Succinate receptor in GtoPdb v.2023.1

IUPHAR/BPS Guide to Pharmacology CITE Pub Date : 2023-04-26 DOI:10.2218/gtopdb/f446/2023.1

Anthony P. Davenport, Julien Hanson, Wen Chiy Liew

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Abstract

Nomenclature as recommended by NC-IUPHAR [8]. The succinate receptor (GPR91, SUCNR1) is activated by the tricarboxylic acid (or Krebs) cycle intermediate succinate and other dicarboxylic acids with less clear physiological relevance such as maleate [17]. Since its pairing with its endogenous ligand in 2004, intense research has focused on the receptor-ligand pair role in various (patho)physiological processes such as regulation of renin production [17, 39], ischemia injury [17], fibrosis [25], retinal angiogenesis [34], inflammation [25, 23], immune response [32], obesity [44, 26, 21], diabetes [42, 22, 39], platelet aggregation [38, 36] or cancer [28, 46]. The succinate receptor is coupled to Gi/o [11, 17] and Gq/11 protein families [31, 17, 40]. Although the receptor is, upon ligand addition, rapidly desensitized [19, 31], and in some cells internalized [17], it seems to recruit arrestins weakly [10]. The cellular activation of the succinate receptor triggers various signalling pathways such as decrease of cAMP levels, [Ca2+]i mobilization and activation of kinases (ERK, c-Jun, Akt, Src, p38, PI3Kβ, etc.) [12]. The receptor is broadly expressed but is notably abundant in immune cells (M2 macrophages [40, 21], monocytes [32], immature dendritic cells [32], adipocytes [44], platelets [38, 36], etc.) and in the kidney [17].

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琥珀酸受体在GtoPdb v.2023.1

NC-IUPHAR推荐的命名法[8]。琥珀酸受体(GPR91, SUCNR1)被三羧酸(或Krebs)循环中间体琥珀酸和其他生理相关性不太明确的二羧酸(如雄酸)激活[17]。自2004年与其内源性配体配对以来，人们对受体-配体对在各种(病理)生理过程中的作用进行了大量研究，如肾素产生的调节[17,39]、缺血损伤[17]、纤维化[25]、视网膜血管生成[34]、炎症[25,23]、免疫反应[32]、肥胖[44,26,21]、糖尿病[42,22,39]、血小板聚集[38,36]或癌症[28,46]。琥珀酸受体偶联到Gi/o蛋白家族[11,17]和Gq/11蛋白家族[31,17,40]。虽然在配体加入后，受体会迅速脱敏[19,31]，并且在一些内化的细胞中[17]，但它似乎招募阻滞因子的能力较弱[10]。琥珀酸受体的细胞活化触发多种信号通路，如cAMP水平降低、[Ca2+]i动员和激酶(ERK、c-Jun、Akt、Src、p38、PI3Kβ等)的激活[12]。该受体广泛表达，但在免疫细胞(M2巨噬细胞[40,21]、单核细胞[32]、未成熟树突状细胞[32]、脂肪细胞[44]、血小板[38,36]等)和肾脏中表达丰富[17]。

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