · orbitofrontal cortex development · cerebral cortex GABAergic interneuron migration · adenohypophysis development · negative regulation of cell migration · peristalsis · regulation of cAMP metabolic process · auditory behavior · activation of protein kinase activity · regulation of synaptic transmission, GABAergic · positive regulation of cytokinesis · circadian regulation of gene expression · negative regulation of dopamine secretion · response to histamine · response to nicotine · intracellular signal transduction · positive regulation of urine volume · positive regulation of renal sodium excretion · positive regulation of multicellular organism growth · response to cocaine · negative regulation of circadian sleep/wake cycle, sleep · dopamine metabolic process · response to drug · regulation of potassium ion transport · response to morphine · pigmentation · regulation of phosphoprotein phosphatase activity · positive regulation of G-protein coupled receptor protein signaling pathway · negative regulation of blood pressure · negative regulation of innate immune response · positive regulation of transcription from RNA polymerase II promoter · phosphatidylinositol metabolic process · negative regulation of insulin secretion · behavioral response to cocaine · behavioral response to ethanol · regulation of long-term neuronal synaptic plasticity · response to axon injury · branching morphogenesis of a nerve · arachidonic acid secretion · negative regulation of protein secretion · release of sequestered calcium ion into cytosol · negative regulation of cytosolic calcium ion concentration · positive regulation of cytosolic calcium ion concentration involved in phospholipase C-activating G-protein coupled signaling pathway · regulation of dopamine uptake involved in synaptic transmission · positive regulation of dopamine uptake involved in synaptic transmission · regulation of synapse structural plasticity · negative regulation of protein kinase B signaling · negative regulation of synaptic transmission, glutamatergic · positive regulation of growth hormone secretion · prepulse inhibition · phospholipase C-activating dopamine receptor signaling pathway · negative regulation of dopamine receptor signaling pathway · positive regulation of ERK1 and ERK2 cascade · adenylate cyclase-activating adrenergic receptor signaling pathway · regulation of locomotion involved in locomotory behavior · positive regulation of glial cell-derived neurotrophic factor secretion · positive regulation of long-term synaptic potentiation · negative regulation of voltage-gated calcium channel activity Sources: Amigo / QuickGO
RNA表达模式
更多表达数据
直系同源体
物种	人类	小鼠
Entrez	1813	13489
Ensembl	ENSG00000149295	ENSMUSG00000032259
UniProt	P14416	P61168
mRNA序列	NM_000795	NM_010077
蛋白序列	NP_000786	NP_034207
基因位置	Chr 11: 113.41 – 113.48 Mb	Chr 9: 49.34 – 49.41 Mb
PubMed查询	[1]	[2]
查 论 编

Dopamine receptor D₂, also known as D2R, is a protein that, in humans, is encoded by the DRD2 gene.The dopamine D2 receptor was discovered in 1975 by Philip Seeman who had named it as the antipsychotic dopamine receptor ^[1] The dopamine D2 receptor is the main receptor for all antipsychotic drugs. Any drug that does not interfere with dopamine action at the D2 receptor does not have an antipsychotic action.

Function

This gene encodes the D₂ subtype of the dopamine receptor, which is coupled to G_i subtype of G protein-coupled receptor. This G protein-coupled receptor inhibits adenylyl cyclase activity.^[2]

In mice, regulation of D2R surface expression by the calcium sensor NCS-1 in the dentate gyrus is involved in exploration, synaptic plasticity and memory formation.^[3]

In flies, activation of the D2 autoreceptor protected dopamine neurons from cell death induced by a toxin mimicking Parkinson's disease pathology.^[4]

Isoforms

Alternative splicing of this gene results in three transcript variants encoding different isoforms.^[5]

The long form (D2Lh) has the "canonical" sequence and functions as a classic post-synaptic receptor.^[6] The short form (D2Sh) is pre-synaptic and functions as an autoreceptor that regulates the levels of dopamine in the synaptic cleft.^[6] Agonism of D2sh receptors inhibits dopamine release; antagonism increases dopaminergic release.^[6] A third D2(Longer) form differs from the canonical sequence where 270V is replaced by VVQ.^[7]

Genetics

Allelic variants:

• A-241G
• C132T, G423A, T765C, C939T, C957T, and G1101A^[8]
• Cys311Ser
• -141C insertion/deletion^[9] The polymorphisms have been investigated with respect to association with schizophrenia.^[10]

