Jeff Blackinton

DJ-1 acts in parallel to the PINK1/parkin pathway to control mitochondrial function and autophagy

Mutations in DJ-1, PINK1 (PTEN-induced putative kinase 1) and parkin all cause recessive parkinsonism in humans, but the relationships between these genes are not clearly defined. One event associated with loss of any of these genes is altered mitochondrial function. Recent evidence suggests that turnover of damaged mitochondria by autophagy might be central to the process of recessive parkinsonism. Here, we show that loss of DJ-1 leads to loss of mitochondrial polarization, fragmentation of mitochondria and accumulation of markers of autophagy (LC3 punctae and lipidation) around mitochondria in human dopaminergic cells. These effects are due to endogenous oxidative stress, as antioxidants will reverse all of them. Similar to PINK1 and parkin, DJ-1 also limits mitochondrial fragmentation in response to the mitochondrial toxin rotenone. Furthermore, overexpressed parkin will protect against loss of DJ-1 and, although DJ-1 does not alter PINK1 mitochondrial phenotypes, DJ-1 is still active against rotenone-induced damage in the absence of PINK1. None of the three proteins complex together using size exclusion chromatography. These data suggest that DJ-1 works in parallel to the PINK1/parkin pathway to maintain mitochondrial function in the presence of an oxidative environment.

Formation of a stabilized cysteine sulfinic acid is critical for the mitochondrial function of the parkinsonism protein DJ-1.

The formation of cysteine-sulfinic acid has recently become appreciated as a modification that links protein function to cellular oxidative status. Human DJ-1, a protein associated with inherited parkinsonism, readily forms cysteine-sulfinic acid at a conserved cysteine residue (Cys106 in human DJ-1). Mutation of Cys106 causes the protein to lose its normal protective function in cell culture and model organisms. However, it is unknown whether the loss of DJ-1 protective function in these mutants is due to the absence of Cys106 oxidation or the absence of the cysteine residue itself. To address this question, we designed a series of substitutions at a proximal glutamic acid residue (Glu18) in human DJ-1 that alter the oxidative propensity of Cys106 through changes in hydrogen bonding. We show that two mutations, E18N and E18Q, allow Cys106 to be oxidized to Cys106-sulfinic acid under mild conditions. In contrast, the E18D mutation stabilizes a cysteine-sulfenic acid that is readily reduced to the thiol in solution and in vivo. We show that E18N and E18Q can both partially substitute for wild-type DJ-1 using mitochondrial fission and cell viability assays. In contrast, the oxidatively impaired E18D mutant behaves as an inactive C106A mutant and fails to protect cells. We therefore conclude that formation of Cys106-sulfinic acid is a key modification that regulates the protective function of DJ-1.

RNA binding activity of the recessive parkinsonism protein DJ-1 supports involvement in multiple cellular pathways

Parkinsons disease (PD) is a major neurodegenerative condition with several rare Mendelian forms. Oxidative stress and mitochondrial function have been implicated in the pathogenesis of PD but the molecular mechanisms involved in the degeneration of neurons remain unclear. DJ-1 mutations are one cause of recessive parkinsonism, but this gene is also reported to be involved in cancer by promoting Ras signaling and suppressing PTEN-induced apoptosis. The specific function of DJ-1 is unknown, although it is responsive to oxidative stress and may play a role in the maintenance of mitochondria. Here, we show, using four independent methods, that DJ-1 associates with RNA targets in cells and the brain, including mitochondrial genes, genes involved in glutathione metabolism, and members of the PTEN/PI3K cascade. Pathogenic recessive mutants are deficient in this activity. We show that DJ-1 is sufficient for RNA binding at nanomolar concentrations. Further, we show that DJ-1 binds RNA but dissociates after oxidative stress. These data implicate a single mechanism for the pleiotropic effects of DJ-1 in different model systems, namely that the protein binds multiple RNA targets in an oxidation-dependent manner.

