Project description:Parkinson disease (PD) is characterized by extensive loss of A9 dopaminergic (DA) neurons in the substantia nigra pars compacta (SNpc). A strong association has been reported between PD and exposure to mitochondrial toxins such as the environmental pesticides paraquat, maneb, and rotenone. Here, using a robust, patient-derived, stem cell model of PD that allows comparison of -synuclein ( -syn) mutant cells and isogeneic mutation-corrected controls, we identify mitochondrial toxin-induced perturbations specific to A53T -syn mutant A9-DA neurons (hNs). We report a novel molecular pathway whereby basal as well as toxin-induced oxidative and nitrosative stress inhibits the MEF2C-PGC1 transcription network in A53T hNs compared to corrected controls, contributing to mitochondrial dysfunction and apoptotic cell death. Our data provide mechanistic insight into gene-environmental interaction (GxE) in the pathogenesis of PD. Furthermore, using small molecule high-throughput screening, we identify the MEF2C-PGC1 pathway as a new drug target for therapeutic benefit in PD. In the current study, isogenic hiPSCs differing exclusively at a single amino acid (A53T) were exposed to either 2.8uM paraquat in combination with 1uM maneb for 24h or PBS vehicle control. Gene expression profile was analysed to assess the effect of both the genotype and exposure regiment on gene expression.

Project description:Parkinson disease (PD) is characterized by extensive loss of A9 dopaminergic (DA) neurons in the substantia nigra pars compacta (SNpc). A strong association has been reported between PD and exposure to mitochondrial toxins such as the environmental pesticides paraquat, maneb, and rotenone. Here, using a robust, patient-derived, stem cell model of PD that allows comparison of -synuclein ( -syn) mutant cells and isogeneic mutation-corrected controls, we identify mitochondrial toxin-induced perturbations specific to A53T -syn mutant A9-DA neurons (hNs). We report a novel molecular pathway whereby basal as well as toxin-induced oxidative and nitrosative stress inhibits the MEF2C-PGC1 transcription network in A53T hNs compared to corrected controls, contributing to mitochondrial dysfunction and apoptotic cell death. Our data provide mechanistic insight into gene-environmental interaction (GxE) in the pathogenesis of PD. Furthermore, using small molecule high-throughput screening, we identify the MEF2C-PGC1 pathway as a new drug target for therapeutic benefit in PD.

Project description:Objective: Parkinson's disease (PD) is part of a common type of neurodegenerative disease. AVE0991, a non-peptide analogue of Ang-(1-7), by which the progression of PD has been discovered to be ameliorated, but the specific mechanism whereby AVE0991 modulates the progression of PD remains unclear. Materials and Methods: During the study, the mice overexpressing of human α-syn(A53T) were established to simulate PD pathology, and we also constructed an in vitro model of mouse dopaminergic neurons overexpressing hα-syn(A53T). The [18F] FDG-PET/CT method was also employed to assess FDG uptake in human α-syn(A53T) overexpressing mice. Level of Lnc HOTAIRM1, miR-223-3p were detected via RT-qPCR. Flow cytometry was deployed to assay cell apoptosis. Results: AVE0991 improved behavior disorder and decreased α-syn expression in the substantia nigra in mice with Parkinson's disease. AVE0991 inhibited apoptosis of dopaminergic neurons overexpressing hα-syn(A53T) by LncRNA HOTAIRM1. MiR-223-3p binds to HOTAIRM1 as a ceRNA and directly targets α-syn. Conclusion: The angiotensin-(1–7) analogue AVE0991 targeted the HOTAIRM1/miR-223-3p axis to degrade α-synuclein in PD mice, and showed neuroprotection in vitro.

