Activators of alpha synuclein expression identified by reporter cell line-based high throughput drug screen.

Multiplications, mutations and dysregulation of the alpha synuclein gene (SNCA) are associated with the demise of dopaminergic neurons and are considered to play important roles in the pathogenesis of familial and sporadic forms of Parkinson's disease. Regulation of SNCA expression might thus be an appropriate target for treatment. We aimed to identify specific modulators of SNCA transcription, generated CRISPR/Cas9 modified SNCA-GFP-luciferase (LUC) genomic fusion- and control cell lines and screened a library of 1649 bioactive compounds, including the FDA approved drugs. We found no inhibitors but three selective activators which increased SNCA mRNA and protein levels.

DJ-1 is a redox sensitive adapter protein for high molecular weight complexes involved in regulation of catecholamine homeostasis.

DJ-1 is an oxidation sensitive protein encoded by the PARK7 gene. Mutations in PARK7 are a rare cause of familial recessive Parkinson's disease (PD), but growing evidence suggests involvement of DJ-1 in idiopathic PD. The key clinical features of PD, rigidity and bradykinesia, result from neurotransmitter imbalance, particularly the catecholamines dopamine (DA) and noradrenaline. We report in human brain and human SH-SY5Y neuroblastoma cell lines that DJ-1 predominantly forms high molecular weight (HMW) complexes that included RNA metabolism proteins hnRNPA1 and PABP1 and the glycolysis enzyme GAPDH. In cell culture models the oxidation status of DJ-1 determined the specific complex composition. RNA sequencing indicated that oxidative changes to DJ-1 were concomitant with changes in mRNA transcripts mainly involved in catecholamine metabolism. Importantly, loss of DJ-1 function upon knock down (KD) or expression of the PD associated form L166P resulted in the absence of HMW DJ-1 complexes. In the KD model, the absence of DJ-1 complexes was accompanied by impairment in catecholamine homeostasis, with significant increases in intracellular DA and noraderenaline levels. These changes in catecholamines could be rescued by re-expression of DJ-1. This catecholamine imbalance may contribute to the particular vulnerability of dopaminergic and noradrenergic neurons to neurodegeneration in PARK7-related PD. Notably, oxidised DJ-1 was significantly decreased in idiopathic PD brain, suggesting altered complex function may also play a role in the more common sporadic form of the disease.

DNA methylation in Parkinson's disease.

Epigenetic processes control the embryonic development into multicellular organisms and determine the functional differences of genetically identical cells and individuals. They are also involved in a variety of complex functions such as learning and memory consolidation and have been implicated in aging processes. Beyond the actual genetic information encoded in the DNA sequence, epigenetic modifications in particular DNA methylation and various histone modifications shape the chromatin into a transcriptional permissive or repressive state. DNA methylation patterns are altered by environmental conditions and can be carried forward through mitosis and meiosis. Hence, DNA methylation probably mediates complex environment-gene interactions, determines individual disease characteristics, and contributes to effects and side effects of drugs. In addition to classic monogenic epigenetic diseases, i.e., Prader-Willi and Rett syndrome, recent data point to an epigenetic component also in apparent sporadic neuro-psychiatric disorders and increasing evidence suggests a role for altered DNA methylation in Parkinson's disease. Epigenetic alterations, DNA methylation in particular, may account for the yet unexplained individual susceptibility and the variability in the course of Parkinson's disease and could provide hints toward the development of novel therapeutic targets. Parkinson's disease (PD) is conceptualized as a consequence of genetic variants and environment-gene interactions on a background of age-related changes. Epigenetic modifications have been implicated in aging and can be altered by environment stimuli. The review explores the possibility of an epigenetic component in PD, focusing on DNA methylation. Methylation of α-synuclein (SNCA) and microtubule-associated protein tau gene appear to be of particular importance and epigenome-wide methylation studies point to several additional candidate genes which may contribute to the individual susceptibility toward PD. This article is part of a special issue on Parkinson disease.

