Anthony J R Hickey, Alice R Harford, Pierre U Blier, Jules B Devaux
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Importantly, substantial decreases in ATP synthesis occur at temperatures immediately below the temperature of heart failure, and this suggests a causal role of mitochondria in hyperthermic death. However, what causes mitochondria to fail? Here, we consider the answers to this question. Mitochondrial dysfunction at high temperature has classically been attributed to elevated leak respiration suspected to result from increased movement of protons (H+) through the inner mitochondrial membrane (IMM), thereby bypassing the ATP synthases. In this Commentary, we introduce some alternative explanations for elevated leak respiration. We first consider respiratory complex I and then propose that a loss of IMM structure occurs as temperatures rise. The loss of the cristae folds of the IMM may affect the efficiency of H+ transport, increasing H+ conductance either through the IMM or into the bulk water phases of mitochondria. 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引用次数: 0
摘要
尽管在临界温度下发生高热死亡的机理仍未确定,但关键的活跃兴奋组织(如心脏和大脑)的线粒体很可能是这一过程的关键。线粒体产生细胞维持完整性和功能所需的 90% 的 ATP。线粒体还与生物合成途径相结合,支持整体新陈代谢,在细胞内进行交流,并调节细胞的健康和死亡途径。我们以前的研究表明,随着温度的升高,心脏和大脑线粒体合成 ATP 的效率和绝对能力都会下降,最终导致 ATP 不足以支持细胞需求,器官随之衰竭。重要的是,ATP 合成的大量减少发生在温度低于心力衰竭温度的时候,这表明线粒体在高热死亡中起着因果作用。然而,是什么导致线粒体失效?在此,我们将探讨这一问题的答案。线粒体在高温下的功能障碍通常被归因于泄漏呼吸的升高,怀疑是由于质子(H+)通过线粒体内膜(IMM)的运动增加,从而绕过了 ATP 合成酶。在本评论中,我们将介绍泄漏呼吸升高的一些替代解释。我们首先考虑了呼吸复合体 I,然后提出随着温度升高,线粒体内膜结构会发生损失。线粒体膜嵴褶的损失可能会影响 H+ 的运输效率,增加通过线粒体膜或进入线粒体大体水相的 H+ 传导。无论是哪种情况,O2 的消耗都会增加,而 ATP 的合成则会减少。
What causes cardiac mitochondrial failure at high environmental temperatures?
Although a mechanism accounting for hyperthermic death at critical temperatures remains elusive, the mitochondria of crucial active excitable tissues (i.e. heart and brain) may well be key to this process. Mitochondria produce ∼90% of the ATP required by cells to maintain cellular integrity and function. They also integrate into biosynthetic pathways that support metabolism as a whole, allow communication within the cell, and regulate cellular health and death pathways. We have previously shown that cardiac and brain mitochondria demonstrate decreases in the efficiency of, and absolute capacity for ATP synthesis as temperatures rise, until ultimately there is too little ATP to support cellular demands, and organ failure follows. Importantly, substantial decreases in ATP synthesis occur at temperatures immediately below the temperature of heart failure, and this suggests a causal role of mitochondria in hyperthermic death. However, what causes mitochondria to fail? Here, we consider the answers to this question. Mitochondrial dysfunction at high temperature has classically been attributed to elevated leak respiration suspected to result from increased movement of protons (H+) through the inner mitochondrial membrane (IMM), thereby bypassing the ATP synthases. In this Commentary, we introduce some alternative explanations for elevated leak respiration. We first consider respiratory complex I and then propose that a loss of IMM structure occurs as temperatures rise. The loss of the cristae folds of the IMM may affect the efficiency of H+ transport, increasing H+ conductance either through the IMM or into the bulk water phases of mitochondria. In either case, O2 consumption increases while ATP synthesis decreases.
期刊介绍:
Journal of Experimental Biology is the leading primary research journal in comparative physiology and publishes papers on the form and function of living organisms at all levels of biological organisation, from the molecular and subcellular to the integrated whole animal.