Project description:Parkinson's disease is the second most common neurodegenerative disorder, whose characteristic pathology involves progressive loss of dopaminergic neurons and formation of Lewy bodies(LBs) in the substantia nigra(SN). Aggregated and misfolded α-synuclein(α-syn) is the major constituent of LBs. As the newly discovered pathway of renin-angiotensin system (RAS), Angiotensin-(1-7)(Ang-(1-7)) and its receptor Mas have attracted increasing attentions for their correlation with PD progression, but underlying mechanisms remain not very clear. Based on the above, this study established PD models of mice and primary dopaminergic neurons with overexpression of α-syn, then discussed the effect of Ang-(1-7)/Mas on these models combined with downstream lncRNA and miRNA. The findings show that Ang-(1-7) alleviates behavioral disorders, rescues dopaminergic neurons loss and lowers α-syn expression in the SN of hα-syn(A53T) overexpressed PD mice. We also discover that Ang-(1-7) decreases the level of α-syn and apoptosis in the hα-syn(A53T) overexpressed dopaminergic neurons through NEAT1/miR-153-3p axis. Moreover, miR-153-3p expression in peripheral blood is found negatively correlated with that of α-syn. These results not only uncovered the significance and related mechanisms of Ang-(1-7)/Mas on α-syn pathology, but also throwed a new light upon miR-153-3p and NEAT1 as biomarkers and therapeutic targets in PD.

Project description:Parkinson's disease is a prevalent neurodegenerative disorder for which there is no cure. The cause of PD symptoms is loss of dopamine neurons in the midbrain, but it is not known why these neurons die. Pesticide exposure is epidemiologically associated with PD, and administration of the organic pesticide rotenone to rats recapitulates most of the behavioral, neurochemical, and neuropathological findings in PD, including specific death of dopamine neurons. We have developed an in vitro model of rotenone toxicity using a dopaminergic cell line (SK-N-MC neuroblastoma cells) that mimics many of the cellular changes seen with in vivo rotenone toxicity and with PD, such as alpha-synuclein aggregation and oxidative damage. We are currently using this simple model to explore mechanisms of dopaminergic neurodegeneration, with our ultimate goal being the discovery of novel mechanisms for dopaminergic neuroprotection in PD. We will examine gene expression profiles of cultured SK-N-MC cells at several time points during rotenone exposure to determine pathways involved in rotenone toxicity and dopaminergic degeneration. We will compare these profiles to baseline profiles of rodent dopaminergic neurons that we have already obtained, as well as to profiles of dopamine neurons from rotenone-treated rats that we will obtain in the near future. We will also compare these data to published results from SN neurons from human PD patients. This technique will not only help us to detect gene expression changes relevant to dopaminergic neurodegeneration in PD, but it will allow us to determine if the SK-N-MC system can be reliably used to screen for neuroprotective therapies for PD. We anticipate that SK-N-MC cells will show a relevant subset of the gene changes seen in dopamine neurons in vivo and that this will guide us in the sorts of mechanisms and drugs that can be screened in this system. Chronic exposure to low levels of rotenone causes changes in gene expression in SK-N-MC cells that sensitize the cells to toxic insults. We also hypothesize that there are several compensatory protective pathways that are stimulated by chronic rotenone, although these pathways are ultimately ineffective at preventing damage. We anticipate that gene expression profiling of rotenone-treated cells over time will suggest several novel strategies for neuroprotective intervention. SK-N-MC cells will be grown in three different media: media only, vehicle (EtOH), and rotenone (5 nM). All current experimental evidence in our lab indicates that vehicle-treated cells are indistinguishable from media-only cells. Rotenone-treated cellls have a stereotypical response in culture. At one week, the only noticed change is an increase in alph-synuclein aggregation. At two weeks, evidence of increased oxidative stress appears (increased protein carbonyls and lipid peroxidation). At four weeks, the cells are markedly sensitized to oxidative challenge with H2O2. Therefore, we will examine gene expression at baseline, and during 1, 2, and 4 weeks of rotenone treatment. Three experiments will be performed, each lasting 4 weeks. For each experiment, three separate dishes of vehicle-treated, and rotenone-treated cells will be harvested at 1, 2, and 4 weeks (18 independent samples). Untreated, media-only cells will be harvested after 1 week in vitro to serve as baseline cells. Total RNA will be isolated. An equal amount of RNA from one dish per experiment per group will be used to compose the final samples. Therefore, each independent sample will consist of RNA from 3 separate experiments. This will allow us to take advantage of a pooling strategy, yet not sacrifice technical and biological replication. 21 samples will be sent to the Consortium. Three will be from untreated cells. Nine will be vehicle-treated at 1, 2, and 4 weeks (3 each). Nine will be rotenone-treated at 1, 2 , and 4 weeks (3 each). Each sample will be labeled and hybridized to one Affymetrix Human Genome U133 Plus 2.0 Gene Chip. With assistance of the consortium, we will analyze the data using the Signifiance Analysis of Microarrays (SAM) program and self-organizing map algorithms.

