Ca2+ dynamics and oxidative signaling are fundamental mechanisms for mitochondrial bioenergetics and cell function. The MCU complex is the major pathway by which these signals are integrated ...in mitochondria. Whether and how these coactive elements interact with MCU have not been established. As an approach toward understanding the regulation of MCU channel by oxidative milieu, we adapted inflammatory and hypoxia models. We identified the conserved cysteine 97 (Cys-97) to be the only reactive thiol in human MCU that undergoes S-glutathionylation. Furthermore, biochemical, structural, and superresolution imaging analysis revealed that MCU oxidation promotes MCU higher order oligomer formation. Both oxidation and mutation of MCU Cys-97 exhibited persistent MCU channel activity with higher Ca2+m uptake rate, elevated mROS, and enhanced Ca2+m overload-induced cell death. In contrast, these effects were largely independent of MCU interaction with its regulators. These findings reveal a distinct functional role for Cys-97 in ROS sensing and regulation of MCU activity.
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•Mitochondrial Ca2+ uniporter complex core component senses mitochondrial ROS•MCU Cys-97 undergoes S-glutathionylation and exhibits as a higher-order oligomer•Interaction between MCU and its regulatory components is unaltered by MCU oxidation•Inflammatory/hypoxia signals promote MCU oxidation and sensitize cells to death
Dong et al. show that conserved MCU Cys-97 senses mitochondrial luminal ROS, and MCU oxidation promotes MCU higher-order oligomer formation and exhibits persistent activation of the MCU channel, elevated mitochondrial ROS, and enhanced Ca2+m overload-induced cell death. These findings reveal a distinct functional role for Cys-97 in mROS sensing and regulation of MCU activity.
Transient receptor potential melastatin channel subfamily member 2 (TRPM2) has an essential function in cell survival and is highly expressed in many cancers. Inhibition of TRPM2 in neuroblastoma by ...depletion with CRISPR technology or expression of dominant negative TRPM2-S has been shown to significantly reduce cell viability. Here, the role of proline-rich tyrosine kinase 2 (Pyk2) in TRPM2 modulation of neuroblastoma viability was explored. In TRPM2-depleted cells, phosphorylation and expression of Pyk2 and cAMP-responsive element-binding protein (CREB), a downstream target, were significantly reduced after application of the chemotherapeutic agent doxorubicin. Overexpression of wild-type Pyk2 rescued cell viability. Reduction of Pyk2 expression with shRNA decreased cell viability and CREB phosphorylation and expression, demonstrating Pyk2 modulates CREB activation. TRPM2 depletion impaired phosphorylation of Src, an activator of Pyk2, and this may be a mechanism to reduce Pyk2 phosphorylation. TRPM2 inhibition was previously demonstrated to decrease mitochondrial function. Here, CREB, Pyk2, and phosphorylated Src were reduced in mitochondria of TRPM2-depleted cells, consistent with their role in modulating expression and activation of mitochondrial proteins. Phosphorylated Src and phosphorylated and total CREB were reduced in TRPM2-depleted nuclei. Expression and function of mitochondrial calcium uniporter (MCU), a target of phosphorylated Pyk2 and CREB, were significantly reduced. Wild-type TRPM2 but not Ca
-impermeable mutant E960D reconstituted phosphorylation and expression of Pyk2 and CREB in TRPM2-depleted cells exposed to doxorubicin. Results demonstrate that TRPM2 expression protects the viability of neuroblastoma through Src, Pyk2, CREB, and MCU activation, which play key roles in maintaining mitochondrial function and cellular bioenergetics.