Post-transcriptional regulation of mRNA associated with DJ-1 in Sporadic Parkinson disease

Mutations in DJ-1 lead to a monogenic form of early onset recessive parkinsonism. DJ-1 can respond to oxidative stress, which has been proposed to be involved in the pathogenesis of sporadic Parkinson disease (PD). We have recently reported that DJ-1 interacts with mRNA in an oxidation-dependent manner. Here, we confirm interaction of DJ-1 and RNA in human brain using immunoprecipitation followed by quantitative real time PCR. We confirmed previous reports that DJ-1 is more oxidized in cortex from cases of sporadic PD compared to controls. In the same samples, protein and RNA expression was measured for four DJ-1 target genes GPx4, MAPK8IP1, ND2 and ND5. While no alterations in mRNA expression were observed, an increase in protein expression was observed in PD cases for GPx4 and MAPK8IP1. In the same patients, we saw decreased mRNA and protein levels of two mitochondrial targets, ND2 and ND5. These results suggest that these proteins undergo regulation at the post-transcriptional level that may involve translational regulation by DJ-1.

Expression of PINK1 mRNA in human and rodent brain and in Parkinson's disease

Mutations in PINK1 (PTEN-induced putative kinase 1) are causal for early onset recessive parkinsonism in humans, characterized by damage to the nigrostriatal system. In situ hybridization studies in rodent brains have suggested a predominantly neuronal expression of PINK1 mRNA but immunocytochemistry of human brain tissue has shown PINK1-like immunoreactivity in both neurons and glia. In this study, we assessed the comparative distribution of PINK1 mRNA in human, rat and mouse brain. We observe that in humans PINK1 message is expressed in neurons with very little to no signal in glia and confirms similar findings in rodent tissue. Highest levels of expression were observed in hippocampus, substantia nigra and cerebellar Purkinje cells. We also show that PINK1 mRNA expression is similar in nigral neurons from neurologically normal controls and sporadic Parkinsons disease cases.

DJ-1 Mutations are Rare in a Swedish Parkinson Cohort

Mutations in the PARK7 gene, DJ-1, have been reported to cause early-onset and familial Parkinson’s disease (PD). The function of DJ-1 and how it contributes to the development of the disease is not clear today, but several studies report that DJ-1 is responsive to oxidative stress and important for the maintenance of mitochondria. We have screened three coding regions of DJ-1 (exon 2, 5 and 7) in a Swedish Parkinson cohort. The Swedish PD material consisted of 67 patients with a self reported positive family history of PD and 77 patients with early-onset of disease (≤50 years old). We detected two patients with the previously reported synonymous mutation, Ala167Ala (c.501A>G, rs71653621), in exon 7. No Ala167Ala carriers were identified among 213 neurologically healthy Swedish controls. Mechanisms by which the synonymous Ala167Ala mutation can have consequences are unknown. It may affect the mRNA stability, secondary structure of mRNA, synthesis, turnover, protein folding and function. We could show a 1.3% decrease in DJ-1 mRNA folding energy in the A<G substituted sequence compared to the wild type sequence in silico, suggesting a possible small effect of Ala167Ala on DJ-1 gene function. This is the first report on an identified DJ-1 mutation in Swedish PD patients. Our results, in combination with those of previous studies, strengthen the hypothesis that alterations in DJ-1 are not a common cause of familial and early-onset PD world-wide.

Identification of the epitope of a monoclonal antibody to DJ-1.

Mutations in DJ-1 can cause early onset parkinsonism. Various antibodies have been generated to detect this protein, one of which is a commonly used monoclonal antibody (clone 3E8). Since results of in situ examinations of DJ-1 expression with this antibody have differed from analyses with species-specific antibodies (e.g. rat), it would be useful to know the epitope for this antibody. Using GFP-tagged deletion constructs of human DJ-1, we have localized the epitope region for this antibody to within residues 56-78 of human DJ-1. Mapping this region to the published three-dimensional structure of DJ-1 indicates that this is a solvent-accessible surface epitope. Immunonegativity of E64D mutant DJ-1 with the monoclonal antibody suggests that glutamate 64 of human DJ-1 contributes to the epitope recognized by this antibody. Moreover, the loss of immunoreactivity due to such a small substitution demonstrates the remarkable sensitivity of the monoclonal antibody 3E8 to DJ-1.