Sadahiro Masato, Erickson Connor, Lin Wei-Jye, Shin Andrew C, Razzoli Maria, Jiang Cheng, Fargali Samira, Gurney Allison, Kelley Kevin A, Buettner Christoph, Bartolomucci Alessandro, Salton Stephen R
Departments of Neuroscience (M.S., W.-J.L., C.J., S.F., C.B., S.R.S.), Medicine (A.C.S., C.B.), Geriatrics (S.R.S.), and Developmental and Regenerative Biology (K.A.K.), Friedman Brain Institute (S.R.S.), and Graduate School of Biomedical Sciences (M.S., C.J.), Icahn School of Medicine at Mount Sinai, New York, New York 10029-6574; and Department of Integrative Biology and Physiology (C.E., M.R., A.G., A.B.), University of Minnesota, Minneapolis, Minnesota 55455-0001.
Endocrinology. 2015 May;156(5):1724-38. doi: 10.1210/en.2014-1826. Epub 2015 Feb 12.
Targeted deletion of VGF, a secreted neuronal and endocrine peptide precursor, produces lean, hypermetabolic, and infertile mice that are resistant to diet-, lesion-, and genetically-induced obesity and diabetes. Previous studies suggest that VGF controls energy expenditure (EE), fat storage, and lipolysis, whereas VGF C-terminal peptides also regulate reproductive behavior and glucose homeostasis. To assess the functional equivalence of human VGF(1-615) (hVGF) and mouse VGF(1-617) (mVGF), and to elucidate the function of the VGF C-terminal region in the regulation of energy balance and susceptibility to obesity, we generated humanized VGF knockin mouse models expressing full-length hVGF or a C-terminally deleted human VGF(1-524) (hSNP), encoded by a single nucleotide polymorphism (rs35400704). We show that homozygous male and female hVGF and hSNP mice are fertile. hVGF female mice had significantly increased body weight compared with wild-type mice, whereas hSNP mice have reduced adiposity, increased activity- and nonactivity-related EE, and improved glucose tolerance, indicating that VGF C-terminal peptides are not required for reproductive function, but 1 or more specific VGF C-terminal peptides are likely to be critical regulators of EE. Taken together, our results suggest that human and mouse VGF proteins are largely functionally conserved but that species-specific differences in VGF peptide function, perhaps a result of known differences in receptor binding affinity, likely alter the metabolic phenotype of hVGF compared with mVGF mice, and in hSNP mice in which several C-terminal VGF peptides are ablated, result in significantly increased activity- and nonactivity-related EE.
VGF是一种分泌型神经元和内分泌肽前体,对其进行靶向缺失会产生体型消瘦、代谢亢进且不育的小鼠,这些小鼠对饮食、损伤和基因诱导的肥胖及糖尿病具有抗性。先前的研究表明,VGF控制能量消耗(EE)、脂肪储存和脂肪分解,而VGF C末端肽也调节生殖行为和葡萄糖稳态。为了评估人VGF(1 - 615)(hVGF)和小鼠VGF(1 - 617)(mVGF)的功能等效性,并阐明VGF C末端区域在能量平衡调节和肥胖易感性中的作用,我们构建了人源化VGF基因敲入小鼠模型,该模型表达全长hVGF或由单核苷酸多态性(rs35400704)编码的C末端缺失的人VGF(1 - 524)(hSNP)。我们发现,纯合的雄性和雌性hVGF和hSNP小鼠具有生育能力。与野生型小鼠相比,hVGF雌性小鼠体重显著增加,而hSNP小鼠脂肪量减少、与活动和非活动相关的EE增加且葡萄糖耐量改善,这表明VGF C末端肽对生殖功能不是必需的,但1种或更多种特定的VGF C末端肽可能是EE的关键调节因子。综上所述,我们的结果表明人和小鼠的VGF蛋白在很大程度上功能保守,但VGF肽功能的物种特异性差异,可能是受体结合亲和力已知差异的结果,与mVGF小鼠相比可能改变hVGF的代谢表型,并且在几种C末端VGF肽被切除的hSNP小鼠中,导致与活动和非活动相关的EE显著增加。
