Browsing by Subject "Cell respiration"

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    PDK regulated Warburg effect protects differentiated adipocytes against ROS
    (2014-10-06) Roell, William Christopher; March, Keith L.; Considine, Robert V.; Harris, Robert A.; Tune, Johnathan David
    Literature has demonstrated the ability of human adipose tissue to generate large amounts of lactate. However, it is not understood why adipose tissue produces lactate, how the production of lactate is regulated, and what potential benefit this has to the adipocyte or the organism. We first characterized a human model of adipogenic differentiation with minimal donor to donor variability to assess metabolic changes associated with mature adipocytes compared to their precursors. Indeed, similar to what was observed in human clinical studies, the differentiated adipocytes demonstrated increased lactate production. However, the differentiated adipocytes compared to their precursors (preadipocytes or ASCs) demonstrate an aerobic glycolysis-like (also called Warburg effect-like) increase in glycolysis characterized by a 5.2 fold increase in lactate production in normoxic conditions (atmospheric oxygen tension). Remarkably, this increase in lactate occurred even though the differentiated adipocytes simultaneously demonstrate an increase in oxidative capacity. This low fraction of oxidative capacity coupled with increased lactate production indicated regulation of oxidative rates most likely at the point of pyruvate conversion to either acetyl-CoA (oxidative metabolism) or lactate (glycolytic metabolism). To investigate the potential regulation of this metabolic phenotype, PDK isoform expression was assessed and we found PDK 1 and 4 transcript and protein elevated in the differentiated cells. Non-selective pharmacologic inhibition of the PDKs resulted in decreased lactate production, supporting a regulatory role for PDK in modulation of the observed Warburg effect. PDK inhibition also resulted in increased ROS production in the adipocytes after several hours of treatment and a decrease in cell viability when PDK inhibition was carried out over 36 hours. The resulting loss in viability could be rescued by antioxidant (Tempol) treatment, indicating the decrease in viability was ROS mediated. Similar to what is seen in cancer cells, our data demonstrate that differentiation of human adipocytes is accompanied by a PDK-dependent increase in glycolytic metabolism (Warburg effect) that not only leads to lactate production, but also seems to protect the cells from increased and detrimental generation of ROS.
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    Succinate dehydrogenase-complex II regulates skeletal muscle cellular respiration and contractility but not muscle mass in genetically induced pulmonary emphysema
    (American Association for the Advancement of Science, 2024) Balnis, Joseph; Tufts, Ankita; Jackson, Emily L.; Drake, Lisa A.; Singer, Diane V.; Lacomis, David; Lee, Chun Geun; Elias, Jack A.; Doles, Jason D.; Maher, L. James, III; Jen, Annie; Coon, Joshua J.; Jourd’heuil, David; Singer, Harold A.; Vincent, Catherine E.; Jaitovich, Ariel; Anatomy, Cell Biology and Physiology, School of Medicine
    Reduced skeletal muscle mass and oxidative capacity coexist in patients with pulmonary emphysema and are independently associated with higher mortality. If reduced cellular respiration contributes to muscle atrophy in that setting remains unknown. Using a mouse with genetically induced pulmonary emphysema that recapitulates muscle dysfunction, we found that reduced activity of succinate dehydrogenase (SDH) is a hallmark of its myopathic changes. We generated an inducible, muscle-specific SDH knockout mouse that demonstrates lower mitochondrial oxygen consumption, myofiber contractility, and exercise endurance. Respirometry analyses show that in vitro complex I respiration is unaffected by loss of SDH subunit C in muscle mitochondria, which is consistent with the pulmonary emphysema animal data. SDH knockout initially causes succinate accumulation associated with a down-regulated transcriptome but modest proteome effects. Muscle mass, myofiber type composition, and overall body mass constituents remain unaltered in the transgenic mice. Thus, while SDH regulates myofiber respiration in experimental pulmonary emphysema, it does not control muscle mass or other body constituents.
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    Sulfotransferase 1C2 Increases Mitochondrial Respiration by Converting Mitochondrial Membrane Cholesterol to Cholesterol Sulfate
    (American Chemical Society, 2024) Kolb, Alexander J.; Corridon, Peter; Ullah, Mahbub; Pfaffenberger, Zechariah J.; Xu, Wei Min; Winfree, Seth; Sandoval, Ruben H.; Hato, Takeshi; Witzmann, Frank A.; Mohallem, Rodrigo; Franco, Jackeline; Aryal, Uma K.; Atkinson, Simon J.; Basile, David P.; Bacallao, Robert L.; Biology, School of Science
    Hypothesis: In this communication, we test the hypothesis that sulfotransferase 1C2 (SULT1C2, UniProt accession no. Q9WUW8) can modulate mitochondrial respiration by increasing state-III respiration. Methods and results: Using freshly isolated mitochondria, the addition of SULT1C2 and 3-phosphoadenosine 5 phosphosulfate (PAPS) results in an increased maximal respiratory capacity in response to the addition of succinate, ADP, and rotenone. Lipidomics and thin-layer chromatography of mitochondria treated with SULT1C2 and PAPS showed an increase in the level of cholesterol sulfate. Notably, adding cholesterol sulfate at nanomolar concentration to freshly isolated mitochondria also increases maximal respiratory capacity. In vivo studies utilizing gene delivery of SULT1C2 expression plasmids to kidneys result in increased mitochondrial membrane potential and confer resistance to ischemia/reperfusion injury. Mitochondria isolated from gene-transduced kidneys have elevated state-III respiration as compared with controls, thereby recapitulating results obtained with mitochondrial fractions treated with SULT1C2 and PAPS. Conclusion: SULT1C2 increases mitochondrial respiratory capacity by modifying cholesterol, resulting in increased membrane potential and maximal respiratory capacity. This finding uncovers a unique role of SULT1C2 in cellular physiology and extends the role of sulfotransferases in modulating cellular metabolism.