Some researchers have previously associated the polymorphism Taq 1A (rs1800497) to the DRD2 gene. However, the polymorphism resides in exon 8 of the ANKK1 gene.^[11] DRD2 TaqIA polymorphism has been reported to be associated with an increased risk for developing motor fluctuations but not hallucinations in Parkinson's disease.^[12][13]

Ligands

Most of the older antipsychotic drugs such as chlorpromazine and haloperidol are antagonists for the dopamine D₂ receptor, but are, in general, very unselective, at best selective only for the "D₂-like family" receptors and so binding to D₂, D₃ and D₄, and often also to many other receptors such as those for serotonin and histamine, resulting in a range of side-effects and making them poor agents for scientific research. In similar manner, older dopamine agonists used for Parkinson's disease such as bromocriptine and cabergoline are poorly selective for one dopamine receptor over another, and, although most of these agents do act as D₂ agonists, they affect other subtypes as well. Several selective D₂ ligands are, however, now available, and this number is likely to increase as further research progresses.

Agonists

• Bromocriptine – full agonist
• Cabergoline (Caberl)
• N,N-Propyldihydrexidine – analogue of the D₁/D₅ agonist dihydrexidine; Selective for postsynaptic D₂ receptor over the presynaptic D₂ autoreceptor.
• Piribedil – also D₃ receptor agonist and α₂–adrenergic antagonist
• Pramipexole – also D₃, D₄ receptor agonist
• Quinelorane – affinity for D₂ > D₃
• Quinpirole – also D₃ receptor agonist
• Ropinirole – full agonist
• Sumanirole – full agonist; highly selective
• Talipexole – selective for D₂ over other dopamine receptors, but also acts as α₂–adrenoceptor agonist and 5-HT₃ antagonist.

Partial agonists

• Aplindore
• Aripiprazole (Abilify in the US)^[14]
• Brexpiprazole/OPC-34712
• Cariprazine
• RP5063
• GSK-789,472 – Also D₃ antagonist, with good selectivity over other receptors ^[15]
• Ketamine (also NMDA antagonist)
• LSD – in vitro, LSD was found to be a partial agonist and potentiates dopamine-mediated prolactin secretion in lactotrophs.^[16] LSD is also a 5-HT_2A agonist.
• Modafinil
• Roxindole (only at the D₂ autoreceptors)
• OSU-6162 – Also 5-HT_2A partial agonist, acts as "dopamine stabilizer"
• Salvinorin A – Also κ-opioid agonist.

Antagonists

• Atypical antipsychotics
• Desmethoxyfallypride
• Domperidone – D₂ and D₃ antagonist; does not cross the blood-brain barrier
• Eticlopride
• Fallypride
• Hydroxyzine (Vistaril, Atarax)
• Itopride
• L-741,626 – highly selective D₂ antagonist
• C¹¹ Raclopride radiolabled – commonly employed in positron emission tomography studies^[17]
• Typical antipsychotics
• SV 293^[18]
• Yohimbine

D₂sh selective (presynaptic autoreceptors)

• Amisulpride (low doses)
• UH-232

Allosteric modulators

• Homocysteine – negative allosteric modulator^[19]
• PAOPA^[20]
• SB-269,652 ^[21][22][23]

Functionally selective ligands

• See reference^[24]

Protein-protein interactions

The dopamine receptor D₂ has been shown to interact with EPB41L1,^[25] PPP1R9B^[26] and NCS-1.^[27]

Receptor oligomers

The D₂ receptor forms receptor heterodimers in vivo (in living animals) with other G protein-coupled receptors; these include:^[28]

• D₁–D₂ dopamine receptor heteromer
• D₂–adenosine A_2A
• D₂–ghrelin receptor
• D_2sh–TAAR1^{[note 1]}

The D₂ receptor has been shown to form hetorodimers in vitro (and possibly in vivo) with DRD₃,^[31] DRD₅,^[32] and 5-HT_2A.^[33]

See also

• Dopamine receptor

Notes

1. D2sh–TAAR1 is a presynaptic heterodimer which involves the relocation of TAAR1 from the intracellular space to D2sh at the plasma membrane, increased D2sh agonist binding affinity, and signal transduction through the calcium–PKC–NFAT pathway and G-protein independent PKB–GSK3 pathway.^[29][30]

