Premature senescence is regulated by crosstalk among TFEB, the autophagy lysosomal pathway and ROS derived from damaged mitochondria in NaAsO₂-exposed auditory cells.

IF 7 2区生物学 Q1 CELL BIOLOGY Cell Death Discovery Pub Date : 2024-08-28 DOI:10.1038/s41420-024-02139-4

Yuna Suzuki, Ken Hayashi, Fumiyuki Goto, Yasuyuki Nomura, Chisato Fujimoto, Makoto Makishima

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Abstract

Age-related hearing loss (ARHL) is one of the most prevalent types of sensory decline in a superaging society. Although various studies have focused on the effect of oxidative stress on the inner ear as an inducer of ARHL, there are no effective preventive approaches for ARHL. Recent studies have suggested that oxidative stress-induced DNA damage responses (oxidative DDRs) drive cochlear cell senescence and contribute to accelerated ARHL, and autophagy could function as a defense mechanism against cellular senescence in auditory cells. However, the underlying mechanism remains unclear. Sodium arsenite (NaAsO₂) is a unique oxidative stress inducer associated with reactive oxygen species (ROS) that causes high-tone hearing loss similar to ARHL. Transcription factor EB (TFEB) functions as a master regulator of the autophagy‒lysosome pathway (ALP), which is a potential target during aging and the pathogenesis of various age-related diseases. Here, we focused on the function of TFEB and the impact of intracellular ROS as a potential target for ARHL treatment in a NaAsO₂-induced auditory premature senescence model. Our results suggested that short exposure to NaAsO₂ leads to DNA damage, lysosomal damage and mitochondrial damage in auditory cells, triggering temporary signals for TFEB transport into the nucleus and, as a result, causing insufficient autophagic flux and declines in lysosomal function and biogenesis and mitochondrial quality. Then, intracellular ROS derived from damaged mitochondria play a role as a second messenger to induce premature senescence in auditory cells. These findings suggest that TFEB activation via transport into the nucleus contributes to anti-senescence activity in auditory cells and represents a new therapeutic target for ARHL. We have revealed the potential function of TFEB as a master regulator of the induction of oxidative stress-induced premature senescence and the senescence-associated secretion phenotype (SASP) in auditory cells, which regulates ALP and controls mitochondrial quality through ROS production.

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在NaAsO2暴露的听觉细胞中，早衰受TFEB、自噬溶酶体途径和来自受损线粒体的ROS之间的串扰调控。

老年性听力损失（ARHL）是超老龄化社会中最普遍的感官衰退类型之一。虽然各种研究都关注氧化应激对内耳的影响，认为氧化应激是 ARHL 的诱因，但目前还没有有效的 ARHL 预防方法。最近的研究表明，氧化应激诱导的DNA损伤反应（氧化DDRs）驱动耳蜗细胞衰老，并导致ARHL加速，而自噬可作为听觉细胞衰老的防御机制。然而，其基本机制仍不清楚。亚砷酸钠（NaAsO2）是一种独特的氧化应激诱导剂，与活性氧（ROS）有关，可导致类似于ARHL的高音听力损失。转录因子 EB（TFEB）是自噬-溶酶体途径（ALP）的主调节因子，是衰老和各种老年相关疾病发病机制的潜在靶标。在这里，我们重点研究了在NaAsO2诱导的听觉早衰模型中TFEB的功能以及细胞内ROS作为ARHL治疗潜在靶点的影响。我们的研究结果表明，短时间暴露于NaAsO2会导致听觉细胞DNA损伤、溶酶体损伤和线粒体损伤，触发TFEB转运到细胞核的临时信号，从而导致自噬通量不足、溶酶体功能和生物发生以及线粒体质量下降。然后，来自受损线粒体的细胞内 ROS 作为第二信使发挥作用，诱导听觉细胞过早衰老。这些研究结果表明，TFEB 通过转运到细胞核而被激活，有助于听觉细胞的抗衰老活性，是治疗 ARHL 的新靶点。我们揭示了 TFEB 作为诱导氧化应激诱导的听觉细胞过早衰老和衰老相关分泌表型（SASP）的主调节因子的潜在功能，它通过 ROS 的产生调节 ALP 和控制线粒体质量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Cell Death Discovery Biochemistry, Genetics and Molecular Biology-Cell Biology

CiteScore

8.30

自引率

1.40%

发文量

468

审稿时长

9 weeks

期刊介绍： Cell Death Discovery is a multidisciplinary, international, online-only, open access journal, dedicated to publishing research at the intersection of medicine with biochemistry, pharmacology, immunology, cell biology and cell death, provided it is scientifically sound. The unrestricted access to research findings in Cell Death Discovery will foster a dynamic and highly productive dialogue between basic scientists and clinicians, as well as researchers in industry with a focus on cancer, neurobiology and inflammation research. As an official journal of the Cell Death Differentiation Association (ADMC), Cell Death Discovery will build upon the success of Cell Death & Differentiation and Cell Death & Disease in publishing important peer-reviewed original research, timely reviews and editorial commentary. Cell Death Discovery is committed to increasing the reproducibility of research. To this end, in conjunction with its sister journals Cell Death & Differentiation and Cell Death & Disease, Cell Death Discovery provides a unique forum for scientists as well as clinicians and members of the pharmaceutical and biotechnical industry. It is committed to the rapid publication of high quality original papers that relate to these subjects, together with topical, usually solicited, reviews, editorial correspondence and occasional commentaries on controversial and scientifically informative issues.