Department of Science and Technologies, University of Sannio, Benevento, Italy.
Department of Biology, Federico II University, Naples, Italy.
Front Endocrinol (Lausanne). 2021 Mar 4;12:631176. doi: 10.3389/fendo.2021.631176. eCollection 2021.
Refeeding after caloric restriction induces weight regain and a disproportionate recovering of fat mass rather than lean mass (catch-up fat) that, in humans, associates with higher risks to develop chronic dysmetabolism. Studies in a well-established rat model of semistarvation-refeeding have reported that catch-up fat associates with hyperinsulinemia, glucose redistribution from skeletal muscle to white adipose tissue and suppressed adaptive thermogenesis sustaining a high efficiency for fat deposition. The skeletal muscle of catch-up fat animals exhibits reduced insulin-stimulated glucose utilization, mitochondrial dysfunction, delayed contraction-relaxation kinetics, increased proportion of slow fibers and altered local thyroid hormone metabolism, with suggestions of a role for iodothyronine deiodinases. To obtain novel insights into the skeletal muscle response during catch-up fat in this rat model, the functional proteomes of tibialis anterior and soleus muscles, harvested after 2 weeks of caloric restriction and 1 week of refeeding, were studied. Furthermore, to assess the implication of thyroid hormone metabolism in catch-up fat, circulatory thyroid hormones as well as liver type 1 (D1) and liver and skeletal muscle type 3 (D3) iodothyronine deiodinase activities were evaluated. The proteomic profiling of both skeletal muscles indicated catch-up fat-induced alterations, reflecting metabolic and contractile adjustments in soleus muscle and changes in glucose utilization and oxidative stress in tibialis anterior muscle. In response to caloric restriction, D3 activity increased in both liver and skeletal muscle, and persisted only in skeletal muscle upon refeeding. In parallel, liver D1 activity decreased during caloric restriction, and persisted during catch-up fat at a time-point when circulating levels of T4, T3 and rT3 were all restored to those of controls. Thus, during catch-up fat, a local hypothyroidism may occur in liver and skeletal muscle despite systemic euthyroidism. The resulting reduced tissue thyroid hormone bioavailability, likely D1- and D3-dependent in liver and skeletal muscle, respectively, may be part of the adaptive thermogenesis sustaining catch-up fat. These results open new perspectives in understanding the metabolic processes associated with the high efficiency of body fat recovery after caloric restriction, revealing new implications for iodothyronine deiodinases as putative biological brakes contributing in suppressed thermogenesis driving catch-up fat during weight regain.
热量限制后再喂养会导致体重反弹和脂肪量不成比例地恢复,而不是瘦体重(追赶性脂肪),在人类中,这与发生慢性代谢功能障碍的风险增加有关。在半饥饿-再喂养的已建立的大鼠模型中进行的研究报告称,追赶性脂肪与高胰岛素血症、骨骼肌葡萄糖向白色脂肪组织重新分布以及适应性产热受抑制有关,从而维持脂肪沉积的高效率。追赶性脂肪动物的骨骼肌表现出胰岛素刺激的葡萄糖利用减少、线粒体功能障碍、收缩-松弛动力学延迟、慢肌纤维比例增加以及局部甲状腺激素代谢改变,并提示碘甲状腺原氨酸脱碘酶起作用。为了在这种大鼠模型中获得关于追赶性脂肪期间骨骼肌反应的新见解,研究了在热量限制 2 周和再喂养 1 周后收获的比目鱼肌和跖肌的功能蛋白质组。此外,为了评估甲状腺激素代谢在追赶性脂肪中的作用,评估了循环甲状腺激素以及肝脏 1 型(D1)和肝脏和骨骼肌 3 型(D3)碘甲状腺原氨酸脱碘酶的活性。两种骨骼肌的蛋白质组学分析表明,追赶性脂肪引起的改变反映了跖肌的代谢和收缩调整,以及比目鱼肌葡萄糖利用和氧化应激的变化。对热量限制的反应,D3 活性在肝脏和骨骼肌中均增加,并且仅在再喂养时在骨骼肌中持续存在。同时,在热量限制期间,D1 活性在肝脏中降低,并且在追赶性脂肪期间持续存在,此时 T4、T3 和 rT3 的循环水平均恢复到对照组的水平。因此,尽管系统甲状腺功能正常,但在追赶性脂肪期间,肝脏和骨骼肌可能会发生局部甲状腺功能减退症。由此产生的组织甲状腺激素生物利用度降低,可能分别取决于肝脏和骨骼肌中的 D1 和 D3,可能是维持追赶性脂肪的适应性产热的一部分。这些结果为理解与热量限制后体脂肪恢复效率高相关的代谢过程开辟了新的视角,揭示了碘甲状腺原氨酸脱碘酶作为潜在的生物刹车的新意义,这些刹车有助于抑制产热,推动体重恢复期间的追赶性脂肪。
