β1-肾上腺素能受体 N-末端单核苷酸变体的 O-糖基化改变可调节受体的加工和功能活性。

Hanna E Tuhkanen, Ilona J Haasiomäki, Jarkko J Lackman, Christoffer K Goth, S Orvokki Mattila, Zilu Ye, Sergey Y Vakhrushev, Johanna Magga, Risto Kerkelä, Henrik Clausen, Katrine T Schjoldager, Ulla E Petäjä-Repo
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引用次数: 0

摘要

G 蛋白偶联受体(GPCRs)的 N 端非同义单核苷酸多态性(SNPs)很常见,通常会影响受体的翻译后修饰。然而,它们的功能影响在很大程度上还不为人所知。我们之前已经证明,人类 β1 肾上腺素能受体(β1AR)的 N 端细胞外结构域是由多肽 GalNAc 转移酶-2 进行 O 型糖基化的,而多肽 GalNAc 转移酶-2 能共同调节受体的蛋白水解。在这里,我们证明常见的 S49G 以及罕见的 A29T 和 R31Q SNPs 会改变这些修饰,从而对受体加工产生不同的影响。这是通过体外 O 型糖基化实验、原生受体 N 端 O 型糖基化肽分析以及在细胞系和缺乏 O 型糖基化的新生大鼠心室心肌细胞中表达受体变体来实现的。这些 SNP 消除(S49G)或引入(A29T)了调节性 O-糖基化,分别增强或抑制了相邻位点(P52↓L53 和 R31↓L32)的裂解,或取消了 R31↓L32 的主要位点(R31Q)。T29 和 Q31 变体的蛋白水解抑制与细胞表面全长受体水平的增加有关。此外,在增强的旁观者生物发光能量转移β-arrestin2招募试验中,S49变体与共同的C端R389G多态性以协调的方式显示出异丙肾上腺素介导的信号转导增加。由于第 49 位的 Gly 是胎盘哺乳动物的祖先,研究结果表明,它与 Ser 的交换在人类中产生了 β1AR 功能增益表型。这项研究为调控机制提供了证据,在调控配体结合和激活的经典结构域之外的 GPCR SNP 可改变受体的加工和功能。因此,有必要对其他具有临床意义的 GPCR SNPs 作为药物靶点进行进一步研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Altered O-glycosylation of β1-adrenergic receptor N-terminal single-nucleotide variants modulates receptor processing and functional activity.

N-terminal nonsynonymous single-nucleotide polymorphisms (SNPs) of G protein-coupled receptors (GPCRs) are common and often affect receptor post-translational modifications. Their functional implications are, however, largely unknown. We have previously shown that the human β1-adrenergic receptor (β1AR) is O-glycosylated in the N-terminal extracellular domain by polypeptide GalNAc transferase-2 that co-regulates receptor proteolytic cleavage. Here, we demonstrate that the common S49G and the rare A29T and R31Q SNPs alter these modifications, leading to distinct effects on receptor processing. This was achieved by in vitro O-glycosylation assays, analysis of native receptor N-terminal O-glycopeptides, and expression of receptor variants in cell lines and neonatal rat ventricular cardiomyocytes deficient in O-glycosylation. The SNPs eliminated (S49G) or introduced (A29T) regulatory O-glycosites that enhanced or inhibited cleavage at the adjacent sites (P52↓L53 and R31↓L32), respectively, or abolished the major site at R31↓L32 (R31Q). The inhibition of proteolysis of the T29 and Q31 variants correlated with increased full-length receptor levels at the cell surface. Furthermore, the S49 variant showed increased isoproterenol-mediated signaling in an enhanced bystander bioluminescence energy transfer β-arrestin2 recruitment assay in a coordinated manner with the common C-terminal R389G polymorphism. As Gly at position 49 is ancestral in placental mammals, the results suggest that its exchange to Ser has created a β1AR gain-of-function phenotype in humans. This study provides evidence for regulatory mechanisms by which GPCR SNPs outside canonical domains that govern ligand binding and activation can alter receptor processing and function. Further studies on other GPCR SNPs with clinical importance as drug targets are thus warranted.

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