Browsing by Author "Chetty, Devina"

Now showing 1 - 1 of 1
  • Thumbnail Image
    Item
    Evaluating the neuroprotective effect of curcumin on a PINK1 cell model of Parkinson's disease
    (Stellebosch : Stellenbosch University, 2022-04) Chetty, Devina; Bardien, Soraya; Kenyon, Colin; Abrahams, Shameemah; Stellenbosch University. Faculty of Medicine and Health Sciences. Dept. of Biomedical Sciences: Molecular Biology and Human Genetics.
    ENGLISH ABSTRACT: Parkinson’s disease (PD) is a neurodegenerative disorder characterized by a loss of neurons producing the neurotransmitter dopamine. Notably, despite extensive studies that have revealed numerous dysregulated processes associated with PD, fundamental gaps still exist in our knowledge of the disease pathophysiology. Our understanding of the disease includes processes such as mitochondrial dysfunction causing increased oxidative stress and energy failure, as well as misfolded protein accumulation in large inclusions. However, the spatiotemporal sequence of events leading to PD and, importantly, the initial factors that trigger disease onset remain elusive. This challenges the development of effective therapeutic strategies to prevent and cure PD. Moreover, the various side effects associated with conventional pharmaceuticals currently used to treat this disease motivate the search for a natural treatment that can avoid augmenting the suffering associated with an already debilitating disease. It is evident that mitochondrial dysfunction and oxidative stress are likely to be involved in the disease pathogenesis, therefore studying these phenomena in PD may lead to the development of more effective therapeutic strategies. Curcumin is a plant-based polyphenol that has been observed to have antioxidant properties, increase cell viability, and enhance mitochondrial function. Consequently, the aim of the present study was to create a PD cellular model and evaluate the potential protective effects of curcumin. Therefore, we sought to establish an appropriate PD model by transfecting SH-SY5Y cells with wild-type (WT) or G309D mutant PINK1 cDNA, of which the latter has been shown to upregulate dopamine and lead to cytotoxicity. Additionally, since several neurotoxins have been shown to trigger PD, the toxic herbicide paraquat was administered to complement the model with cellular damage and mitochondrial dysfunction. To confirm the model, we performed RT-qPCR to measure gene expression levels of PINK1 and tyrosine hydroxylase (TH), an enzyme in the dopamine synthesis pathway. PINK1 was significantly upregulated in the mutant, however, no significant difference in TH gene expression was observed between groups. We then sought to measure the levels of dopamine in transfected cells using liquid chromatography-mass spectrometry (LC-MS). Although no dopamine was detected using LC-MS, higher levels of phenylalanine, a precursor of dopamine, were observed in the mutant. Using this model, we sought to test the protective effects of curcumin using assays that measure cellular and mitochondrial health. A toxic paraquat concentration of 1.7 mM was chosen to elicit a 50 % decrease in cell viability for the model, while a curcumin concentration of 2.5 μM was chosen as it exhibited no toxic effects. Following the establishment of the model, four treatment groups were established for all experiments thereon: untreated control, curcumin only treatment, paraquat only treatment, and pre-treatment (curcumin treatment followed by paraquat treatment). We found that curcumin was unable to significantly rescue the paraquat-induced reduction in cell viability and mitochondrial membrane potential. The latter was significantly reduced in PINK1 transfected groups, more so in the G309D mutant, indicating the toxic effects of the mutation. Thereafter, the effects of curcumin and polycaprolactone encapsulated nanocurcumin on cell viability were compared. Formulations of curcumin including nanocurcumin are postulated to improve the stability and efficacy of curcumin. Interestingly, curcumin had a greater protective effect, whereas nanocurcumin as well as the empty nanoparticles elicited toxicity. In fact, p re-treatment with the nanocurcumin prior to paraquat treatment caused a 30 % greater loss in cell viability compared to the paraquat treatment alone. Finally, a literature review was published, exploring the potential of consistent dietary consumption of curcumin as an alternative or supplement to existing therapies. We speculate that curcumin binds to α- synuclein protein (found to accumulate in PD) and that this complex is subsequently excreted from the body via the large intestine. In this view, replacing some of the PD drugs in an individual’s treatment regime with a nutraceutical, or ‘functional food’, like curcumin may improve therapeutic benefits with fewer side effects. Considering these results and the published evidence for curcumin as a dietary ‘nutraceutical’, further studies are required to optimize curcumin treatment before advocation of its widespread use as a PD therapeutic agent. Study limitations include the use of an unverified WT plasmid and an undifferentiated cell line, which can be addressed in future work. The findings in this study are of importance as they may contribute to advancing the development of novel plant-based therapies to treat and potentially prevent this detrimental disease.