Avian mitochondrial glutamine metabolism.

Intact avian liver mitochondria were shown to synthesize glutamine from glutamate in the absence of exogenous ATP and ammonia. With L-[U-14C]glutamate as the substrate, there was an approximate 1:1 stoichiometry between glutamate deaminated (as measured by the release of 14CO2 due to alpha-keto-[14C]glutarate oxidation) and glutamate amidated. With L-[15N]glutamate as the substrate, the isolated glutamine was shown by low and high resolution mass spectrometry of its phenylisothiocyanate derivative to contain 15N in both the alpha-amino and amide groups. Thus, for each mole of glutamate taken up, approximately 0.5 mol is deaminated and the other 0.5 mol serves as a substrate for glutamine synthetase previously localized in these mitochondria (Vorhaben, J. E., and Campbell, J. W. (1972) J. Biol. Chem. 247,2763). The permeability of L-glutamine to intact avian liver mitochondria was studied by a rapid centrifugation technique. Efflux as well as influx of L-glutamine were both rapid and appeared to occur by a passive, energy-independent process. These results indicate that the mitochondrial glutamine synthetase present in uricotelic species represents the primary ammonia detoxication reaction in that ammonia released intramitochondrially during amino acid catabolism is converted to glutamine for efflux to the cytosol where it may serve as a substrate for purine (uric acid) biosynthesis.     

Hypoxia and mitochondrial oxidative metabolism

It is now clear that mitochondrial defects are associated with a large variety of clinical phenotypes. This is the result of the mitochondria's central role in energy production, reactive oxygen species homeostasis, and cell death. These processes are interdependent and may occur under various stressing conditions, among which low oxygen levels (hypoxia) are certainly prominent. Cells exposed to hypoxia respond acutely with endogenous metabolites and proteins promptly regulating metabolic pathways, but if low oxygen levels are prolonged, cells activate adapting mechanisms, the master switch being the hypoxia-inducible factor 1 (HIF-1). Activation of this factor is strictly bound to the mitochondrial function, which in turn is related with the oxygen level. Therefore in hypoxia, mitochondria act as [O₂] sensors, convey signals to HIF-1directly or indirectly, and contribute to the cell redox potential, ion homeostasis, and energy production. Although over the last two decades cellular responses to low oxygen tension have been studied extensively, mechanisms underlying these functions are still indefinite. Here we review current knowledge of the mitochondrial role in hypoxia, focusing mainly on their role in cellular energy and reactive oxygen species homeostasis in relation with HIF-1 stabilization. In addition, we address the involvement of HIF-1 and the inhibitor protein of F₁F₀ ATPase in the hypoxia-induced mitochondrial autophagy.     

Stimulation of mitochondrial pyruvate metabolism and citrulline synthesis by dexamethasone. Effect of isolation and incubation media.

Hepatic mitochondria isolated in 0.3 M-sucrose or 0.3 M-mannitol from rats treated for 3h with dexamethasone displayed stimulated rates of pyruvate carboxylation and decarboxylation and citrulline synthesis when compared with organelles from control animals. Mitochondria isolated in mannitol also displayed elevated rates of pyruvate carboxylation and decarboxylation when compared with those isolated in sucrose, and this stimulation was shown to be independent of the lengthy isolation procedure. Citrulline synthesis proceeded at similar rates in mitochondria isolated in either sugar. The concentration of exchangeable adenine nucleotides was identical in mitochondria isolated in sucrose or mannitol, suggesting that those prepared in the former sugar are not more permeable to metabolites than those prepared in the latter. The matrix volume of mitochondria isolated in mannitol was greater than that of mitochondria isolated in sucrose, and the effect of mannitol on pyruvate metabolism was mimicked by swelling the organelles in hypo-osmotic sucrose. Measurements of the extra-matrix volume by using [14C]sucrose or [14C]mannitol suggest that mannitol can permeate mitochondria to a greater extent than can sucrose. The possibility that mannitol elicits its effect by entering the mitochondrial matrix and so initiating swelling is discussed.     

Regulation of metabolism by mitochondrial enzyme acetylation in cardiac ischemia-reperfusion injury

Ischemia reperfusion injury (I/R injury) contributes significantly to morbidity and mortality following myocardial infarction (MI). Although rapid reperfusion of the ischemic myocardium was established decades ago as a highly beneficial therapy for MI, significant cell death still occurs after the onset of reperfusion. Mitochondrial dysfunction is closely associated with I/R injury, resulting in the uncontrolled production of reactive oxygen species (ROS). Considerable efforts have gone into understanding the metabolic perturbations elicited by I/R injury. Recent work has identified the critical role of reversible protein acetylation in maintaining normal mitochondrial biologic function and energy metabolism both in the normal heart and during I/R injury. Several studies have shown that modification of class I HDAC and/or Sirtuin (Sirt) activity is cardioprotective in the setting of I/R injury. A better understanding of the role of these metabolic pathways in reperfusion injury and their regulation by reversible protein acetylation presents a promising way forward in improving the treatment of cardiac reperfusion injury. Here we briefly review some of what is known about how acetylation regulates mitochondrial metabolism and how it relates to I/R injury.     

