David R Powell, Deon D Doree, Melanie K Shadoan, Kenneth A Platt, Robert Brommage, Peter Vogel, Jean-Pierre Revelli
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引用次数: 0
Abstract
Genes regulating body fat are shared with high fidelity by mice and humans, indicating that mouse knockout (KO) phenotyping might identify valuable antiobesity drug targets. Male Mrs2 magnesium transporter (Mrs2) KO mice were recently reported as thin when fed a high-fat diet (HFD). They also exhibited increased energy expenditure (EE)/body weight and had beiged adipocytes that, along with isolated hepatocytes, demonstrated increased oxygen consumption, suggesting that increased EE drove the thin phenotype. Here we provide our data on these and additional assays in Mrs2 KO mice. We generated Mrs2 KO mice by homologous recombination. HFD-fed male and female Mrs2 KO mice had significantly less body fat, measured by quantitative magnetic resonance, than wild-type (WT) littermates. HFD-fed Mrs2 KO mice did not demonstrate increased EE by indirect calorimetry and could not maintain body temperature at 4 °C, consistent with their decreased brown adipose tissue stores but despite increased beige white adipose tissue. Instead, when provided a choice between HFD and low-fat diet (LFD), Mrs2 KO mice showed a significant 15% decrease in total energy intake resulting from significantly lower HFD intake that offset numerically increased LFD intake. Food restriction studies performed using WT mice suggested that this decrease in energy intake could explain the loss of body fat. Oral glucose tolerance test studies revealed significantly improved insulin sensitivity in Mrs2 KO mice. We conclude that HFD-fed Mrs2 KO mice are thin with improved insulin sensitivity, and that this favorable metabolic phenotype is driven by hypophagia. Further evaluation is warranted to determine the suitability of MRS2 as a drug target for antiobesity therapeutics.
小鼠和人类高度共享调节体脂的基因,这表明小鼠基因敲除(KO)表型可能会发现有价值的抗肥胖药物靶点。最近有报道称,雄性 Mrs2 镁转运体(Mrs2)KO 小鼠在喂食高脂饮食(HFD)时很瘦。它们还表现出能量消耗(EE)/体重增加,脂肪细胞呈米字形,与离体肝细胞一起显示出耗氧量增加,这表明能量消耗的增加驱动了瘦弱表型。在此,我们提供了在 Mrs2 KO 小鼠中进行的这些试验和其他试验的数据。我们通过同源重组产生了 Mrs2 KO 小鼠。与 WT 小鼠相比,通过 QMR 测量,以 HFD 饲喂的雌雄 Mrs2 KO 小鼠的体脂明显较少。通过间接热量计测量,以高密度脂蛋白喂养的 Mrs2 KO 小鼠的 EE 并未增加,而且无法将体温维持在 4 摄氏度,这与它们的 BAT 储存量减少但米色 WAT 增加是一致的。相反,当在高脂饮食(HFD)和低脂饮食(LFD)之间进行选择时,Mrs2 KO 小鼠的总能量摄入量显著减少了 15%,这是因为高脂饮食摄入量的显著降低抵消了低脂饮食摄入量的增加。使用 WT 小鼠进行的食物限制研究表明,能量摄入的减少可以解释体脂的减少。OGTT 研究表明,Mrs2 KO 小鼠的胰岛素敏感性明显提高。我们的结论是,以高密度脂蛋白饲料喂养的 Mrs2 KO 小鼠身材消瘦,胰岛素敏感性提高,而这种有利的代谢表型是由低食欲驱动的。我们需要进一步评估,以确定 MRS2 是否适合作为抗肥胖疗法的药物靶点。
期刊介绍:
The mission of Endocrinology is to be the authoritative source of emerging hormone science and to disseminate that new knowledge to scientists, clinicians, and the public in a way that will enable "hormone science to health." Endocrinology welcomes the submission of original research investigating endocrine systems and diseases at all levels of biological organization, incorporating molecular mechanistic studies, such as hormone-receptor interactions, in all areas of endocrinology, as well as cross-disciplinary and integrative studies. The editors of Endocrinology encourage the submission of research in emerging areas not traditionally recognized as endocrinology or metabolism in addition to the following traditionally recognized fields: Adrenal; Bone Health and Osteoporosis; Cardiovascular Endocrinology; Diabetes; Endocrine-Disrupting Chemicals; Endocrine Neoplasia and Cancer; Growth; Neuroendocrinology; Nuclear Receptors and Their Ligands; Obesity; Reproductive Endocrinology; Signaling Pathways; and Thyroid.
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