Levels of Coenzyme Q10 and Several COQ Proteins in Human Astrocytoma Tissues Are Inversely Correlated with Malignancy.

In a previous study, we reported the alterations of primary antioxidant enzymes and decreased citrate synthase (CS) activities in different grades of human astrocytoma tissues. Here, we further investigated coenzyme Q10 (CoQ10) levels and protein levels of polyprenyl diphosphate synthase subunit (PDSS2) and several COQ proteins required for CoQ10 biosynthesis in these tissues. We found that the level of endogenous CoQ10, but not of exogenous α-tocopherol, was higher in nontumor controls than in all grades of astrocytoma tissues. The levels of COQ3, COQ5, COQ6, COQ7, COQ8A, and COQ9, but not of COQ4, were lower in Grade IV astrocytoma tissues than in controls or low-grade (Grades I and II) astrocytomas, but PDSS2 levels were higher in astrocytoma tissues than in controls. Correlation analysis revealed that the levels of CoQ10 and COQ proteins were negatively correlated with malignancy degree and positively correlated with CS activity, whereas PDSS2 level was positively correlated with malignancy. Moreover, lower level of mitochondrial DNA-encoded cytochrome c oxidase subunit 2 was not only associated with a higher malignancy degree but also with lower level of all COQ proteins detected. The results revealed that mitochondrial abnormalities are associated with impaired CoQ10 maintenance in human astrocytoma progression.

Characterization of human mitochondrial PDSS and COQ proteins and their roles in maintaining coenzyme Q10 levels and each other's stability.

Mutations of many PDSS and COQ genes are associated with primary coenzyme Q10 (CoQ10) deficiency, whereas mitochondrial DNA (mtDNA) mutations might cause secondary CoQ10 deficiency. Previously, we found that COQ5 and COQ9 proteins are present in different protein complexes in the mitochondria in human 143B cells and demonstrated that COQ5 and COQ9 knockdown suppresses CoQ10 levels. In the present study, we characterized other PDSS and COQ proteins and examined possible crosstalk among various PDSS and COQ proteins. Specific antibodies and mitochondrial localization of mature proteins for these proteins, except PDSS1 and COQ2, were identified. Multiple isoforms of PDSS2 and COQ3 were observed. Moreover, PDSS1, PDSS2, and COQ3 played more important roles in maintaining the stability of the other proteins. Protein complexes containing PDSS2, COQ3, COQ4, COQ6, or COQ7 protein in the mitochondria were detected. Two distinct PDSS2-containing protein complexes could be identified. Transient knockdown of these genes, except COQ6 and COQ8, decreased CoQ10 levels, but only COQ7 knockdown hampered mitochondrial respiration and caused increased ubiquinol:ubiquinone ratios and accumulation of a putative biosynthetic intermediate with reversible redox property as CoQ10. Furthermore, suppressed levels of PDSS2 and various COQ proteins (except COQ3 and COQ8A) were found in cybrids containing the pathogenic mtDNA A8344G mutation or in FCCP-treated 143B cells, which was similar to our previous findings for COQ5. These novel findings may prompt the elucidation of the putative CoQ synthome in human cells and the understanding of these PDSS and COQ protein under physiological and pathological conditions.