Department of Health Sciences, Area of Physiology, University of Jaen, Jaen, Spain.
Department of Health Sciences, Universidad Loyola Andalucía, Sevilla, Spain.
J Physiol. 2024 Nov;602(21):5631-5641. doi: 10.1113/JP285516. Epub 2024 Apr 17.
In eukaryotic cells, aerobic energy is produced by mitochondria through oxygen uptake. However, little is known about the early mitochondrial responses to moderate hypobaric hypoxia (MHH) in highly metabolic active tissues. Here, we describe the mitochondrial responses to acute MHH in the heart and skeletal muscle. Rats were randomly allocated into a normoxia control group (n = 10) and a hypoxia group (n = 30), divided into three groups (0, 6, and 24 h post-MHH). The normoxia situation was recapitulated at the University of Granada, at 662 m above sea level. The MHH situation was performed at the High-Performance Altitude Training Centre of Sierra Nevada located in Granada at 2320 m above sea level. We found a significant increase in mitochondrial supercomplex assembly in the heart as soon as the animals reached 2320 m above sea level and their levels are maintained 24 h post-exposure, but not in skeletal muscle. Furthermore, in skeletal muscle, at 0 and 6 h, there was increased dynamin-related protein 1 (Drp1) expression and a significant reduction in Mitofusin 2. In conclusion, mitochondria from the muscle and heart respond differently to MHH: mitochondrial supercomplexes increase in the heart, whereas, in skeletal muscle, the mitochondrial pro-fission response is trigged. Considering that skeletal muscle was not actively involved in the ascent when the heart was beating faster to compensate for the hypobaric, hypoxic conditions, we speculate that the different responses to MHH are a result of the different energetic requirements of the tissues upon MHH. KEY POINTS: The heart and the skeletal muscle showed different mitochondrial responses to moderate hypobaric hypoxia. Moderate hypobaric hypoxia increases the assembly of the electron transport chain complexes into supercomplexes in the heart. Skeletal muscle shows an early mitochondrial pro-fission response following exposure to moderate hypobaric hypoxia.
在真核细胞中,通过摄取氧气,线粒体通过有氧代谢产生能量。然而,对于高度代谢活跃的组织中,中度低压缺氧(MHH)对线粒体的早期反应知之甚少。在这里,我们描述了心脏和骨骼肌对急性 MHH 的线粒体反应。大鼠被随机分配到常氧对照组(n=10)和缺氧组(n=30),分为三组(MHH 后 0、6 和 24 小时)。常氧情况在格拉纳达大学(海拔 662 米)重现。MHH 情况在位于格拉纳达海拔 2320 米的内华达山脉高性能高原训练中心进行。我们发现,动物一到达海拔 2320 米以上,心脏中线粒体超级复合物的组装就显著增加,并且在暴露后 24 小时仍保持不变,但在骨骼肌中没有。此外,在骨骼肌中,在 0 和 6 小时时,动力相关蛋白 1(Drp1)的表达增加,而 Mitofusin 2 的表达显著减少。总之,肌肉和心脏的线粒体对 MHH 的反应不同:心脏中线粒体超级复合物增加,而骨骼肌中线粒体的分裂反应被触发。考虑到当心脏跳动更快以补偿低压、缺氧条件时,骨骼肌并没有主动参与上升,我们推测,不同的组织对 MHH 的不同反应是由于组织对 MHH 的不同能量需求所致。关键点:心脏和骨骼肌对中度低压缺氧表现出不同的线粒体反应。中度低压缺氧增加了心脏中线粒体电子传递链复合物形成超级复合物的组装。暴露于中度低压缺氧后,骨骼肌早期出现线粒体分裂反应。
