Project description: Not available

Project description:The bioenergetics and molecular determinants of the metabolic response to mitochondrial dysfunction are incompletely understood, in part due to a lack of appropriate isogenic cellular models of primary mitochondrial defects. Here, we capitalize on a recently developed cell model with defined levels of m.8993T>G mutation heteroplasmy, mTUNE, to investigate the metabolic underpinnings of mitochondrial dysfunction. We found that impaired utilization of reduced nicotinamide adenine dinucleotide (NADH) by the mitochondrial respiratory chain leads to cytosolic reductive carboxylation of glutamine as a new mechanism for cytosol-confined NADH recycling supported by malate dehydrogenase 1 (MDH1). We also observed that increased glycolysis in cells with mitochondrial dysfunction is associated with increased cell migration in an MDH1-dependent fashion. Our results describe a novel link between glycolysis and mitochondrial dysfunction mediated by reductive carboxylation of glutamine.

Project description:Artifacts due to metabolite extraction, derivatization, and detection techniques can result in aberrant observations that are not accurate representations of actual cell metabolism. Here, we show that α-ketoglutarate (α-KG) is reductively aminated to glutamate in methanol:water metabolite extracts, which introduces an artifact into metabolomics studies. We also identify pyridoxamine and urea as amine donors for α-KG to produce glutamate in methanol:water buffer in vitro, and we demonstrate that the addition of ninhydrin to the methanol:water buffer suppresses the reductive amination of α-KG to glutamate in vitro and in metabolite extracts. Finally, we calculate that glutamate levels have been overestimated by 10-50%, depending on cell line, due to α-KG reductive amination. These findings suggest that precautions to account for α-KG reductive amination should be taken for the accurate quantification of glutamate in metabolomics studies.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Mitochondrial metabolism provides precursors to build macromolecules in growing cancer cells. In normally functioning tumour cell mitochondria, oxidative metabolism of glucose- and glutamine-derived carbon produces citrate and acetyl-coenzyme A for lipid synthesis, which is required for tumorigenesis. Yet some tumours harbour mutations in the citric acid cycle (CAC) or electron transport chain (ETC) that disable normal oxidative mitochondrial function, and it is unknown how cells from such tumours generate precursors for macromolecular synthesis. Here we show that tumour cells with defective mitochondria use glutamine-dependent reductive carboxylation rather than oxidative metabolism as the major pathway of citrate formation. This pathway uses mitochondrial and cytosolic isoforms of NADP(+)/NADPH-dependent isocitrate dehydrogenase, and subsequent metabolism of glutamine-derived citrate provides both the acetyl-coenzyme A for lipid synthesis and the four-carbon intermediates needed to produce the remaining CAC metabolites and related macromolecular precursors. This reductive, glutamine-dependent pathway is the dominant mode of metabolism in rapidly growing malignant cells containing mutations in complex I or complex III of the ETC, in patient-derived renal carcinoma cells with mutations in fumarate hydratase, and in cells with normal mitochondria subjected to acute pharmacological ETC inhibition. Our findings reveal the novel induction of a versatile glutamine-dependent pathway that reverses many of the reactions of the canonical CAC, supports tumour cell growth, and explains how cells generate pools of CAC intermediates in the face of impaired mitochondrial metabolism.

Project description:Isocitrate dehydrogenase (IDH) is a reversible enzyme that catalyzes the NADP(+)-dependent oxidative decarboxylation of isocitrate (ICT) to α-ketoglutarate (αKG) and the NADPH/CO(2)-dependent reductive carboxylation of αKG to ICT. Reductive carboxylation by IDH1 was potently inhibited by NADP(+) and, to a lesser extent, by ICT. IDH1 and IDH2 with cancer-associated mutations at the active site arginines were unable to carry out the reductive carboxylation of αKG. These mutants were also defective in ICT decarboxylation and converted αKG to 2-hydroxyglutarate using NADPH. These mutant proteins were thus defective in both of the normal reactions of IDH. Biochemical analysis of heterodimers between wild-type and mutant IDH1 subunits showed that the mutant subunit did not inactivate reductive carboxylation by the wild-type subunit. Cells expressing the mutant IDH are thus deficient in their capacity for reductive carboxylation and may be compromised in their ability to produce acetyl-CoA under hypoxia or when mitochondrial function is otherwise impaired.

Project description:Environmental stresses, including hypoxia or detachment for anchorage independence, or attenuation of mitochondrial respiration through inhibition of electron transport chain induce reductive carboxylation in cells with an enhanced fraction of citrate arising through reductive metabolism of glutamine. This metabolic process contributes to redox homeostasis and sustains biosynthesis of lipids. Reductive carboxylation is often dependent on cytosolic isocitrate dehydrogenase 1 (IDH1). However, whether diverse cellular signals induce reductive carboxylation differentially or through a common signaling converging node remains unclear. We found that induction of reductive carboxylation commonly requires enhanced tyrosine phosphorylation and activation of IDH1, which, surprisingly, is achieved by attenuation of a cytosolic protein tyrosine phosphatase, Src homology region 2 domain-containing phosphatase-2 (SHP-2). Mechanistically, diverse signals induce reductive carboxylation by converging at upregulation of NADPH oxidase 2, leading to elevated cytosolic reactive oxygen species that consequently inhibit SHP-2. Together, our work elucidates the signaling basis underlying reductive carboxylation in cancer cells.

