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MC4R 的信号转导功能存在显性负效应,这是由其第三跨膜区的杂合性突变引起的。

A heterozygous mutation in the third transmembrane domain causes a dominant-negative effect on signalling capability of the MC4R.

机构信息

Department of Pediatric Endocrinology, Charité, Campus Virchow-Klinikum - Universitatsmedizin Berlin, Berlin, Germany.

出版信息

Obes Facts. 2008;1(3):155-62. doi: 10.1159/000138251. Epub 2008 Jun 20.

DOI:10.1159/000138251
PMID:20054175
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6452123/
Abstract

BACKGROUND

Heterozygous MC4R mutation is the most frequent cause of monogenic obesity. For most MC4R mutations a gene dosage effect seems to be the underlying mechanism. However, a dominant negative effect of a heterozygous MC4R mutation was recently identified, pointing to an additional mechanism of MC4R inactivation.

METHODS

The complete loss-of-function mutation (Ser136Phe), identified in a cohort of obese Austrian patients, was characterized for cell surface expression, signal transduction and ligand binding properties. Co-transfection studies tested for a dominant negative effect. Dimerization was investigated by a sandwich ELISA and by fluorescence resonance energy transfer (FRET) approach. Potential intramolecular interactions of Ser136 were studied by homologous receptor modelling based on the crystal structure of the beta2-adrenergic receptor.

RESULTS

The Ser136Phe mutation showed a dominant negative effect. The sandwich ELISA and FRET approach demonstrated dimerization of mutant and wild type receptor. Receptor modelling revealed an essential function of Ser136 at transmembrane helix 3 (TMH3) for establishing H-bonds between TMH2, TMH3, and TMH7. The mutation Ser136Phe most likely disrupts this network and leads to an incompetent helix-helix arrangement in the mutated receptor.

CONCLUSION

Identification of dominant negative MC4R mutations is important to fully understand receptor function and to determine receptor regions that are involved in MC4R dimer activation.

摘要

背景

杂合子 MC4R 突变是单基因肥胖的最常见原因。对于大多数 MC4R 突变,基因剂量效应似乎是其潜在机制。然而,最近发现杂合子 MC4R 突变具有显性负效应,这表明 MC4R 失活存在另一种机制。

方法

在奥地利肥胖患者队列中发现的完全丧失功能的突变(Ser136Phe),对其细胞表面表达、信号转导和配体结合特性进行了特征描述。共转染研究测试了显性负效应。夹心 ELISA 和荧光共振能量转移(FRET)方法研究了二聚化。基于β2-肾上腺素能受体的晶体结构,通过同源受体建模研究了 Ser136 的潜在分子内相互作用。

结果

Ser136Phe 突变显示出显性负效应。夹心 ELISA 和 FRET 方法证明了突变和野生型受体的二聚化。受体建模表明,Ser136 在跨膜螺旋 3(TMH3)处对于在 TMH2、TMH3 和 TMH7 之间建立氢键具有重要功能。Ser136Phe 突变很可能破坏了这个网络,导致突变受体中无能的螺旋-螺旋排列。

结论

鉴定显性负 MC4R 突变对于充分理解受体功能以及确定参与 MC4R 二聚体激活的受体区域非常重要。

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