“新生”肝脂肪激活过氧化物酶体增殖物激活受体α（PPARα）以维持葡萄糖、脂质和胆固醇的稳态。

"New" hepatic fat activates PPARalpha to maintain glucose, lipid, and cholesterol homeostasis.

作者信息

Chakravarthy Manu V, Pan Zhijun, Zhu Yimin, Tordjman Karen, Schneider Jochen G, Coleman Trey, Turk John, Semenkovich Clay F

机构信息

Endocrinology, Metabolism, and Lipid Research, Department of Medicine, Washington University School of Medicine, St. Louis, Missouri 63110, USA.

出版信息

Cell Metab. 2005 May;1(5):309-22. doi: 10.1016/j.cmet.2005.04.002.

DOI:10.1016/j.cmet.2005.04.002

PMID:16054078

Abstract

De novo lipogenesis is an energy-expensive process whose role in adult mammals is poorly understood. We generated mice with liver-specific inactivation of fatty-acid synthase (FAS), a key lipogenic enzyme. On a zero-fat diet, FASKOL (FAS knockout in liver) mice developed hypoglycemia and fatty liver, which were reversed with dietary fat. These phenotypes were also observed after prolonged fasting, similarly to fasted PPARalpha-deficiency mice. Hypoglycemia, fatty liver, and defects in expression of PPARalpha target genes in FASKOL mice were corrected with a PPARalpha agonist. On either zero-fat or chow diet, FASKOL mice had low serum and hepatic cholesterol levels with elevated SREBP-2, decreased HMG-CoA reductase expression, and decreased cholesterol biosynthesis; these were also corrected with a PPARalpha agonist. These results suggest that products of the FAS reaction regulate glucose, lipid, and cholesterol metabolism by serving as endogenous activators of distinct physiological pools of PPARalpha in adult liver.

摘要

从头脂肪生成是一个消耗能量的过程，其在成年哺乳动物中的作用尚不清楚。我们构建了脂肪酸合酶（FAS，一种关键的脂肪生成酶）肝脏特异性失活的小鼠。在零脂肪饮食条件下，FASKOL（肝脏中FAS基因敲除）小鼠出现低血糖和脂肪肝，而饮食中的脂肪可使其逆转。长时间禁食后也观察到了这些表型，这与禁食的PPARα缺陷小鼠类似。FASKOL小鼠的低血糖、脂肪肝以及PPARα靶基因表达缺陷可通过PPARα激动剂得到纠正。无论在零脂肪饮食还是普通饮食条件下，FASKOL小鼠的血清和肝脏胆固醇水平都较低，同时SREBP-2升高、HMG-CoA还原酶表达降低以及胆固醇生物合成减少；这些也可通过PPARα激动剂得到纠正。这些结果表明，FAS反应的产物通过作为成年肝脏中不同生理池的PPARα的内源性激活剂来调节葡萄糖、脂质和胆固醇代谢。

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“新生”肝脂肪激活过氧化物酶体增殖物激活受体α（PPARα）以维持葡萄糖、脂质和胆固醇的稳态。

"New" hepatic fat activates PPARalpha to maintain glucose, lipid, and cholesterol homeostasis.

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