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INTRODUCTION: Pyruvate Dehydrogenase Complex (PDC) is a pivotal gatekeeper between cytosolic glycolysis and mitochondrial oxidative phosphorylation, playing important role in aerobic energy metabolism. Most PDC deficiency, cases being caused by mutations in PDHA1 encoding the α subunit of the rate-limiting E1 enzyme, which is characterized by abnormal phenotypes caused by energy deprivation at peripheral/central nervous systems and muscular tissues. This study aims to evaluate the potential therapeutic effect of arginine and thiamine in ameliorating mitochondrial function in patient-derived cultured cells. MATERIALS AND METHODS: PDC-deficient cell lines, carrying three different PDHA1 variants, were cultured in the absence and presence of arginine and/or thiamine at therapeutical levels, 4 mM and 100 µM, respectively. Mitochondrial bioenergetics profile was evaluated using the Seahorse extracellular flux analyzer. RESULTS: In physiological conditions, control cells presented standard values for all parameters evaluating the mitochondrial function, no differences being observed after supplementation of culture medium with therapeutic levels of arginine and/or thiamine. However, PDC-PDHA1 deficient cell lines consumed less oxygen than the control cells, but arginine and thiamine supplementation increased the basal respiration for values similar or higher than the control cell line. Moreover, arginine and thiamine treatment highlighted an inefficient oxidative phosphorylation carried out by PDC-deficient cell lines. Finally, this treatment showed an increased oxygen consumption by enzymes other than those in the respiratory chain, thus proving the dependence of these mutant cell lines on cytosolic sources for ATP production, namely glycolysis. CONCLUSIONS: This study showed that arginine and thiamine, at therapeutical levels, increase the basal oxygen consumption rate of PDC-deficient cell lines, as well as their ATP-linked respiration. This parameter measures the capacity of the cell to meet its energetic demands and, therefore, its increase reveals a higher electron flow through the respiratory chain, which is coupled to elevated oxidative phosphorylation, thus indicating an overall increased robustness in mitochondrial- related bioenergetics.
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BACKGROUND: The pyruvate dehydrogenase complex (PDC) catalyzes the irreversible decarboxylation of pyruvate into acetyl-CoA. PDC deficiency can be caused by alterations in any of the genes encoding its several subunits. The resulting phenotype, though very heterogeneous, mainly affects the central nervous system. The aim of this study is to describe and discuss the clinical, biochemical and genotypic information from thirteen PDC deficient patients, thus seeking to establish possible genotype-phenotype correlations. RESULTS: The mutational spectrum showed that seven patients carry mutations in the PDHA1 gene encoding the E1α subunit, five patients carry mutations in the PDHX gene encoding the E3 binding protein, and the remaining patient carries mutations in the DLD gene encoding the E3 subunit. These data corroborate earlier reports describing PDHA1 mutations as the predominant cause of PDC deficiency but also reveal a notable prevalence of PDHX mutations among Portuguese patients, most of them carrying what seems to be a private mutation (p.R284X). The biochemical analyses revealed high lactate and pyruvate plasma levels whereas the lactate/pyruvate ratio was below 16; enzymatic activities, when compared to control values, indicated to be independent from the genotype and ranged from 8.5% to 30%, the latter being considered a cut-off value for primary PDC deficiency. Concerning the clinical features, all patients displayed psychomotor retardation/developmental delay, the severity of which seems to correlate with the type and localization of the mutation carried by the patient. The therapeutic options essentially include the administration of a ketogenic diet and supplementation with thiamine, although arginine aspartate intake revealed to be beneficial in some patients. Moreover, in silico analysis of the missense mutations present in this PDC deficient population allowed to envisage the molecular mechanism underlying these pathogenic variants. CONCLUSION: The identification of the disease-causing mutations, together with the functional and structural characterization of the mutant protein variants, allow to obtain an insight on the severity of the clinical phenotype and the selection of the most appropriate therapy.