de Lange Pieter, Moreno Maria, Silvestri Elena, Lombardi Assunta, Goglia Fernando, Lanni Antonia
Dipartimento di Scienze della Vita, Seconda Università degli Studi di Napoli, Via Vivaldi 43, 81100 Caserta, Italy.
FASEB J. 2007 Nov;21(13):3431-41. doi: 10.1096/fj.07-8527rev. Epub 2007 Jun 26.
Energy deprivation poses a tremendous challenge to skeletal muscle. Glucose (ATP) depletion causes muscle fibers to undergo rapid adaptive changes toward the use of fatty acids (instead of glucose) as fuel. Physiological situations involving energy deprivation in skeletal muscle include exercise and fasting. A vast body of evidence is available on the signaling pathways that lead to structural/metabolic changes in muscle during exercise and endurance training. In contrast, only recently has a systematic, overall picture been obtained of the signaling processes (and their kinetics and sequential order) that lead to adaptations of the muscle to the fasting state. It has become clear that the reaction of the organism to food restraint or deprivation involves a rapid signaling process causing skeletal muscles, which generally use glucose as their predominant fuel, to switch to the use of fat as fuel. Efficient sensing of glucose depletion in skeletal muscle guarantees maintained activity in those tissues that rely entirely on glucose (such as the brain). To metabolize fatty acids, skeletal muscle needs to activate complex transcription, translation, and phosphorylation pathways. Only recently has it become clear that these pathways are interrelated and tightly regulated in a rapid, transient manner. Food deprivation may trigger these responses with a timing/intensity that differs among animal species and that may depend on their individual ability to induce structural/metabolic changes that serve to safeguard whole-body energy homeostasis in the longer term. The increased cellular AMP/ATP ratio induced by food deprivation, which results in activation of AMP-activated protein kinase (AMPK), initiates a rapid signaling process, resulting in the recruitment of factors mediating the structural/metabolic shift in skeletal muscle toward this change in fuel usage. These factors include peroxisome proliferator-activated receptor (PPAR)gamma coactivator-1alpha (PGC-1alpha), PPARdelta, and their target genes, which are involved in the formation of oxidative muscle fibers, mitochondrial biogenesis, oxidative phosphorylation, and fatty acid oxidation. Fatty acids, besides being the fuel for mitochondrial oxidation, have been identified as important signaling molecules regulating the transcription and/or activity of the genes or gene products involved in fatty acid metabolism during food deprivation. It is thus becoming increasingly clear that fatty acids determine the economy of their own usage. We discuss the order of events from the onset of food deprivation and their importance.
能量剥夺对骨骼肌构成了巨大挑战。葡萄糖(ATP)耗竭会使肌纤维迅速发生适应性变化,转而利用脂肪酸(而非葡萄糖)作为燃料。涉及骨骼肌能量剥夺的生理状况包括运动和禁食。关于运动和耐力训练期间导致肌肉结构/代谢变化的信号通路,已有大量证据。相比之下,直到最近才获得了关于导致肌肉适应禁食状态的信号传导过程(及其动力学和顺序)的系统、全面图景。已经清楚的是,生物体对食物限制或剥夺的反应涉及一个快速的信号传导过程,使通常以葡萄糖为主要燃料的骨骼肌转而使用脂肪作为燃料。骨骼肌中葡萄糖耗竭的有效感知确保了那些完全依赖葡萄糖的组织(如大脑)的持续活动。为了代谢脂肪酸,骨骼肌需要激活复杂的转录、翻译和磷酸化途径。直到最近才清楚这些途径是相互关联的,并以快速、短暂的方式受到严格调控。食物剥夺可能以不同动物物种不同的时间/强度触发这些反应,这可能取决于它们诱导结构/代谢变化的个体能力,这些变化有助于在长期内维持全身能量稳态。食物剥夺引起的细胞内AMP/ATP比值增加,导致AMP激活的蛋白激酶(AMPK)激活,启动一个快速的信号传导过程,导致介导骨骼肌结构/代谢向这种燃料使用变化转变的因子的募集。这些因子包括过氧化物酶体增殖物激活受体(PPAR)γ共激活因子-1α(PGC-1α)、PPARδ及其靶基因,它们参与氧化肌纤维的形成、线粒体生物发生、氧化磷酸化和脂肪酸氧化。脂肪酸除了作为线粒体氧化的燃料外,还被确定为在食物剥夺期间调节参与脂肪酸代谢的基因或基因产物的转录和/或活性的重要信号分子。因此,越来越清楚的是,脂肪酸决定了它们自身使用的经济性。我们讨论了从食物剥夺开始的一系列事件及其重要性。
