Mild activation of the mitochondrial unfolded protein response increases lifespan without increasing resistance to stress

Alexa Di Pede, Bokang Ko, Abdelrahman AlOkda, Aura A. Tamez Gonzalez, Jeremy M. Van Raamsdonk
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Abstract

The mitochondrial unfolded protein response (mitoUPR) is a stress response pathway that responds to mitochondrial insults by altering gene expression to recover mitochondrial homeostasis. The mitoUPR is mediated by the stress-activated transcription factor ATFS-1. Constitutive activation of ATFS-1 increases resistance to exogenous stressors but paradoxically decreases lifespan. In this work, we determined the optimal levels of expression of activated ATFS-1 with respect to lifespan and resistance to stress by treating constitutively-active atfs-1(et17) worms with different concentrations of RNA interference (RNAi) bacteria targeting atfs-1. We observed the maximum lifespan of atfs-1(et17) worms at full-strength atfs-1 RNAi, which was significantly longer than wild-type lifespan. Under the conditions of maximum lifespan, atfs-1(et17) worms did not show enhanced resistance to stress, suggesting a trade-off between stress resistance and longevity. The maximum resistance to stress in atfs-1(et17) worms occurred on empty vector (0% atfs-1 knockdown). Under these conditions, atfs-1(et17) worms are short-lived. This indicates that constitutive activation of ATFS-1 can increase lifespan or enhance resistance to stress but not both, at the same time. Finally, we determined the timing requirements for ATFS-1 to affect lifespan. We found that knocking down atfs-1 expression only during development is sufficient to extend atfs-1(et17) lifespan, while adult-only knockdown has no effect. Overall, these results demonstrate that constitutively active ATFS-1 can extend lifespan when expressed at low levels and that this lifespan extension is not dependent on the ability of ATFS-1 to enhance resistance to stress.
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轻度激活线粒体未折叠蛋白反应会延长寿命,但不会增强对压力的抵抗力
线粒体未折叠蛋白反应(mitoUPR)是一种应激反应途径,它通过改变基因表达来应对线粒体损伤,从而恢复线粒体的平衡。mitoUPR 由应激激活转录因子 ATFS-1 介导。ATFS-1 的持续激活可增强对外源应激源的抵抗力,但矛盾的是会缩短寿命。在这项工作中,我们用不同浓度的靶向atfs-1的RNA干扰(RNAi)细菌处理组成型活性atfs-1(et17)蠕虫,确定了活化的ATFS-1在寿命和抗应激方面的最佳表达水平。我们观察到,在全强度atfs-1 RNAi条件下,atfs-1(et17)蠕虫的最大寿命明显长于野生型。在最大寿命条件下,atfs-1(et17)蠕虫并没有表现出更强的抗应激能力,这表明抗应激能力和寿命之间存在权衡。在空载体(atfs-1基因敲除率为0%)条件下,atfs-1(et17)蠕虫的抗应激能力最强。在这些条件下,atfs-1(et17)蠕虫的寿命很短。这表明 ATFS-1 的组成性激活可以延长寿命或提高抗逆性,但不能同时提高寿命和抗逆性。最后,我们确定了 ATFS-1 影响寿命的时间要求。我们发现,只在发育过程中敲除atfs-1的表达足以延长atfs-1(et17)的寿命,而只在成年期敲除则没有影响。总之,这些结果表明,组成型活性 ATFS-1 在低水平表达时可以延长寿命,而且这种寿命延长并不依赖于 ATFS-1 增强抗应激能力的能力。
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