Project description:The differentiation into effector and memory CD8+ T cell subsets was recently associated with specific metabolic pathways to sustain their diverse bioenergetics needs. Clonally expanding T cells rely strongly on glucose and glutamine utilization to maintain high cell proliferation and effector functions. We found that proliferating effector CD8+ T cells, in addition to oxidizing, also reductively carboxylate glutamine, to maintain rapid lipid synthesis for cell proliferation. Interfering with reductive carboxylation by genetic deletion of isocitrate dehydrogenase 2 (IDH2), the enzyme mediating this reaction in the mitochondria, surprisingly did not impair proliferation and effector function upon infection, but skewed the CD8+ T cell response towards enhanced memory differentiation. Pharmacological IDH2 inhibition during in vitro CAR T cell manufacturing also induced memory features and thus strongly enhanced their antitumor activity and persistence upon adoptive cell transfer into murine melanoma tumour models. Mechanistically, IDH2 inhibition caused a disequilibrium in metabolites regulating histone-modifying enzymes, which altered the epigenetic landscape, increasing chromatin accessibility at genes required for memory differentiation. Restoring this metabolite balance or preventing the epigenetic modifications abrogated the enhanced CD8+ T cell memory differentiation and anti-tumour activity induced by IDH2 inhibition. These findings suggest that reductive carboxylation of glutamine in activated CD8+ T cells is dispensable for their effector function, but instead primarily instructs a metabolite composition that epigenetically locks them in a terminal effector differentiation program. Blocking this metabolic route allows for increased memory formation, which can be exploited to optimize CAR T cell production for adoptive cell transfer immunotherapy against cancer.

Project description:The differentiation into effector and memory CD8+ T cell subsets was recently associated with specific metabolic pathways to sustain their diverse bioenergetics needs. Clonally expanding T cells rely strongly on glucose and glutamine utilization to maintain high cell proliferation and effector functions. We found that proliferating effector CD8+ T cells, in addition to oxidizing, also reductively carboxylate glutamine, to maintain rapid lipid synthesis for cell proliferation. Interfering with reductive carboxylation by genetic deletion of isocitrate dehydrogenase 2 (IDH2), the enzyme mediating this reaction in the mitochondria, surprisingly did not impair proliferation and effector function upon infection, but skewed the CD8+ T cell response towards enhanced memory differentiation. Pharmacological IDH2 inhibition during in vitro CAR T cell manufacturing also induced memory features and thus strongly enhanced their antitumor activity and persistence upon adoptive cell transfer into murine melanoma tumour models. Mechanistically, IDH2 inhibition caused a disequilibrium in metabolites regulating histone-modifying enzymes, which altered the epigenetic landscape, increasing chromatin accessibility at genes required for memory differentiation. Restoring this metabolite balance or preventing the epigenetic modifications abrogated the enhanced CD8+ T cell memory differentiation and anti-tumour activity induced by IDH2 inhibition. These findings suggest that reductive carboxylation of glutamine in activated CD8+ T cells is dispensable for their effector function, but instead primarily instructs a metabolite composition that epigenetically locks them in a terminal effector differentiation program. Blocking this metabolic route allows for increased memory formation, which can be exploited to optimize CAR T cell production for adoptive cell transfer immunotherapy against cancer.

Project description:To investigate the effects of the predominant nonprotein thiol, glutathione (GSH), on redox homeostasis, we employed complementary pharmacological and genetic strategies to determine the consequences of both loss- and gain-of-function GSH content in vitro. We monitored the redox events in the cytosol and mitochondria using reduction-oxidation sensitive green fluorescent protein (roGFP) probes and the level of reduced/oxidized thioredoxins (Trxs). Either H(2)O(2) or the Trx reductase inhibitor 1-chloro-2,4-dinitrobenzene (DNCB), in embryonic rat heart (H9c2) cells, evoked 8 or 50 mV more oxidizing glutathione redox potential, E(hc) (GSSG/2GSH), respectively. In contrast, N-acetyl-L-cysteine (NAC) treatment in H9c2 cells, or overexpression of either the glutamate cysteine ligase (GCL) catalytic subunit (GCLC) or GCL modifier subunit (GCLM) in human embryonic kidney 293 T (HEK293T) cells, led to 3- to 4-fold increase of GSH and caused 7 or 12 mV more reducing E(hc), respectively. This condition paradoxically increased the level of mitochondrial oxidation, as demonstrated by redox shifts in mitochondrial roGFP and Trx2. Lastly, either NAC treatment (EC(50) 4 mM) or either GCLC or GCLM overexpression exhibited increased cytotoxicity and the susceptibility to the more reducing milieu was achieved at decreased levels of ROS. Taken together, our findings reveal a novel mechanism by which GSH-dependent reductive stress triggers mitochondrial oxidation and cytotoxicity.