Parkinson’s disease (PD) is a progressive neurodegenerative disease that causes a debilitating movement disorder. While most cases of PD appear to be sporadic, rare Mendelian forms have provided tremendous insight into disease pathogenesis. Accumulating evidence suggests that impaired mitochondria underpin PD pathology. In support of this theory, data from multiple PD models has linked PINK1 and parkin, two recessive PD genes, in a common pathway impacting mitochondrial health, prompting a flurry of research to identify their mitochondrial targets. Recent work has focused on the role of PINK1 and parkin in mediating mitochondrial autophagy (mitophagy), however, emerging evidence casts parkin and PINK1 as key players in multiple domains of mitochondrial health and quality control.
Excessive poly(ADP-ribose) (PAR) polymerase-1 (PARP-1) activation kills cells via a cell-death process designated "parthanatos" in which PAR induces the mitochondrial release and nuclear translocation of apoptosis-inducing factor to initiate chromatinolysis and cell death. Accompanying the formation of PAR are the reduction of cellular NAD + and energetic collapse, which have been thought to be caused by the consumption of cellular NAD + by PARP-1. Here we show that the bioenergetic collapse following PARP-1 activation is not dependent on NAD + depletion. Instead PARP-1 activation initiates glycolytic defects via PAR-dependent inhibition of hexokinase, which precedes the NAD + depletion in N-methyl-N-nitroso-N-nitroguanidine (MNNG)-treated cortical neurons. Mitochondrial defects are observed shortly after PARP-1 activation and are mediated largely through defective glycolysis, because supplementation of the mitochondrial substrates pyruvate and glutamine reverse the PARP-1-mediated mitochondrial dysfunction. Depleting neurons of NAD + with FK866, a highly specific noncompetitive inhibitor of nicotinamide phosphoribosyltransferase, does not alter glycolysis or mitochondrial function. Hexokinase, the first regulatory enzyme to initiate glycolysis by converting glucose to glucose-6-phosphate, contains a strong PAR-binding motif. PAR binds to hexokinase and inhibits hexokinase activity in MNNG-treated cortical neurons. Preventing PAR formation with PAR glycohydrolase prevents the PAR-dependent inhibition of hexokinase. These results indicate that bioenergetic collapse induced by overactivation of PARP-1 is caused by PAR-dependent inhibition of glycolysis through inhibition of hexokinase.
Mutations in parkin lead to early-onset autosomal recessive Parkinson's disease (PD) and inactivation of parkin is thought to contribute to sporadic PD. Adult knockout of parkin in the ventral midbrain of mice leads to an age-dependent loss of dopamine neurons that is dependent on the accumulation of parkin interacting substrate (PARIS), zinc finger protein 746 (ZNF746), and its transcriptional repression of PGC-1α. Here we show that adult knockout of parkin in mouse ventral midbrain leads to decreases in mitochondrial size, number, and protein markers consistent with a defect in mitochondrial biogenesis. This decrease in mitochondrial mass is prevented by short hairpin RNA knockdown of PARIS. PARIS overexpression in mouse ventral midbrain leads to decreases in mitochondrial number and protein markers and PGC-1α-dependent deficits in mitochondrial respiration. Taken together, these results suggest that parkin loss impairs mitochondrial biogenesis, leading to declining function of the mitochondrial pool and cell death. Recently, the parkin interacting substrate (PARIS) also known as zinc finger protein 746 (ZNF746) was shown to be required for loss of DA neurons in adult conditional parkin knockout (KO) mice (19). PARIS is polyubiquitinated by parkin via lysine-48 targeting it for ubiquitin proteasomal degradation. Deletion of parkin in adult mice leads to an age-dependent progressive loss of DA neurons that is due to the accumulation of PARIS because depletion of PARIS in adult conditional parkin knockout mice prevents the loss of DA neurons (19). PARIS is a transcriptional repressor that regulates the expression of peroxisome proliferator-activated receptor gamma, coactivator 1α (PGC-1α), a master coregulator of mitochondrial function, biogenesis, and mitochondrial oxidative stress management (19,20). In adult conditional parkin knockout mice, there is a reduction in PGC-1α levels that is dependent on PARIS because reduction in PARIS reverses the reduction in PGC-1α levels (19). PARIS overexpression, at levels equivalent to those in the adult conditional parkin knockout mice, also leads to defects in PGC-1α and causes the selective loss of DA neurons (19). PGC-1α overexpression prevents the defects in PGC-1α signaling and the loss of DA neurons, suggesting that PARIS kills DA neurons in a PGC-1α-dependent fashion (19).Because PGC-1α is a master coregulator of mitochondrial function and mitochondrial defects are a consistent feature of PD, mitochondria were assessed in the adult conditional parkin knockout mice. Here we show that adult conditional knockout of parkin leads to reductions in mitochondrial mass that are dependent upon PARIS. Moreover, PARIS accumulation leads to substantial deficits in mitochondrial respiration that are PGC-1α dependent. Our findings are consistent with parkin regulation of mitochondrial biogenesis. ResultsReduced Mitochondrial Size and Number in Adult Conditional Parkin Knockouts. Adult conditional parkin knockout mice were generated as previously described by injecting a lentiviru...
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