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. Copyright 2008 S. Karger AG, Basel.
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. Copyright 2008 S. Karger AG, Basel.
Authors: Johanna Giuranna; Anna-Lena Volckmar; Anna Heinen; Triinu Peters; Börge Schmidt; Anne Spieker; Helena Straub; Harald Grallert; Timo D Müller; Jochen Antel; Ute Haußmann; Hans Klafki; Liangyou Rui; Johannes Hebebrand; Anke Hinney Journal: Obes Facts Date: 2018-04-10 Impact factor: 3.942
Authors: Christian L Roth; Michael Ludwig; Joachim Woelfle; Zhen-Chuan Fan; Harald Brumm; Heike Biebermann; Ya-Xiong Tao Journal: Endocrine Date: 2009-02-12 Impact factor: 3.633
Authors: Jörg D Wichard; Antonius Ter Laak; Gerd Krause; Nikolaus Heinrich; Ronald Kühne; Gunnar Kleinau Journal: PLoS One Date: 2011-02-04 Impact factor: 3.240