References

1. Madras BK. History of the discovery of the antipsychotic dopamine D2 receptor: a basis for the dopamine hypothesis of schizophrenia. Journal of the History of the Neurosciences. 2013, 22 (1): 62–78. PMID 23323533. doi:10.1080/0964704X.2012.678199. 
2. Usiello A, Baik JH, Rougé-Pont F, Picetti R, Dierich A, LeMeur M, Piazza PV, Borrelli E. Distinct functions of the two isoforms of dopamine D2 receptors. Nature. Nov 2000, 408 (6809): 199–203. PMID 11089973. doi:10.1038/35041572. 
3. Saab BJ, Georgiou J, Nath A, Lee FJ, Wang M, Michalon A, Liu F, Mansuy IM, Roder JC. NCS-1 in the dentate gyrus promotes exploration, synaptic plasticity, and rapid acquisition of spatial memory. Neuron. Sep 2009, 63 (5): 643–56. PMID 19755107. doi:10.1016/j.neuron.2009.08.014. 
4. Wiemerslage L, Schultz BJ, Ganguly A, Lee D. Selective degeneration of dopaminergic neurons by MPP(+) and its rescue by D2 autoreceptors in Drosophila primary culture. Journal of Neurochemistry. Aug 2013, 126 (4): 529–40. PMID 23452092. doi:10.1111/jnc.12228. 
5. Entrez Gene: DRD2 dopamine receptor D2. 
6. Beaulieu JM, Gainetdinov RR. The physiology, signaling, and pharmacology of dopamine receptors. Pharmacological Reviews. Mar 2011, 63 (1): 182–217. PMID 21303898. doi:10.1124/pr.110.002642. 
7. UniProt P14416
8. Duan J, Wainwright MS, Comeron JM, Saitou N, Sanders AR, Gelernter J, Gejman PV. Synonymous mutations in the human dopamine receptor D2 (DRD2) affect mRNA stability and synthesis of the receptor. Human Molecular Genetics. Feb 2003, 12 (3): 205–16. PMID 12554675. doi:10.1093/hmg/ddg055. 
9. Arinami T, Gao M, Hamaguchi H, Toru M. A functional polymorphism in the promoter region of the dopamine D2 receptor gene is associated with schizophrenia. Human Molecular Genetics. Apr 1997, 6 (4): 577–82. PMID 9097961. doi:10.1093/hmg/6.4.577. 
10. Glatt SJ, Faraone SV, Tsuang MT. DRD2 -141C insertion/deletion polymorphism is not associated with schizophrenia: results of a meta-analysis. American Journal of Medical Genetics. Part B, Neuropsychiatric Genetics. Jul 2004, 128B (1): 21–3. PMID 15211624. doi:10.1002/ajmg.b.30007. 
11. Lucht M, Rosskopf D. Comment on "Genetically determined differences in learning from errors". Science. Jul 2008, 321 (5886): 200; author reply 200. PMID 18621654. doi:10.1126/science.1155372. 
12. Wang J, Liu ZL, Chen B. Association study of dopamine D2, D3 receptor gene polymorphisms with motor fluctuations in PD. Neurology. Jun 2001, 56 (12): 1757–9. PMID 11425949. doi:10.1212/WNL.56.12.1757. 
13. Wang J, Zhao C, Chen B, Liu ZL. Polymorphisms of dopamine receptor and transporter genes and hallucinations in Parkinson's disease. Neuroscience Letters. Jan 2004, 355 (3): 193–6. PMID 14732464. doi:10.1016/j.neulet.2003.11.006. 
14. Clinical Pharmacology for Abilify. RxList.com. 2010-01-21 [2010-01-21]. 
15. Holmes IP, Blunt RJ, Lorthioir OE, Blowers SM, Gribble A, Payne AH, Stansfield IG, Wood M, Woollard PM, Reavill C, Howes CM, Micheli F, Di Fabio R, Donati D, Terreni S, Hamprecht D, Arista L, Worby A, Watson SP. The identification of a selective dopamine D2 partial agonist, D3 antagonist displaying high levels of brain exposure. Bioorganic & Medicinal Chemistry Letters. Mar 2010, 20 (6): 2013–6. PMID 20153647. doi:10.1016/j.bmcl.2010.01.090. 