Resting mitochondrial matrix Ca2+ is maintained through a mitochondrial calcium uptake 1 (MICU1)-established threshold inhibition of mitochondrial calcium uniporter (MCU) activity. It is not known ...how MICU1 interacts with MCU to establish this Ca2+ threshold for mitochondrial Ca2+ uptake and MCU activity. Here, we show that MICU1 localizes to the mitochondrial matrix side of the inner mitochondrial membrane and MICU1/MCU binding is determined by a MICU1 N-terminal polybasic domain and two interacting coiled-coil domains of MCU. Further investigation reveals that MICU1 forms homo-oligomers, and this oligomerization is independent of the polybasic region. However, the polybasic region confers MICU1 oligomeric binding to MCU and controls mitochondrial Ca2+ current (IMCU). Moreover, MICU1 EF hands regulate MCU channel activity, but do not determine MCU binding. Loss of MICU1 promotes MCU activation leading to oxidative burden and a halt to cell migration. These studies establish a molecular mechanism for MICU1 control of MCU-mediated mitochondrial Ca2+ accumulation, and dysregulation of this mechanism probably enhances vascular dysfunction.
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•Mitochondrial Ca2+ is maintained by MICU1 inhibition of mitochondrial uniporter•MICU1 localizes to the mitochondrial matrix and forms homo-oligomers•MICU1/MCU binding is determined by a MICU1 N-terminal polybasic domain•MICU1 EF hands determine MCU activity, but not binding
Resting mitochondrial matrix Ca2+ is maintained through a MICU1-established threshold inhibition of mitochondrial calcium uniporter (MCU) activity. Madesh and colleagues show that MICU1 localizes to the mitochondrial matrix and that MICU1/MCU interaction is determined by a MICU1 N-terminal polybasic domain and two interacting coiled-coil domains of MCU. MICU1 forms homo-oligomers, and this oligomerization is independent of the polybasic region. Loss of MICU1 promotes MCU activation leading to oxidative burden and a halt to endothelial cell migration. MICU1 dysregulation may thus enhance vascular dysfunction.
Obesity increases the risk of hepatocellular carcinoma (HCC) especially in men, but the molecular mechanism remains obscure. Here, we show that an androgen receptor (AR)-driven oncogene, cell ...cycle-related kinase (CCRK), collaborates with obesity-induced pro-inflammatory signaling to promote non-alcoholic steatohepatitis (NASH)-related hepatocarcinogenesis. Lentivirus-mediated Ccrk ablation in liver of male mice fed with high-fat high-carbohydrate diet abrogates not only obesity-associated lipid accumulation, glucose intolerance and insulin resistance, but also HCC development. Mechanistically, CCRK fuels a feedforward loop by inducing STAT3-AR promoter co-occupancy and transcriptional up-regulation, which in turn activates mTORC1/4E-BP1/S6K/SREBP1 cascades via GSK3β phosphorylation. Moreover, hepatic CCRK induction in transgenic mice stimulates mTORC1-dependent G
csf expression to enhance polymorphonuclear myeloid-derived suppressor cell recruitment and tumorigenicity. Finally, the STAT3-AR-CCRK-mTORC1 pathway components are concordantly over-expressed in human NASH-associated HCCs. These findings unveil the dual roles of an inflammatory-CCRK circuitry in driving metabolic and immunosuppressive reprogramming through mTORC1 activation, thereby establishing a pro-tumorigenic microenvironment for HCC development.
