Project description:Mitochondrial proteases regulate the dynamic properties of the organelle morphology and ensure functional plasticity at the cellular level. The metalloprotease OMA1 mediates constitutive and stress-inducible processing of its substrates in mitochondria, but the number of functionally characterized substrates remains limited. Using multiproteomic and biochemical approaches, we show that the membrane-anchored inner membrane space (IMS) protein AIFM1 serves as a mitochondrial stress-responsive substrate of OMA1. We define that OMA1 cleaves AIFM1 in the IMS under stress conditions, which is a kinetically slower reaction than that of the conventional substrate, the dynamin-like GTPase OPA1. Membrane dislocation of cleaved AIFM1 in mitochondria reduces its binding to subunits of the oxidative phosphorylation machinery. This leads to a decrease in the respiratory activity and ultimately impairs cell growth. Mechanistically, we show that AIFM1 broadly safeguards the mitochondrial proteome at steady state by participating in the protein import, in particular respiratory complex I subunits, via the Tim23 complex. These results reveal an unrecognized role for OMA1 in integrating mitochondrial stress sensing and cellular energetics by altering the topology of AIFM1.The internal identifier was: m4m1hgAENCThe repository contains AIFM1 wildtype and KO TREx cells (samples 1-8), which were not used in the associated publication. The file names contain pp for +/+ and mm for -/-.File names 09-12 (file names: R98ENLYFG) correspond to TCS. The file names 13-16 (M1_R98del) correspond to TCS/TEV.Raw fileSample Name01_AIFM1_KO_pp_fyxK.rawFlp-In-T REx-293-mock#102_AIFM1_KO_pp_wxP9.rawFlp-In-T REx-293-mock#203_AIFM1_KO_pp_Djpr.rawFlp-In-T REx-293-mock#304_AIFM1_KO_pp_txOk.rawFlp-In-T REx-293-mock#405_AIFM1_KO_mm_moaT.rawFlp-In-T REx-293 AIFM1 KO-mock#106_AIFM1_KO_mm_W5lK.rawFlp-In-T REx-293 AIFM1 KO-mock#207_AIFM1_KO_mm_XIc0.rawFlp-In-T REx-293 AIFM1 KO-mock#308_AIFM1_KO_mm_pdxt.rawFlp-In-T REx-293 AIFM1 KO-mock#409_AIFM1_C_MycAIFM1_R98ENLYFG_I2x8.rawFlp-In-T REx-293 AIFM1 KO-AIFM1TCS#110_AIFM1_C_MycAIFM1_R98ENLYFG_Hzqq.rawFlp-In-T REx-293 AIFM1 KO-AIFM1TCS#211_AIFM1_C_MycAIFM1_R98ENLYFG_4P4M.rawFlp-In-T REx-293 AIFM1 KO-AIFM1TCS#312_AIFM1_C_MycAIFM1_R98ENLYFG_MktX.rawFlp-In-T REx-293 AIFM1 KO-AIFM1TCS#413_AIFM1_C_MycAIFM1_M1_R98del_7NiF.rawFlp-In-T REx-293 AIFM1 KO-AIFM1TCS/TEV#114_AIFM1_C_MycAIFM1_M1_R98del_yf68.rawFlp-In-T REx-293 AIFM1 KO-AIFM1TCS/TEV#215_AIFM1_C_MycAIFM1_M1_R98del_hmKM.rawFlp-In-T REx-293 AIFM1 KO-AIFM1TCS/TEV#316_AIFM1_C_MycAIFM1_M1_R98del_qXgO.rawFlp-In-T REx-293 AIFM1 KO-AIFM1TCS/TEV#4

Project description:To better understand how OMA1 affects mitochondrial proteostasis and stress responses, we performed a proteomic survey of OMA1-deficient cells for proteolytic substrates. We demonstrate that OMA1 cleaves the mitochondrial chaperone DNAJC15 facilitating its degradation by the mitochondrial m-AAA protease. The loss of DNAJC15 alters protein import by TIM23 protein translocases in the IM and limits the accumulation of OXPHOS-related mitochondrial matrix and IM proteins. Non-imported mitochondrial preproteins accumulate at the endoplasmic reticulum (ER) and trigger an ATF6-related unfolded protein response. These results demonstrate that OMA1 allows to adapt mitochondrial protein biogenesis to stress and reveal an intricate network of cellular stress responses to proteostasis disturbances.