16. Giacomelli S, Palmery M, Romanelli L, Cheng CY, Silvestrini B. Lysergic acid diethylamide (LSD) is a partial agonist of D2 dopaminergic receptors and it potentiates dopamine-mediated prolactin secretion in lactotrophs in vitro. Life Sciences. 1998, 63 (3): 215–22. PMID 9698051. doi:10.1016/S0024-3205(98)00262-8. 
17. Wang GJ, Volkow ND, Thanos PK, Fowler JS. Similarity between obesity and drug addiction as assessed by neurofunctional imaging: a concept review. Journal of Addictive Diseases. 2004, 23 (3): 39–53. PMID 15256343. doi:10.1300/J069v23n03_04. 
18. Huang R, Griffin SA, Taylor M, Vangveravong S, Mach RH, Dillon GH, Luedtke RR. The effect of SV 293, a D2 dopamine receptor-selective antagonist, on D2 receptor-mediated GIRK channel activation and adenylyl cyclase inhibition. Pharmacology. 2013, 92 (1–2): 84–9. PMID 23942137. doi:10.1159/000351971. 
19. Agnati LF, Ferré S, Genedani S, Leo G, Guidolin D, Filaferro M, Carriba P, Casadó V, Lluis C, Franco R, Woods AS, Fuxe K. Allosteric modulation of dopamine D2 receptors by homocysteine. Journal of Proteome Research. Nov 2006, 5 (11): 3077–83. PMID 17081059. doi:10.1021/pr0601382. 
20. Beyaert MG, Daya RP, Dyck BA, Johnson RL, Mishra RK. PAOPA, a potent dopamine D2 receptor allosteric modulator, prevents and reverses behavioral and biochemical abnormalities in an amphetamine–sensitized preclinical animal model of schizophrenia. European Neuropsychopharmacology. Mar 2013, 23 (3): 253–62. PMID 22658400. doi:10.1016/j.euroneuro.2012.04.010. 
21. Lane JR, Donthamsetti P, Shonberg J, Draper-Joyce CJ, Dentry S, Michino M, Shi L, López L, Scammells PJ, Capuano B, Sexton PM, Javitch JA, Christopoulos A. A new mechanism of allostery in a G protein–coupled receptor dimer. Nature Chemical Biology. Sep 2014, 10 (9): 745–52. PMID 25108820. doi:10.1038/nchembio.1593. 
22. Maggio R, Scarselli M, Capannolo M, Millan MJ. Novel dimensions of D3 receptor function: Focus on heterodimerisation, transactivation and allosteric modulation. European Neuropsychopharmacology. Sep 2015, 25 (9): 1470–9. PMID 25453482. doi:10.1016/j.euroneuro.2014.09.016. 
23. Silvano E, Millan MJ, Mannoury la Cour C, Han Y, Duan L, Griffin SA, Luedtke RR, Aloisi G, Rossi M, Zazzeroni F, Javitch JA, Maggio R. The tetrahydroisoquinoline derivative SB269,652 is an allosteric antagonist at dopamine D3 and D2 receptors. Molecular Pharmacology. Nov 2010, 78 (5): 925–34. PMC 2981362  . PMID 20702763. doi:10.1124/mol.110.065755. 
24. Möller D, Kling RC, Skultety M, Leuner K, Hübner H, Gmeiner P. Functionally selective dopamine D₂, D₃ receptor partial agonists. Journal of Medicinal Chemistry. Jun 2014, 57 (11): 4861–75. PMID 24831693. doi:10.1021/jm5004039. 
25. Binda AV, Kabbani N, Lin R, Levenson R. D2 and D3 dopamine receptor cell surface localization mediated by interaction with protein 4.1N. Molecular Pharmacology. Sep 2002, 62 (3): 507–13. PMID 12181426. doi:10.1124/mol.62.3.507. 
