Tianai Sun scite author profile

S tringent response is the main strategy used by bacteria to cope with fluctuating nutrient supplies and metabolic and oxidative stresses 1,2 . This process rapidly redirects energy from cell proliferation toward stress survival by reduction of biosynthesis, conservation of ATP and blockage of GTP production 3 . The stringent response is triggered by the accumulation of the bacterial 'alarmone' (p)ppGpp (guanosine tetra-or penta-phosphate, shortened as ppGpp below) through the regulation of ppGpp synthetases and hydrolases in the RelA and SpoT homologue family 2 .Recent studies suggest that the stringent response may also function in metazoans, as metazoan genomes encode a homologue of bacterial SpoT-MESH1 (Metazoan SpoT Homologue 1, encoded by HDDC3)-that can hydrolyse ppGpp in vitro and functionally complement SpoT in Escherichia coli 4 . Furthermore, Mesh1 deletion in Drosophila displays impaired starvation resistance and extensive transcriptional reprogramming 4 . Despite these supporting lines of evidence, neither ppGpp nor its synthetase has been discovered in metazoans, thus obscuring the genuine function and the relevant substrate(s) of MESH1 in mammalian cells. Here, we have identified NADPH as an efficient substrate of MESH1. MESH1 is a cytosolic NADPH phosphatase that is induced under stress conditions, leading to the NADPH depletion and ferroptosis-a novel form of iron-dependent regulated cell death characterized by lipid peroxidation 5 . Accordingly, MESH1 removal preserves the NADPH level in stressed cells and promotes their ferroptotic survival.Critical to the bacterial stringent response is the rapid relocation of resources from proliferation toward stress survival through the respective accumulation and degradation of (p)ppGpp by RelA and SpoT homologues. While mammalian genomes encode MESH1, a homologue of the bacterial (p)ppGpp hydrolase SpoT, neither (p)ppGpp nor its synthetase has been identified in mammalian cells. Here, we show that human MESH1 is an efficient cytosolic NADPH phosphatase that facilitates ferroptosis. Visualization of the MESH1-NADPH crystal structure revealed a bona fide affinity for the NADPH substrate. Ferroptosisinducing erastin or cystine deprivation elevates MESH1, whose overexpression depletes NADPH and sensitizes cells to ferroptosis, whereas MESH1 depletion promotes ferroptosis survival by sustaining the levels of NADPH and GSH and by reducing lipid peroxidation. The ferroptotic protection by MESH1 depletion is ablated by suppression of the cytosolic NAD(H) kinase, NADK, but not its mitochondrial counterpart NADK2. Collectively, these data shed light on the importance of cytosolic NADPH levels and their regulation under ferroptosis-inducing conditions in mammalian cells.

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The Hippo Pathway Effector TAZ Regulates Ferroptosis in Renal Cell Carcinoma

Yang

Ding

Sun

et al. 2019

SSRN Journal

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Regulation of ferroptosis in cancer cells by YAP/TAZ and Hippo pathways: The therapeutic implications

Sun

Chi

2021

Genes & Diseases

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Ferroptosis is a novel form of iron-dependent cell death characterized by lipid peroxidation. While the importance and disease relevance of ferroptosis is gaining recognition, much remains unknown about various genetic and non-genetic determinants of ferroptosis. Hippo signaling pathway is an evolutionarily conserved pathway that responds to various environmental cues and controls organ size, cell proliferation, death, and self-renewal capacity. In cancer biology, Hippo pathway is a potent tumor suppressing mechanism and its dysregulation contributes to apoptosis evasion, cancer development, metastasis, and treatment resistance. Hippo dysregulation leads to aberrant activation of YAP and TAZ, the two major transcription co-activators of TEADs, that induce the expression of genes triggering tumor-promoting phenotypes, including enhanced cell proliferation, self-renewal and apoptosis inhibition. The Hippo pathway is regulated by the cell-cell contact and cellular density/confluence. Recently, ferroptosis has also been found being regulated by the cellular contact and density. The YAP/TAZ activation under low density, while confers apoptosis resistance, renders cancer cells sensitivity to ferroptosis. These findings establish YAP/TAZ and Hippo pathways as novel determinants of ferroptosis. Therefore, inducing ferroptosis may have therapeutic potential for YAP/TAZ-activated chemo-resistant and metastatic tumor cells. Reciprocally, various YAP/TAZ-targeting treatments under clinical development may confer ferroptosis resistance, limiting the therapeutic efficacy.

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The regulation of ferroptosis by MESH1 through the activation of the integrative stress response

et al. 2021

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All organisms exposed to metabolic and environmental stresses have developed various stress adaptive strategies to maintain homeostasis. The main bacterial stress survival mechanism is the stringent response triggered by the accumulation “alarmone” (p)ppGpp, whose level is regulated by RelA and SpoT. While metazoan genomes encode MESH1 (Metazoan SpoT Homolog 1) with ppGpp hydrolase activity, neither ppGpp nor the stringent response is found in metazoa. The deletion of Mesh1 in Drosophila triggers a transcriptional response reminiscent of the bacterial stringent response. However, the function of MESH1 remains unknown until our recent discovery of MESH1 as the first cytosolic NADPH phosphatase that regulates ferroptosis. To further understand whether MESH1 knockdown triggers a similar transcriptional response in mammalian cells, here, we employed RNA-Seq to analyze the transcriptome response to MESH1 knockdown in human cancer cells. We find that MESH1 knockdown induced different genes involving endoplasmic reticulum (ER) stress, especially ATF3, one of the ATF4-regulated genes in the integrative stress responses (ISR). Furthermore, MESH1 knockdown increased ATF4 protein, eIF2a phosphorylation, and induction of ATF3, XBPs, and CHOP mRNA. ATF4 induction contributes to ~30% of the transcriptome induced by MESH1 knockdown. Concurrent ATF4 knockdown re-sensitizes MESH1-depleted RCC4 cells to ferroptosis, suggesting its role in the ferroptosis protection mediated by MESH1 knockdown. ATF3 induction is abolished by the concurrent knockdown of NADK, implicating a role of NADPH accumulation in the integrative stress response. Collectively, these results suggest that MESH1 depletion triggers ER stress and ISR as a part of its overall transcriptome changes to enable stress survival of cancer cells. Therefore, the phenotypic similarity of stress tolerance caused by MESH1 removal and NADPH accumulation is in part achieved by ISR to regulate ferroptosis.

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Tianai Sun

The Hippo Pathway Effector TAZ Regulates Ferroptosis in Renal Cell Carcinoma

MESH1 is a cytosolic NADPH phosphatase that regulates ferroptosis

The Hippo Pathway Effector TAZ Regulates Ferroptosis in Renal Cell Carcinoma

Regulation of ferroptosis in cancer cells by YAP/TAZ and Hippo pathways: The therapeutic implications

The regulation of ferroptosis by MESH1 through the activation of the integrative stress response

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