Tanaka Kosuke, Masaki Yuko, Tanaka Masatake, Miyazaki Masayuki, Enjoji Munechika, Nakamuta Makoto, Kato Masaki, Nomura Masatoshi, Inoguchi Toyoshi, Kotoh Kazuhiro, Takayanagi Ryoichi
Kosuke Tanaka, Yuko Masaki, Masatake Tanaka, Masayuki Miyazaki, Masaki Kato, Masatoshi Nomura, Kazuhiro Kotoh, Ryoichi Takayanagi, Department of Medicine and Bioregulatory Science, Graduate School of Medical Sciences, Kyushu University, Fukuoka 812-8582, Japan.
World J Gastroenterol. 2014 Mar 14;20(10):2653-63. doi: 10.3748/wjg.v20.i10.2653.
To investigate the metabolic changes in skeletal muscle and/or adipose tissue in glucagon-like peptide-1-induced improvement of nonalcoholic fatty liver disease (NAFLD).
Male Wistar rats were fed either a control diet (control group) or a high-fat diet (HFD). After 4 wk, the HFD-fed rats were subdivided into two groups; one group was injected with exenatide [HFD-Ex(+) group] and the other with saline [HFD-Ex(-) group] every day for 12 wk. The control group received saline and were fed a control diet. Changes in weight gain, energy intake, and oxygen consumption were analyzed. Glucose tolerance tests were performed after 8 wk of treatment. Histological assessments were performed in liver and adipose tissue. RNA expression levels of lipid metabolism related genes were evaluated in liver, skeletal muscle, and adipose tissue.
Exenatide attenuated weight gain [HFD-Ex(-) vs HFD-Ex(+)] and reduced energy intake, which was accompanied by an increase in oxygen consumption and a decrease in the respiratory exchange ratio [HFD-Ex(-) vs HFD-Ex(+)]. However, exenatide did not affect glucose tolerance. Exenatide reduced lipid content in the liver and adipose tissue. Exenatide did not affect the expression of lipid metabolism-related genes in the liver or skeletal muscle. In adipose tissue, exenatide significantly upregulated lipolytic genes, including hormone-sensitive lipase, carnitine palmitoyltransferase-1, long-chain acyl-CoA dehydrogenase, and acyl-CoA oxidase 1 [HFD-Ex(-) vs HFD-Ex(+)]. Exenatide also upregulated catalase and superoxide dismutase 2 [HFD-Ex(-) vs HFD-Ex(+)].
In addition to reducing appetite, enhanced lipid use by exenatide in adipose tissue may reduce hepatic lipid content in NAFLD, most likely by decreasing lipid influx into the liver.
研究胰高血糖素样肽-1诱导非酒精性脂肪性肝病(NAFLD)改善过程中骨骼肌和/或脂肪组织的代谢变化。
雄性Wistar大鼠分别喂食对照饮食(对照组)或高脂饮食(HFD)。4周后,将喂食HFD的大鼠分为两组;一组每天注射艾塞那肽[HFD-Ex(+)组],另一组每天注射生理盐水[HFD-Ex(-)组],持续12周。对照组注射生理盐水并喂食对照饮食。分析体重增加、能量摄入和耗氧量的变化。治疗8周后进行葡萄糖耐量试验。对肝脏和脂肪组织进行组织学评估。评估肝脏、骨骼肌和脂肪组织中脂质代谢相关基因的RNA表达水平。
艾塞那肽减轻了体重增加[HFD-Ex(-)组与HFD-Ex(+)组相比],并减少了能量摄入,同时伴有耗氧量增加和呼吸交换率降低[HFD-Ex(-)组与HFD-Ex(+)组相比]。然而,艾塞那肽不影响葡萄糖耐量。艾塞那肽降低了肝脏和脂肪组织中的脂质含量。艾塞那肽不影响肝脏或骨骼肌中脂质代谢相关基因的表达。在脂肪组织中,艾塞那肽显著上调了脂解基因,包括激素敏感性脂肪酶、肉碱棕榈酰转移酶-1、长链酰基辅酶A脱氢酶和酰基辅酶A氧化酶1[HFD-Ex(-)组与HFD-Ex(+)组相比]。艾塞那肽还上调了过氧化氢酶和超氧化物歧化酶2[HFD-Ex(-)组与HFD-Ex(+)组相比]。
除了降低食欲外,艾塞那肽增强脂肪组织中脂质的利用可能通过减少脂质流入肝脏来降低NAFLD患者肝脏中的脂质含量。