26. Smith FD, Oxford GS, Milgram SL. Association of the D2 dopamine receptor third cytoplasmic loop with spinophilin, a protein phosphatase-1-interacting protein. The Journal of Biological Chemistry. Jul 1999, 274 (28): 19894–900. PMID 10391935. doi:10.1074/jbc.274.28.19894. 
27. Kabbani N, Negyessy L, Lin R, Goldman-Rakic P, Levenson R. Interaction with neuronal calcium sensor NCS-1 mediates desensitization of the D2 dopamine receptor. The Journal of Neuroscience. Oct 2002, 22 (19): 8476–86. PMID 12351722. 
28. Beaulieu JM, Espinoza S, Gainetdinov RR. Dopamine receptors - IUPHAR Review 13. British Journal of Pharmacology. Jan 2015, 172 (1): 1–23. PMC 4280963  . PMID 25671228. doi:10.1111/bph.12906. 
29. Grandy DK, Miller GM, Li JX. "TAARgeting Addiction"-The Alamo Bears Witness to Another Revolution: An Overview of the Plenary Symposium of the 2015 Behavior, Biology and Chemistry Conference. Drug Alcohol Depend. February 2016, 159: 9–16. PMID 26644139. doi:10.1016/j.drugalcdep.2015.11.014. This original observation of TAAR1 and DA D2R interaction has subsequently been confirmed and expanded upon with observations that both receptors can heterodimerize with each other under certain conditions ... Additional DA D2R/TAAR1 interactions with functional consequences are revealed by the results of experiments demonstrating that in addition to the cAMP/PKA pathway (Panas et al., 2012) stimulation of TAAR1-mediated signaling is linked to activation of the Ca++/PKC/NFAT pathway (Panas et al.,2012) and the DA D2R-coupled, G protein-independent AKT/GSK3 signaling pathway (Espinoza et al., 2015; Harmeier et al., 2015), such that concurrent TAAR1 and DA DR2R activation could result in diminished signaling in one pathway (e.g. cAMP/PKA) but retention of signaling through another (e.g., Ca++/PKC/NFA) 
30. Harmeier A, Obermueller S, Meyer CA, Revel FG, Buchy D, Chaboz S, Dernick G, Wettstein JG, Iglesias A, Rolink A, Bettler B, Hoener MC. Trace amine-associated receptor 1 activation silences GSK3β signaling of TAAR1 and D2R heteromers. Eur Neuropsychopharmacol. 2015, 25 (11): 2049–61. PMID 26372541. doi:10.1016/j.euroneuro.2015.08.011. Interaction of TAAR1 with D2R altered the subcellular localization of TAAR1 and increased D2R agonist binding affinity. 
31. Maggio R, Millan MJ. Dopamine D2-D3 receptor heteromers: pharmacological properties and therapeutic significance. Current Opinion in Pharmacology. Feb 2010, 10 (1): 100–7. PMID 19896900. doi:10.1016/j.coph.2009.10.001. 
32. Hasbi A, O'Dowd BF, George SR. Heteromerization of dopamine D2 receptors with dopamine D1 or D5 receptors generates intracellular calcium signaling by different mechanisms. Current Opinion in Pharmacology. Feb 2010, 10 (1): 93–9. PMC 2818238  . PMID 19897420. doi:10.1016/j.coph.2009.09.011. 
33. Albizu L, Holloway T, González-Maeso J, Sealfon SC. Functional crosstalk and heteromerization of serotonin 5-HT2A and dopamine D2 receptors. Neuropharmacology. Sep 2011, 61 (4): 770–7. PMC 3556730  . PMID 21645528. doi:10.1016/j.neuropharm.2011.05.023. 

