Cultured human skin keloid fibroblasts (KFs) showed bioenergetics similar to cancer cells in generating ATP mainly from glycolysis as demonstrated by increased lactate production. Activities of hexokinase, glyceraldehyde-3-phosphate dehydrogenase, and lactate dehydrogenase were also significantly higher compared with normal fibroblasts (NFs). Inhibitors of glycolysis decreased the rate of ATP biosynthesis more significantly in KFs suggesting their reliance on glycolysis. In contrast, ATP generation in NFs was derived mainly from oxidative phosphorylation (OXPHOS), which was more compromised by mitochondrial/respiratory inhibitors. However, when fortified with excess exogenous respiratory substrates, ATP production was increased to a similar maximal level in both types of fibroblasts. In spite of this seemingly equal total capacity, ATP biosynthesis and intracellular ATP concentration were significantly higher in KFs, which further increased their ATP production when exposed to hypoxia and hypoxia-mimetics: desferrioxamine and cobalt chloride. This upregulation was again significantly compromised by glycolytic inhibitors. The rate of generation of reactive oxygen species was lower in KFs possibly due to their switch to aerobic glycolysis from mitochondrial OXPHOS. Thus, cultured skin KFs could provide a human cell model to study the de-regulation of bioenergetics of proliferative cells and their response to the HIF (hypoxia-inducible factor) signaling.
Exposure of Neuro-2a and PC12 cells to micromolar concentrations of sulfite caused an increase in reactive oxygen species and a decrease in ATP. Likewise, the biosynthesis of ATP in intact rat brain mitochondria from the oxidation of glutamate was inhibited by micromolar sulfite. Glutamate-driven respiration increased the mitochondrial membrane potential (MMP), and this was abolished by sulfite but the MMP generated by oxidation of malate and succinate was not affected. The increased rate of production of NADH from exogenous NAD ؉ and glutamate added to rat brain mitochondrial extracts was inhibited by sulfite, and mitochondria preincubated with sulfite failed to reduce NAD ؉ . Glutamate dehydrogenase (GDH) in rat brain mitochondrial extract was inhibited dose-dependently by sulfite as was the activity of a purified enzyme. An increase in the K m (glutamate) and a decrease in V max resulting in an attenuation in V max /K m (glutamate) at 100 M sulfite suggest a mixed type of inhibition. However, uncompetitive inhibition was noted with decreases in both K m (NAD ؉ ) and V max , whereas V max /K m (NAD ؉ ) remained relatively constant. We propose that GDH is one target of action of sulfite, leading to a decrease in ␣-ketoglutarate and a diminished flux through the tricarboxylic acid cycle accompanied by a decrease in NADH through the mitochondrial electron transport chain, a decreased MMP, and a decrease in ATP synthesis. Because glutamate is a major metabolite in the brain, inhibition of GDH by sulfite could contribute to the severe phenotype of sulfite oxidase deficiency in human infants.
Micromolar sulfite elicited an immediate increase in ROS in MDCK, type II, and OK cells. This was accompanied by a depletion of intracellular ATP, which could be explained by its inhibitory effect on mitochondrial GDH. Although MDH was similarly inhibited, the impact was buffered by the high level of this enzyme in kidney mitochondria.
Highlights
APB are phylogenetically and metabolically diverse, includes many extremophiles.
Ability to harvest IR light and use of many inorganic electron donors useful.
Electricity, polymers, fertilizers, feed, antioxidants and pigments recoverable.
Purple non-sulfur bacteria well studied, have wide range of applications.
Metabolic engineering key to improving productivity and metabolic traits.
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