DNA methylation levels of α-synuclein intron 1 in the aging brain.

DNA methylation patterns change with age, and aging itself is a major confounding risk factor for Parkinson's disease (PD). Duplication and triplication, that is, increased expression of the α-synuclein (SNCA) gene, cause familial PD, and demethylation of SNCA intron 1 has been shown to result in increased expression of SNCA. We thus hypothesized that age-related alterations of SNCA methylation might underly the increased susceptibility toward PD in later life. The present study sought to determine (1) whether alterations of SNCA intron 1 methylation occurred during aging, (2) whether the methylation pattern differed between men and women, and (3) whether purified neurons compared with non-neuronal cells exhibited different methylation patterns. The analysis of DNA from brain tissue and fluorescence activated cell sorting-sorted purified neurons of 41 individuals revealed only a minor increase of SNCA intron 1 DNA methylation levels in presumably healthy individuals during aging but no significant difference between men and women. Interestingly enough, methylation of SNCA intron 1 was higher in neurons compared with non-neuronal cells, although non-neuronal cells express lower levels of SNCA. Therefore, the normal pattern of SNCA methylation during aging should not result in increased expression of α-synuclein protein. It is thus likely that additional, yet not identified, mechanisms contribute to the tissue specificity of SNCA expression and the presumed dysregulation in PD.

Zebrafish brain proteomics reveals central proteins involved in neurodegeneration.

Understanding the complex biology of the brain requires analyzing its structural and functional complexity at the protein level. The large-scale analysis of the brain proteome, coupled with characterization of central brain proteins, provides insight into fundamental brain processes and processes linked to neurodegenerative diseases. Here we provide a map of the zebrafish brain proteome by using two-dimensional gel electrophoresis (2DE), followed by the identification of 95 brain proteins using mass spectrometry (LC-ESI MS/MS). Our data show extensive phosphorylation of brain proteins but less prominent glycosylation. Furthermore, ~51% of the identified proteins are predicted to have one or more ubiquitination sites whereas ~90% are predicted to have one or more SUMOylation sites. Our findings provide a valuable proteome map of the zebrafish brain and associated posttranslational modifications demonstrating that zebrafish proteomic approaches can aid in our understanding of proteins central to important neuronal processes and those associated with neurodegenerative disorders.

Parkinson disease protein DJ-1 binds metals and protects against metal-induced cytotoxicity.

The progressive loss of motor control due to reduction of dopamine-producing neurons in the substantia nigra pars compacta and decreased striatal dopamine levels are the classically described features of Parkinson disease (PD). Neuronal damage also progresses to other regions of the brain, and additional non-motor dysfunctions are common. Accumulation of environmental toxins, such as pesticides and metals, are suggested risk factors for the development of typical late onset PD, although genetic factors seem to be substantial in early onset cases. Mutations of DJ-1 are known to cause a form of recessive early onset Parkinson disease, highlighting an important functional role for DJ-1 in early disease prevention. This study identifies human DJ-1 as a metal-binding protein able to evidently bind copper as well as toxic mercury ions in vitro. The study further characterizes the cytoprotective function of DJ-1 and PD-mutated variants of DJ-1 with respect to induced metal cytotoxicity. The results show that expression of DJ-1 enhances the cells' protective mechanisms against induced metal toxicity and that this protection is lost for DJ-1 PD mutations A104T and D149A. The study also shows that oxidation site-mutated DJ-1 C106A retains its ability to protect cells. We also show that concomitant addition of dopamine exposure sensitizes cells to metal-induced cytotoxicity. We also confirm that redox-active dopamine adducts enhance metal-catalyzed oxidation of intracellular proteins in vivo by use of live cell imaging of redox-sensitive S3roGFP. The study indicates that even a small genetic alteration can sensitize cells to metal-induced cell death, a finding that may revive the interest in exogenous factors in the etiology of PD.