External links

• 醫學主題詞表（MeSH）：Receptors,+Dopamine+D2
• Pappas, Stephanie. Study: Genes Influence Who Your Friends Are. Imaginova Corp. LiveScience. [20 January 2011]. 

User:Panintelize/沙盒3引用了美国国家医学图书馆提供的資料，这些資料属于公共领域。

查 论 编 細胞表面受體：G蛋白偶联受体 类型A：类视紫红质受体 神经递质（英语：Neurotransmitter receptor） 肾上腺素 α1（英语：Alpha-1 adrenergic receptor） A B（英语：Alpha-1B adrenergic receptor） D（英语：Alpha-1D adrenergic receptor） α2（英语：Alpha-2 adrenergic receptor） A（英语：Alpha-2A adrenergic receptor） B（英语：Alpha-2B adrenergic receptor） C（英语：Alpha-2C adrenergic receptor） β1（英语：Beta-1 adrenergic receptor） β2（英语：Beta-2 adrenergic receptor） β3（英语：Beta-3 adrenergic receptor） 嘌呤 腺苷受體 A1 A2 A2A A2B A3 P2Y（英语：P2Y receptor） 1（英语：P2RY1） 2（英语：P2RY2） 4（英语：P2RY4） 5（英语：LPAR6） 6（英语：P2RY6） 8（英语：P2RY8） 9（英语：GPR23） 10（英语：P2RY10） 11（英语：P2RY11） 12（英语：P2Y12） 13（英语：P2RY13） 14（英语：P2RY14） 血清素 除5-HT3之外：5-HT1（英语：5-HT1 receptor） A B D E F 5-HT2 A B C 5-HT 4 5A 6 7 其它 乙酰胆碱 M1 M2 M3 M4 M5 多巴胺（英语：Dopamine receptor） D1 D2 D3 D4 D5 组胺（英语：Histamine receptor） H1 H2 H3 H4 褪黑素（英语：Melatonin receptor） 1A 1B 1C 痕量胺相关受体 1（英语：TAAR1） 2（英语：TAAR2） 3（英语：TAAR3） 5（英语：TAAR5） 6（英语：TAAR6） 8（英语：TAAR8） 9（英语：TAAR9） 代谢物及 信号分子 花生酸 半胱氨酰白三烯素 1 2 LTB4 1 2 FPRL1 酮基花生酸 前列腺素 D型 1 2 E型 1 2 3 4 FP 前列腺环素 血栓素 其它 胆汁酸 大麻碱 1 2 未命名 18（英语：GPR18） 55（英语：GPR55） 119（英语：GPR119） EB病毒诱导2（英语：GPR183） 雌激素（英语：GPR30） 游离脂肪酸 1 2 3 4 乳酸（英语：GPR81） 溶血磷脂酸 1 2 3 4 5 6 溶血磷脂受体 1（英语：S1PR1） 2 3（英语：S1PR3） 4 5（英语：S1PR2） 6（英语：S1PR4） 7 8（英语：S1PR5） 烟酸 1 2 酮戊二酸（英语：OXGR1） 血小板活化因子 鞘氨醇基-1-磷酸盐 1（英语：S1PR1） 2（英语：S1PR2） 3（英语：S1PR3） 4（英语：S1PR4） 5（英语：S1PR5） 琥珀酸（英语：SUCNR1） 肽 神经肽 B/W 1 2 FF 1 2 S Y 1 2 4 5 神经调节肽 B U 1 2 神经降压素 1 2 其它 过敏毒素（英语：Anaphylatoxin receptors） C3a C5a 血管紧张素 1 2 爱佩琳 铃蟾肽 BRS3 胃泌素释素 NMBR 缓激肽 B1 B2 趋化因子 胆囊收缩素 A B 内皮素 A B 甲酰肽 1 2 3 促卵泡激素 甘丙肽 1 2 3 γ-羟丁酸 促性腺激素释素 1 2 生长素 转移抑素 黄体生成素/绒毛膜促性腺激素 MAS 1（英语：MAS1） 1L（英语：MAS1L） D E F G X1 X2 X3 X4 黑素皮质素 1 2 3 4 5 黑色素浓集激素 1 2 胃动素 阿片 δ κ μ 痛敏肽 & ζ 注意不包括σ受体 丘脑分泌素 1 2 催产素 激动素 1 2 催乳素释放肽 松弛素 1 2 3 4 生长抑素 1 2 3 4 5 速激肽 1 2 3 促甲状腺激素 促甲状腺激素释放激素 尾加压素II 血管收缩素 1A 1B 2 杂项 孤儿受体 G蛋白耦合受体 1（英语：GPR1） 3（英语：GPR3） 4（英语：GPR4） 6（英语：GPR6） 12（英语：GPR12） 15（英语：GPR15） 17（英语：GPR17） 18（英语：GPR18） 19（英语：GPR19） 20（英语：GPR20） 21（英语：GPR21） 22（英语：GPR22） 23 25（英语：GPR25） 26（英语：GPR26） 27（英语：GPR27） 31（英语：GPR31） 32（英语：GPR32） 33（英语：GPR33） 34（英语：GPR34） 35（英语：GPR35） 37（英语：GPR37） 39（英语：GPR39） 42（英语：GPR42） 44（英语：GPR44） 45（英语：GPR45） 50（英语：GPR50） 52（英语：GPR52） 55（英语：GPR55） 