Pharmacological chaperone action in humanized mouse models of MC4R-linked obesity
Patricia René, Damien Lanfray, Denis Richard, Michel Bouvier
Patricia René, Damien Lanfray, Denis Richard, Michel Bouvier
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Resource and Technical Advance Metabolism Therapeutics

Pharmacological chaperone action in humanized mouse models of MC4R-linked obesity

Abstract

MC4R mutations represent the largest monogenic cause of obesity, resulting mainly from receptor misfolding and intracellular retention by the cellular quality control system. The present study aimed at determining whether pharmacological chaperones (PCs) that restore folding and plasma membrane trafficking by stabilizing near native protein conformation may represent valid therapeutic avenues for the treatment of melanocortin type 4 receptor–linked (MC4R-linked) obesity. To test the therapeutic PC potential, we engineered humanized MC4R (hMC4R) mouse models expressing either the WT human MC4R or a prevalent obesity-causing mutant (R165W). Administration of a PC able to rescue cell surface expression and functional activity of R165W-hMC4R in cells restored the anorexigenic response of the R165W-hMC4R obese mice to melanocortin agonist, providing a proof of principle for the therapeutic potential of MC4R-targeting PCs in vivo. Interestingly, the expression of the WT-hMC4R in mice revealed lower sensitivity of the human receptor to α–melanocyte-stimulating hormone (α-MSH) but not β-MSH or melanotan II, resulting in a lower penetrance obese phenotype in the WT-hMC4R versus R165W-hMC4R mice. In conclusion, we created 2 new obesity models, a hypomorphic highlighting species differences and an amorphic providing a preclinical model to test the therapeutic potential of PCs to treat MC4R-linked obesity.

Authors

Patricia René, Damien Lanfray, Denis Richard, Michel Bouvier

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Figure 1

Humanized KI mouse expression and functionality.

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Humanized KI mouse expression and functionality. (A–C) Immunohistochemic...
(AC) Immunohistochemical labeling of MC4R-positive neurons. Brain sections of the paraventricular nucleus (PVN) of the hypothalamus, the medial preoptic area (MPOA), the medial amygdala (MeA), or the mesencephalic periaqueductal gray (PAG) from nontransgenic (NTG), heterozygous (HET), or homozygous (HOMO) hMC4R-KI and homozygous loxTB MC4R-null mice (as indicated) were labeled with anti-GFP antibody (A) or with anti-MC4R antibody (B and C), C being a higher magnification of the PVN and MPOA for the NTG, WT and R165W-hMC4R mice. Inset in A: higher power magnification of boxed areas containing GFP immune reactive neurons (brown cytoplasmic reaction product). Arrows in the center and right insets indicate GFP-positive neurons. Scale bars: 100 μm (A), 50 μm (A, inset), 2 cm (B) and 10 μm (C). (D) MTII response in mouse models. MTII (1 nmol) was intracerebroventricularly (icv) injected in 16- to 22-week-old nontransgenic (NTG) and homozygous (HOMO) hMC4R-KI (WT or mutant [R165W]) or loxTB MC4R-null mice. Food intake was measured 4 hours postadministration in dark phase and reported in percentage. Data were analyzed using the Wilcoxon’s matched pairs test for loxTB MC4R null (NTG = 9, P = 0.0078, HOMO = 10), WT-hMC4R (NTG = 9, P = 0.0078; HOMO = 10, P = 0.0020), and R165W-hMC4R (NTG = 7, P = 0.0156; HOMO = 6). **P < 0.001.