Nature of enhanced mitochondrial oxidative metabolism by a calf blood extract

The effect of calf blood extract (Solcoseryl, SS) on mitochondrial oxidative function in various states was studied polarographically in vitro. 1) Mitochondrial respiration in all 4 conventional study states (Estabrook, 1967) was enhanced by the addition of SS, including states 1 and 2 (endogenous substrates only). 2) The effect of SS on mitochondrial oxygen consumption was concentration dependent, while ADP/O ratio remained constant. The effect of added respiratory substrates varied with the particular substrate at optimally active concentrations. With suboptimal substrate levels, ADP/O ratios were concentration dependent, in contrast to the SS effect. Under oligomycin ATPase inhibition, SS was no longer active, in contrast to DNP, which remained active. 3) In states 3 (added ADP) and 4 (ADP exhausted), oxygen consumption and oxidative phosphorylation were enhanced by SS in the presence or absence of citrate, glutamate, pyruvate, lactate, or ascorbate. However, in the presence of succinate, SS had no effect. 4) ADP/O ratio was decreased by SS in the presence of added substrate, suggesting that SS activation of H(+)-ATPase enhances ATP hydrolysis as well as oxidative phosphorylation and ATP synthesis. 5) The enhancing effect of SS on mitochondrial function is due to hydrophilic components of SS. The lipidic components obtained by Folch fraction of SS have no effect. It is concluded that the effects of SS respiratory substrates and uncouplers on mitochondrial function are essentially different. SS enhances both ATP synthesis and oxygen consumption by mitochondria.     

Methotrexate: studies on cellular metabolism. II--Effects on mitochondrial oxidative metabolism and ion transport

Effects of methotrexate (MTX) on mitochondrial oxidative metabolism and ion transport were studied. MTX decreases the membrane potential (delta psi) upon energization of the mitochondrial membrane by NAD+-linked substrates and decreases the amplitude and velocity of swelling induced by glutamate and alpha-ketoglutarate. MTX also has an inhibitory effect on the activities of the oxidation enzymes of NAD+-linked substrates without interfering with the oxidation systems of FAD-linked substrates. The effects of MTX could be interpreted as a consequence of a decrease in the ionic conductivity of the mitochondrial inner membrane.     

Depression of mitochondrial metabolism by downregulation of cytoplasmic deacetylase, HDAC6

Mitochondria perform multiple functions critical to the maintenance of cellular homeostasis. Here we report that the downregulation of histone deacetylase 6 (HDAC6) causes a reduction in the net activity of mitochondrial enzymes, including respiratory complex II and citrate synthase. HDAC6 deacetylase and ubiquitin-binding activities were both required for recovery of reduced mitochondrial metabolic activity due to the loss of HDAC6. Hsp90, a substrate of HDAC6, localizes to mitochondria and partly mediates the regulation of mitochondrial metabolic activity by HDAC6. Our finding suggests that HDAC6 regulates mitochondrial metabolism and might serve as a cellular homeostasis surveillance factor.     

Autophagy promotes BrafV600E-driven lung tumorigenesis by preserving mitochondrial metabolism

The role of autophagy in cancer is complex and context-dependent. Here we describe work with genetically engineered mouse models of non-small cell lung cancer (NSCLC) in which the tumor-suppressive and tumor-promoting function of autophagy can be visualized in the same system. We discovered that early tumorigenesis in Braf^V600E-driven lung cancer is accelerated by autophagy ablation due to unmitigated oxidative stress, as observed with loss of Nfe2l2/Nrf2-mediated antioxidant defense. However, this growth advantage is eventually overshadowed by progressive mitochondrial dysfunction and metabolic insufficiency, and is associated with increased survival of mice bearing autophagy-deficient tumors. Atg7 deficiency alters progression of Braf^V600E-driven tumors from adenomas (Braf^V600E; atg7^?/?) and adenocarcinomas (trp53^?/?; Braf^V600E; atg7^?/?) to benign oncocytomas that accumulated morphologically and functionally defective mitochondria, suggesting that defects in mitochondrial metabolism may compromise continued tumor growth. Analysis of tumor-derived cell lines (TDCLs) revealed that Atg7-deficient cells are significantly more sensitive to starvation than Atg7–wild-type counterparts, and are impaired in their ability to respire, phenotypes that are rescued by the addition of exogenous glutamine. Taken together, these data suggest that Braf^V600E-driven tumors become addicted to autophagy as a means to preserve mitochondrial function and glutamine metabolism, and that inhibiting autophagy may be a powerful strategy for Braf^V600E-driven malignancies.     

Features of lineage‐specific hematopoietic metabolism revealed by mitochondrial proteomics

Hematopoietic bone marrow is a regenerative tissue of high clinical relevance, yet relatively little is known about the metabolism of the stem and progenitor populations concerned. We have used a multipotent murine cell line to generate sufficient numbers of cells undergoing self‐renewal, erythroid or myeloid differentiation to allow a proteomics analysis of enriched mitochondria. Stringent analysis identified 37 mitochondria‐associated proteins changing on differentiation in this system. Those induced during differentiation were commonly associated with mature cell functions, while those inactivated upon differentiation indicate widespread changes in mitochondrial transport, fatty acid catabolism and oxidative phosphorylation. An erythroid specific reduction in glutamate pyruvate amino transferase 2 was confirmed at the protein level by Western blotting and at the functional level by assays of metabolite turnover. In addition to validating the dataset, these findings suggest significant differences in the core‐metabolism between erythropoiesis and myelopoiesis. This knowledge is of relevance to the in vitro production of cell therapy products and to studies of the interdependence of metabolic and signaling pathways in regenerative tissues. Data are available via ProteomeXchange with identifier PXD002968.