Although peroxisome proliferator‐activated receptor gamma (PPARγ) agonist have been shown to inhibit hepatocellular carcinoma (HCC) development, the role of PPARγ in hepatocarcinogenesis remains ...unclear. We investigated the therapeutic efficacy of PPARγ against HCC. PPARγ‐deficient (PPARγ+/−) and wild‐type (PPARγ+/+) littermates were used in a diethylnitrosamine (DEN)‐induced HCC model and treated with PPARγ agonist (rosiglitazone) or the vehicle alone for 8 months. The effects of PPARγ on HCC cell growth and apoptosis were examined using PPARγ‐expressing adenovirus (Ad‐PPARγ). PPARγ+/− mice were more susceptible to DEN‐induced HCC than PPARγ+/+ mice (94% versus 62%, P < 0.05), and rosiglitazone significantly reduced the incidence of HCC in PPARγ+/+ mice (vehicle 62% versus treatment 24%, P < 0.01), but not in PPARγ+/− mice, indicating that PPARγ suppresses hepatocellular carcinogenesis. A pronounced expression of PPARγ was observed in a HCC cell line (Hep3B) infected with Ad‐PPARγ. Such induction markedly suppressed HCC cell viability (P < 0.01). Further, Hep3B infection with Ad‐PPARγ revealed a decreased proportion of cells in S‐phase (12.92% versus 11.58%, P < 0.05), with arrest at G2/M phase (38.2% versus 55.68%, P < 0.001), and there was concomitant phosphorylation of the key G2/M phase inhibitors cdc25C and cdc2. PPARγ overexpression increased cell apoptosis (21.47% versus 35.02%, P < 0.01), mediated by both extrinsic (Fas and tumor necrosis factor‐α) and intrinsic (caspase‐9, caspase‐3, caspase‐7, and polyADP‐ribose polymerase) pathways. Moreover, PPARγ directly induced a putative tumor suppressor gene, growth differentiation factor‐15. Conclusion: Loss of one PPARγ allele is sufficient to enhance susceptibility to HCC. PPARγ suppresses tumor cell growth through reducing cell proliferation and inducing G2/M phase arrest, apoptosis, and up‐regulating growth differentiation factor‐15. Thus, PPARγ acts as a tumor‐suppressor gene in the liver. HEPATOLOGY 2010
Current Landscape of Heart Failure Gene Therapy Kieserman, Jake M; Myers, Valerie D; Dubey, Praveen ...
Journal of the American Heart Association,
05/2019, Letnik:
8, Številka:
10
Journal Article
Mitochondrial Ca2+ Uniporter (MCU)-dependent mitochondrial Ca2+ uptake is the primary mechanism for increasing matrix Ca2+ in most cell types. However, a limited understanding of the MCU complex ...assembly impedes the comprehension of the precise mechanisms underlying MCU activity. Here, we report that mouse cardiomyocytes and endothelial cells lacking MCU regulator 1 (MCUR1) have severely impaired Ca2+m uptake and IMCU current. MCUR1 binds to MCU and EMRE and function as a scaffold factor. Our protein binding analyses identified the minimal, highly conserved regions of coiled-coil domain of both MCU and MCUR1 that are necessary for heterooligomeric complex formation. Loss of MCUR1 perturbed MCU heterooligomeric complex and functions as a scaffold factor for the assembly of MCU complex. Vascular endothelial deletion of MCU and MCUR1 impaired mitochondrial bioenergetics, cell proliferation, and migration but elicited autophagy. These studies establish the existence of a MCU complex that assembles at the mitochondrial integral membrane and regulates Ca2+-dependent mitochondrial metabolism.
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•MCUR1 binds to MCU and EMRE and functions as a scaffold factor•The coiled-coil domains of both MCU and MCUR1 are essential for MCU complex assembly•Genetic deletion of MCUR1 severely impairs Ca2+m uptake and IMCU current•MCUR1 deletion impairs bioenergetics and cell migration and elicits autophagy
Tomar et al. show that genetic ablation of the MCU complex component MCUR1 perturbs MCU heterooligomeric complex and impairs mitochondrial Ca2+ uptake. MCUR1 binds to MCU and EMRE and functions as a scaffold factor that is necessary for proper Ca2+-dependent mitochondrial bioenergetics.
G protein-coupled receptor kinase 2 (GRK2) is a well-established therapeutic target for the treatment of heart failure. Herein we identify the selective serotonin reuptake inhibitor (SSRI) paroxetine ...as a selective inhibitor of GRK2 activity both in vitro and in living cells. In the crystal structure of the GRK2·paroxetine–Gβγ complex, paroxetine binds in the active site of GRK2 and stabilizes the kinase domain in a novel conformation in which a unique regulatory loop forms part of the ligand binding site. Isolated cardiomyocytes show increased isoproterenol-induced shortening and contraction amplitude in the presence of paroxetine, and pretreatment of mice with paroxetine before isoproterenol significantly increases left ventricular inotropic reserve in vivo with no significant effect on heart rate. Neither is observed in the presence of the SSRI fluoxetine. Our structural and functional results validate a widely available drug as a selective chemical probe for GRK2 and represent a starting point for the rational design of more potent and specific GRK2 inhibitors.
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