Project description:CSDE1 is an RNA-binding protein that associates with a subset of mitochondria-related transcripts. We previously observed that RNAs encoding mitochondrial proteins localized to the mitochondrial inner membrane (MIM), intermembrane space (IMS), matrix, and outer membrane (MOM) are enriched within the CSDE1-bound RNA pool. To determine whether CSDE1 regulates the abundance and mitochondrial localization of mitochondria-associated RNAs in sensory neurons, we performed RNA sequencing of both total RNA and RNA extracted from isolated mitochondria isolated from CSDE1-knockdown sensory neurons. CSDE1 knockdown was achieved using lentiviral transduction, and sequencing results were compared with control neurons infected with empty vector (pLKO).

Project description:Mutations in CHCHD10, a mitochondrial protein implicated in proteostasis and cristae maintenance, cause autosomal dominant mitochondrial diseases characterized by cardiomyopathy and neurodegeneration. Heterozygous Chchd10 S55L knock-in mice (modeling the human S59L variant) develop progressive mitochondrial cardiomyopathy driven by CHCHD10 aggregation, which is associated with chronic activation of the mitochondrial integrated stress response (mtISR). Here, we demonstrate that cardiac dysfunction is affected by biological sex and is associated with dual defects originating at the onset of disease: (1) early respiratory chain failure linked to cytochrome c depletion and impaired copper homeostasis and (2) maladaptive mtISR signaling via the OMA1-DELE1-HRI axis. Genetic inactivation of OMA1 delays cardiomyopathy without rescuing CHCHD10 insolubility, proteomic remodeling, cristae defects or OXPHOS impairment, demonstrating that mtISR can be uncoupled from the bioenergetic collapse triggered by CHCHD10 protein aggregation. Proteomic profiling of soluble and insoluble mitochondrial proteins reveals wide-spread disruptions of mitochondrial proteostasis, including IMS proteins involved in cytochrome c biogenesis. Defective respiration in mutant mitochondria could be rescued by the exogenous addition of cytochrome c, pinpointing IMS proteostasis disruption as a key pathogenic mechanism. Our work reveals that CHCHD10 insolubility and aggregation compromises metabolic resilience by impairing both electron transport and stress adaptation within the IMS, offering new perspectives for the development of therapeutic targets. This repository is connected to PXD064045. The internal idetnfier is: DECTXuxSGj Please note that we had to rename the raw file containing ++ and +- to WT and HET, respectively due to character contstrains in PRIDE submission.

Project description:Mutations in CHCHD10, a mitochondrial protein implicated in proteostasis and cristae maintenance, cause autosomal dominant mitochondrial diseases characterized by cardiomyopathy and neurodegeneration. Heterozygous Chchd10 S55L knock-in mice (modeling the human S59L variant) develop progressive mitochondrial cardiomyopathy driven by CHCHD10 aggregation, which is associated with chronic activation of the mitochondrial integrated stress response (mtISR). Here, we demonstrate that cardiac dysfunction is affected by biological sex and is associated with dual defects originating at the onset of disease: (1) early respiratory chain failure linked to cytochrome c depletion and impaired copper homeostasis and (2) maladaptive mtISR signaling via the OMA1-DELE1-HRI axis. Genetic inactivation of OMA1 delays cardiomyopathy without rescuing CHCHD10 insolubility, proteomic remodeling, cristae defects or OXPHOS impairment, demonstrating that mtISR can be uncoupled from the bioenergetic collapse triggered by CHCHD10 protein aggregation. Proteomic profiling of soluble and insoluble mitochondrial proteins reveals wide-spread disruptions of mitochondrial proteostasis, including IMS proteins involved in cytochrome c biogenesis. Defective respiration in mutant mitochondria could be rescued by the exogenous addition of cytochrome c, pinpointing IMS proteostasis disruption as a key pathogenic mechanism. Our work reveals that CHCHD10 insolubility and aggregation compromises metabolic resilience by impairing both electron transport and stress adaptation within the IMS, offering new perspectives for the development of therapeutic targets. This repository contains the heart whole proteome of the four different genotypes. a) whole proteome dataset is indicated by the identifier: KmUUbGabck

