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Project

Neuropathological and functional characterization of the therapeutic effect of parkin in animal models of Parkinson's disease.

Parkinsons disease (PD) is the most common neurodegenerative movement disorder. It is neuropathologically characterized by a progressive degeneration of dopaminergic neurons in the substantia nigra (SN) and the presence of intracellular </>α</>-synuclein (</>α</>-SYN) containing inclusions called Lewy bodies. Although the etiology of PD is still incompletely understood, the discovery of genes linked to familial PD has tremendously improved our knowledge on the molecular mechanisms involved in the pathogenesis of familial as well as sporadic PD, since both forms share clinical and neuropathological features. </>
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Mutations in the parkin gene cause early-onset autosomal recessive PD. The parkin protein functions as an E3-ubiquitin ligase and is involved in a wide range of cellular functions including the ubiquitin-proteasome system, mitochondrial quality control and activation of signal transduction cascades. O</>verexpression of parkin in cell culture and in vivo</> has been reported to have a neuroprotective effect against a variety of genetic and toxic insults. Furthermore, there is also evidence that inactivation of parkin by oxidative, nitrosative and dopamine stress may playa role in sporadic PD. These data suggest that parkin has a therapeuticpotential for the treatment of not only familial but also sporadic PD. However, the mechanism-of-action underlying the neuroprotective capacityof parkin and more in general the in vivo</> function of parkin and howparkin mutations lead to the development of PD has not yet been completely elucidated.</>
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First, we aimed to further validate the therapeutic effect of parkin in an A53T α-SYN rAAV2/7 genetic rat model of PD that was recently developed in our lab. </>Point mutationsand multiplications of α-SYN cause a rare familial autosomal dominant form of PD and a fibrillar form of </>α</>-SYN is the main protein component of Lewy bodies, which makes </>α</>-SYN a key proteinin PD pathogenesis. </>The neuroprotective capacity of parkin has previously been shown by our research group using lentiviral vectors in a PD model based on the neurotoxin 6-OHDA. Since recombinant adeno-associatedviral (rAAV) vectors have a better tropism and specificity for dopaminergic neurons in vivo</> than lentiviral vectors, we expected that overexpression of parkin with rAAV vectors would improve the neuroprotective activity of parkin. However, despite several optimizations of the experimental conditions, we did not observe a neuroprotective capacity of parkin in this α-SYN rat model. </>
Clinical parkin mutations are most probably loss-of-function mutations. Therefore, in a second part of this thesis, we aimed to explore the effect of parkin deficiency on the survival of dopaminergic neurons in rodents, in an attempt to increase ourunderstanding of the processes leading to dopaminergic cell death in parkin-associated PD patients. Parkin knockout mice fail to recapitulate dopaminergic degeneration, which might be explained by compensatory adaptations. Therefore, in a first strategy, we hypothesized that acute downregulation of parkin in the dopaminergic neurons of adult brain, might overcome these compensatory issues and induce a more pronounced phenotype.We achieved acute, locoregional knockdown of parkin in the SN of adult rats by injection of a rAAV vector coding for a functional micro-RNA based short hairpin sequence directed against rat parkin. However, this didnot result in motor deficits or a clear dopaminergic cell death. </>
In a second strategy to mimic the situation in humans, we overexpressedthe T240R clinical parkin mutant in the SN of adult rodents. </>Cell culture studies and Drosophila</> studies have put forward a dominant negative effect for the T240R-parkin mutant. We aimed to translate those findings to the rodent brain and </>overexpressed T240R-parkin and human wild type parkin as a control in the dopaminergic neurons of adult rats using rAAV vectors. Surprisingly, </>we found that overexpression of not only T240R-parkin but also human wild type parkin induced a progressive and dose-dependent dopaminergic cell death in rats. This degeneration wasspecific for parkin, since similar overexpression of eGFP did not lead to nigral degeneration. These results warrant caution to the developmentof therapeutic strategies for PD based on overexpression of parkin or enhancing parkin activity, since this might be deleterious at long-term for dopaminergic neurons. </>
In a third part of this thesis we investigated how loss of parkin function affects </>α</>-SYN induced neurotoxicity. Therefore, we used two complementary strategies: nigral rAAV2/7-mediated overexpression of human wild type </>α</>-SYN in parkinknockout mice and acute, locoregional downregulation of parkin in an A53T </>α</>-SYN rAAV2/7 rat model of PD. We found that the absence of parkin did not increase the vulnerability of the dopaminergic neurons to cell death induced by wild type </>α</>-SYN. However, the numberof cells positive for </>α</>-SYN phosphorylated at serine residue129, which is considered to be a pathological form of </>α</>-SYN,was significantly higher in the parkin knockout mice compared to the wild type mice.</> On the contrary, local downregulation of parkin significantly increased the sensitivity to A53T α-SYN mediated dopaminergic cell death, without affecting the phosphorylation of α-SYN. Thosedata support a functional relationship between parkin deficiency and α-SYN neurotoxicity.</>
Altogether, the results of this thesis indicate that equilibrated and well-controlled levels of parkin are crucialfor dopaminergic cell survival.</></>
Date:25 Aug 2009 →  7 Feb 2014
Keywords:Parkinson's disease
Disciplines:Laboratory medicine, Medical systems biology, Molecular and cell biology, Neurosciences, Biological and physiological psychology, Cognitive science and intelligent systems, Developmental psychology and ageing
Project type:PhD project