61（英语：GPR61） 62（英语：GPR62） 63（英语：GPR63） 65（英语：GPR65） 68（英语：GPR68） 75（英语：GPR75） 77（英语：GPR77） 78（英语：GPR78） 81（英语：GPR81） 82（英语：GPR82） 83（英语：GPR83） 84（英语：GPR84） 85（英语：GPR85） 87（英语：GPR87） 88（英语：GPR88） 92 101（英语：GPR101） 103 109A 109B 119（英语：GPR119） 120（英语：GPR120） 132（英语：GPR132） 135（英语：GPR135） 137B（英语：GPR137B） 139（英语：GPR139） 141（英语：GPR141） 142（英语：GPR142） 146（英语：GPR146） 148（英语：GPR148） 149（英语：GPR149） 150（英语：GPR150） 151（英语：GPR151） 152（英语：GPR152） 153（英语：GPR153） 160（英语：GPR160） 161（英语：GPR161） 162（英语：GPR162） 171（英语：GPR171） 173（英语：GPR173） 174（英语：GPR174） 176（英语：GPR176） 177（英语：GPR177） 182（英语：GPR182） 183（英语：GPR183） 其它 肾上腺髓质素（英语：GPR182） 嗅觉 视蛋白 3 4 5 1长波 1中波 1短波 RGR 类视色素受体(周视蛋白) 蛋白酶激活（英语：[Protease-activated receptor]]） 1 2 3 4 大脑特异表达 类型B：类分泌素受体 孤儿受体 G蛋白耦合受体 56（英语：GPR56） 64（英语：GPR64） 97（英语：GPR97） 98（英语：GPR98） 110（英语：GPR110） 111（英语：GPR111） 112（英语：GPR112） 113（英语：GPR113） 114（英语：GPR114） 115（英语：GPR115） 116（英语：GPR116） 123（英语：GPR123） 124（英语：GPR124） 125（英语：GPR125） 126（英语：GPR126） 128（英语：GPR128） 133（英语：GPR133） 143（英语：GPR143） 144（英语：GPR144） 155（英语：GPR155） 157（英语：GPR157） 其它 脑血管生成抑制受体 1 2 3 钙粘蛋白 1 2 3 降钙素 降钙素受体类似受体 CD97（英语：CD97） 促肾上腺皮质激素释放激素 1 2 EMR 1 2 3 胰高血糖激素 胰高血糖激素 抑胃多肽 胰高血糖激素类肽1 胰高血糖激素类肽2 生长激素释放激素 PACAPR1 GPR 蛛毒素 1 2 3 表皮生长因子/蛛毒素/7跨膜域集合受体1 抗衰老类蛋白 甲状旁腺激素 1 2 促胰液素 血管活性肠肽 1 2 类型C（英语：Class C GPCR）：代谢型谷氨酸受体 ／信息素 味觉 TAS1R（甜味） 1（英语：TAS1R1） 2（英语：TAS1R2） 3（英语：TAS1R3） TAS2R（苦味） 1（英语：TAS2R1） 3（英语：TAS2R3） 4（英语：TAS2R4） 5（英语：TAS2R5） 8（英语：TAS2R8） 9（英语：TAS2R9） 10（英语：TAS2R10） 12（英语：TAS2R12） 13（英语：TAS2R13） 14 16 19 20 30 31 38 39 40 41 42 43 45 46 50 60 其它 钙敏感受体 γ-氨基丁酸B 1 2 谷氨酸受体 代谢型 1 2 3 4 5 6 7 8 G蛋白耦合受体C族6组A型 GPR 156（英语：GPR156） 158（英语：GPR158） 179（英语：GPR179） RAIG 1 2 3 4 类型F： 卷曲／平滑（英语：Smoothened）受体 卷曲 卷曲受体 1（英语：FZD1） 2（英语：FZD2） 3（英语：FZD3） 4（英语：FZD4） 5（英语：FZD5） 6（英语：FZD6） 7（英语：FZD7） 8（英语：FZD8） 9（英语：FZD9） 10（英语：FZD10） 平滑 平滑受体（英语：Smoothened）   信号转导索引 描述 胞外 神經肽 生长因子 细胞因子 激素 細胞表面受體（英语：Template:Cell surface receptors） 配体门控离子通道 酶联受體 G蛋白偶聯受體 免疫球蛋白超家族（英语：Template:Immunoglobulin superfamily immune receptors） 整合素 神經肽受體 生長因子受體 细胞因子受體 胞內 受體蛋白（英语：Template:Signal transducing adaptor proteins） GTP-binding（英语：Template:GTP-binding protein regulators） MAP激酶 鈣信號 脂質系號 路徑 hedgehog Wnt TGF-β MAPK ERK（英语：Template:MAPK ERK signaling pathway） notch（英语：Template:Notch signaling pathway） JAK-STAT 細胞凋亡 hippo（英语：Template:Hippo signaling pathway） TLR

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