Project description:Double-membrane-bound architecture of mitochondria is essential for its ATP synthesis function; simultaneously such structure sub-divides the organelle into inter-membrane space (IMS) and matrix. IMS and matrix are inherently different in protein folding milieu due to their contrasting oxido-reductive environments and distinctly different protein quality control (PQC) machineries. By inducing proteotoxic stress limited to IMS or matrix using varied stressor proteins, we decipher distinct cellular response to IMS and matrix stress. IMS stress leads to specific upregulation of IMS-resident chaperones and TOM complex components. In contrast, matrix stress leads to specific upregulation of matrix- chaperones and cytosolic PQC components. We report that cells respond to mitochondrial stress by an adaptive mechanism by adjourning mitochondrial respiration while upregulating glycolysis as a compensatory pathway. By systematic genetic interaction, we show that TOM complex components act as specific modulators of IMS-stress response while Vms1 preferentially modulates the matrix stress response

Project description:Mitochondria adapt to cellular stress to ensure cell survival. The stress-regulated mitochondrial peptidase OMA1 orchestrates these adaptive responses, which limit mitochondrial fusion and promote mitochondrial stress signaling and metabolic rewiring. Here, we show that cellular stress adaptation involves OMA1-mediated regulation of mitochondrial protein import and OXPHOS biogenesis. OMA1 cleaves the mitochondrial chaperone DNAJC15 and promotes its degradation by the m-AAA protease AFG3L2. Loss of DNAJC15 reduces the import of OXPHOS-related proteins via the TIMM23-TIMM17A protein translocase, limiting OXPHOS biogenesis under conditions of mitochondrial dysfunction. Non-imported mitochondrial preproteins accumulate at the endoplasmic reticulum and induce an ATF6-related unfolded protein response. Our results demonstrate stress-dependent changes in protein import specificity as part of the OMA1-mediated mitochondrial stress response and highlight the interdependence of proteostasis regulation between different organelles. This dataset contains the fractions of plasmamembrane (40kg), the golgi (100kg) and the soluble fraction. The whole cell (wc), mitochondria (mt) and mitochondria + proteinase K are available under the identifier: Check the attached Excel file for description of the samples and the SILAC channels.

Project description:Mitochondria dynamically adapt to cellular stress to ensure cell survival. The stress-regulated mitochondrial peptidase OMA1 orchestrates these adaptive responses, which limit mitochondrial fusion and promote mitochondrial stress signaling and metabolic rewiring. Here, we show that cellular stress adaptation involves OMA1-mediated regulation of mitochondrial protein import and OXPHOS biogenesis. OMA1 cleaves the mitochondrial chaperone DNAJC15 and promotes its degradation by the m-AAA protease AFG3L2. Loss of DNAJC15 impairs mitochondrial protein import and restricts OXPHOS biogenesis under conditions of mitochondrial dysfunction. Non-imported mitochondrial preproteins accumulate at the endoplasmic reticulum inducing an unfolded protein response. Our results demonstrate stress-dependent changes in mitochondrial protein import as part of the OMA1-mediated mitochondrial stress response and highlight the interdependence of proteostasis regulation between different organelles.

Project description:Mitochondria adapt to cellular stress to ensure cell survival. The stress-regulated mitochondrial peptidase OMA1 orchestrates these adaptive responses, which limit mitochondrial fusion and promote mitochondrial stress signaling and metabolic rewiring. Here, we show that cellular stress adaptation involves OMA1-mediated regulation of mitochondrial protein import and OXPHOS biogenesis. OMA1 cleaves the mitochondrial chaperone DNAJC15 and promotes its degradation by the m-AAA protease AFG3L2. Loss of DNAJC15 reduces the import of OXPHOS-related proteins via the TIMM23-TIMM17A protein translocase, limiting OXPHOS biogenesis under conditions of mitochondrial dysfunction. Non-imported mitochondrial preproteins accumulate at the endoplasmic reticulum and induce an ATF6-related unfolded protein response. Our results demonstrate stress-dependent changes in protein import specificity as part of the OMA1-mediated mitochondrial stress response and highlight the interdependence of proteostasis regulation between different organelles.

Project description:The goal of this study is to understand how mamalian cells respond to the mitochondial stress. Using Quant-seq, we identifed an integrated stress response signature in the cells with compromized mitochondria. Furthermore, using an unbiased CRISPRi genetic screen, we uncovered a novel signaling pathway, in which OMA1, DELE1 and HRI are three major players that relay the mitochondrial stress to the integated stress response. To further study the cellular response in the absence of this pathway, we again used Quant-seq to uncover alternative pathways that might play a role during the mitochondrial stress response.