MESH1-mediated coenzyme A degradation drives ferroptosis sensitivity and muscle pathology
Chao-Chieh Lin, Joshua Rose, Alexander A. Mestre, Chien-Kung Cornelia Ding, Ssu-Yu Chen, Sze Mun Choy, Kah Yong Goh, Weiyi Jiang, Wen Xing Lee, Qizhou Jiang, Yanting Chen, Tianai Sun, Jianli Wu, Yueqi Chen, Yunju Oh, Pyeonghwa Jeong, Jiyong Hong, Kenon Chua, Michael C. Fitzgerald, Guo-Fang Zhang, Hong-Wen Tang, Pei Zhou, Jen-Tsan Chi
Chao-Chieh Lin, Joshua Rose, Alexander A. Mestre, Chien-Kung Cornelia Ding, Ssu-Yu Chen, Sze Mun Choy, Kah Yong Goh, Weiyi Jiang, Wen Xing Lee, Qizhou Jiang, Yanting Chen, Tianai Sun, Jianli Wu, Yueqi Chen, Yunju Oh, Pyeonghwa Jeong, Jiyong Hong, Kenon Chua, Michael C. Fitzgerald, Guo-Fang Zhang, Hong-Wen Tang, Pei Zhou, Jen-Tsan Chi
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Research Article Cell biology Muscle biology

MESH1-mediated coenzyme A degradation drives ferroptosis sensitivity and muscle pathology

Abstract

CoA facilitates fatty acid synthesis, energy production, gene regulation, and antioxidant function. While CoA biosynthesis is well characterized, the mechanisms governing CoA degradation remain poorly understood. Here, we identify the Metazoan Homolog of SpoT, MESH1, as a CoA phosphatase that dephosphorylates CoA at the 3′ position of the ribose ring to form dephospho-CoA. Recent studies have shown that CoA, similar to glutathione, is a cysteine-derived metabolite that protects cells against ferroptosis. Ferroptosis induced by blocking cystine import depletes CoA biosynthesis, while CoA restoration rescues cells from ferroptosis. We found that MESH1 knockdown preserved CoA levels by preventing its degradation, contributing to ferroptosis protection, indicating the bifunctional role of MESH1 in regulating CoA and previously reported NADPH. Mechanistically, MESH1 knockdown elevates CoA levels, maintaining a functional mitochondrial thioredoxin system, thereby preventing mitochondrial lipid peroxidation. In Drosophila, we found that dMesh1 overexpression leads to ferroptosis-mediated muscle atrophy, which can be rescued by increasing CoA and NADPH levels. Taken together, these findings establish MESH1 as a key phosphatase that governs ferroptosis sensitivity by coordinating CoA and NADPH homeostasis, unveiling a link between CoA degradation, mitochondrial integrity, and muscle health.

Authors

Chao-Chieh Lin, Joshua Rose, Alexander A. Mestre, Chien-Kung Cornelia Ding, Ssu-Yu Chen, Sze Mun Choy, Kah Yong Goh, Weiyi Jiang, Wen Xing Lee, Qizhou Jiang, Yanting Chen, Tianai Sun, Jianli Wu, Yueqi Chen, Yunju Oh, Pyeonghwa Jeong, Jiyong Hong, Kenon Chua, Michael C. Fitzgerald, Guo-Fang Zhang, Hong-Wen Tang, Pei Zhou, Jen-Tsan Chi

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Figure 4

Muscle defects induced by MESH1 overexpression in Drosophila were rescued by liproxstatin-1 treatment or by enhancing CoA or NADPH synthesis.

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Muscle defects induced by MESH1 overexpression in Drosophila were rescue...
Overexpression of Mesh1 in skeletal muscles resulted in an open wing phenotype (A), climbing defects (B), muscle shrinkage (C and D), reduced and clustered nuclei with altered nuclear localization (E and F), and increased mitochondrial ROS levels (G and H). These defects were rescued by liproxstatin-1 or pantethine treatment or by overexpression of DPCK or Nadk1b. Scale bars: 20 μm (E and G); original magnification, ×4 (C). (B, D, F, and H) One-way ANOVA, Tukey’s multiple comparisons, n = 6 independent biological replicates.