Peters S J, Dyck D J, Bonen A, Spriet L L
Department of Human Biology and Nutritional Sciences, University of Guelph, Guelph, Ontario N1G 2W1, Canada.
Am J Physiol. 1998 Aug;275(2):E300-9. doi: 10.1152/ajpendo.1998.275.2.E300.
The effects of physiological (0, 0.1, 2.5, and 10 nM) and pharmacological (200 nM) epinephrine concentrations on resting skeletal muscle lipid metabolism were investigated with the use of incubated rat epitrochlearis (EPT), flexor digitorum brevis (FDB), and soleus (SOL) muscles. Muscles were chosen to reflect a range of oxidative capacities: SOL > EPT > FDB. The muscles were pulsed with [1-14C]palmitate and chased with [9,10-3H]palmitate. Incorporation and loss of the labeled palmitate from the triacylglycerol pool (as well as mono- and diacylglycerol, phospholipid, and fatty acid pools) permitted the simultaneous estimation of lipid hydrolysis and synthesis. Endogenous and exogenous fat oxidation was quantified by 14CO2 and 3H2O production, respectively. Triacylglycerol breakdown was elevated above control at all epinephrine concentrations in the oxidative SOL muscle, at 2.5 and 200 nM (at 10 nM, P = 0.066) in the FDB, and only at 200 nM epinephrine in the EPT. Epinephrine stimulated glycogen breakdown in the EPT at all concentrations but only at 10 and 200 nM in the FDB and had no effect in the SOL. We further characterized muscle lipid hydrolysis potential and measured total hormone-sensitive lipase content by Western blotting (SOL > FDB > EPT). This study demonstrated that physiological levels of epinephrine cause measurable increases in triacylglycerol hydrolysis at rest in oxidative but not in glycolytic muscle, with no change in the rate of lipid synthesis or oxidation. Furthermore, epinephrine caused differential stimulation of carbohydrate and fat metabolism in glycolytic vs. oxidative muscle. Epinephrine preferentially stimulated glycogen breakdown over triacylglycerol hydrolysis in the glycolytic EPT muscle. Conversely, in the oxidative SOL muscle, epinephrine caused an increase in endogenous lipid hydrolysis over glycogen breakdown.
利用孵育的大鼠肱三头肌(EPT)、趾短屈肌(FDB)和比目鱼肌(SOL),研究了生理浓度(0、0.1、2.5和10 nM)和药理浓度(200 nM)的肾上腺素对静息骨骼肌脂质代谢的影响。选择这些肌肉以反映一系列氧化能力:SOL>EPT>FDB。用[1-14C]棕榈酸脉冲处理肌肉,并用[9,10-3H]棕榈酸进行追踪。标记的棕榈酸从三酰甘油池(以及单酰甘油、二酰甘油、磷脂和脂肪酸池)中的掺入和损失允许同时估计脂质水解和合成。内源性和外源性脂肪氧化分别通过14CO2和3H2O的产生进行定量。在氧化型SOL肌肉中,所有肾上腺素浓度下三酰甘油分解均高于对照,在FDB中为2.5和200 nM(在10 nM时,P = 0.066),而在EPT中仅在200 nM肾上腺素时升高。肾上腺素在所有浓度下均刺激EPT中的糖原分解,但仅在FDB中为10和200 nM时刺激,对SOL无影响。我们进一步表征了肌肉脂质水解潜力,并通过蛋白质免疫印迹法测量了总激素敏感性脂肪酶含量(SOL>FDB>EPT)。这项研究表明,生理水平的肾上腺素在静息时会导致氧化型而非糖酵解型肌肉中三酰甘油水解有可测量的增加,脂质合成或氧化速率没有变化。此外,肾上腺素在糖酵解型与氧化型肌肉中对碳水化合物和脂肪代谢有不同的刺激作用。在糖酵解型EPT肌肉中,肾上腺素优先刺激糖原分解而非三酰甘油水解。相反,在氧化型SOL肌肉中,肾上腺素导致内源性脂质水解增加而非糖原分解增加。