Project description:To uncover new disease-associated genes and their relevant mechanisms, we carried out a gene microarray analysis based on a Parkinson’s disease (PD) in vitro model induced by a-synuclein oligomers. The result do help to reveal the mRNA and lncRNA profile in a-syn induced cells and rotenone-stimulated cells.

Project description:Background: Cell-to-cell propagation of α-synuclein (α-syn) aggregates is thought to contribute to the pathogenesis of Parkinson’s disease (PD) and underlie the spread of α-syn neuropathology. Increased pro-inflammatory cytokine levels and activated microglia are present in PD and activated microglia can promote α-syn aggregation. However, it is unclear how microglia influence α-syn cell-to-cell transfer. Methods: We developed a clinically relevant mouse model to monitor α-syn prion-like propagation between cells; we transplanted wild-type mouse embryonic midbrain neurons into a mouse striatum overexpressing human α-syn (huα-syn) following adeno-associated viral injection into the substantia nigra. In this system, we depleted or activated microglial cells and determined the effects on the transfer of huα-syn from host nigrostriatal neurons into the implanted dopaminergic neurons, using the presence of huα-syn within the grafted cells as a readout. Results: First, we compared α-syn cell-to-cell transfer between host mice with a normal number of microglia to mice in which we had pharmacologically ablated 80% of the microglia from the grafted striatum. With fewer host microglia, we observed increased accumulation of huα-syn in grafted dopaminergic neurons. Second, we assessed the transfer of α-syn into grafted neurons in the context of microglia activated by one of two stimuli, lipopolysaccharide (LPS) or interleukin-4 (IL-4). LPS exposure led to a strong activation of microglial cells (as determined by microglia morphology and cytokine production) and significantly higher amounts of huα-syn in grafted neurons. In contrast, injection of IL-4 did not change the proportion of grafted dopamine neurons that contained huα-syn relative to controls. RNA sequencing analysis revealed differential gene expression between LPS and IL-4 injected mice; many genes were upregulated in LPS including those involved with the inflammatory response. Conclusions: The absence or the hyperstimulation of microglia affected α-syn transfer in the brain. Our results suggest that under resting, non-inflammatory conditions, microglia modulate the transfer of α-syn. Pharmacological regulation of neuroinflammation could represent a future avenue for limiting the spread of PD neuropathology.

Project description:Parkinson's disease is a prevalent neurodegenerative disorder for which there is no cure. The cause of PD symptoms is loss of dopamine neurons in the midbrain, but it is not known why these neurons die. Pesticide exposure is epidemiologically associated with PD, and administration of the organic pesticide rotenone to rats recapitulates most of the behavioral, neurochemical, and neuropathological findings in PD, including specific death of dopamine neurons. We have developed an in vitro model of rotenone toxicity using a dopaminergic cell line (SK-N-MC neuroblastoma cells) that mimics many of the cellular changes seen with in vivo rotenone toxicity and with PD, such as alpha-synuclein aggregation and oxidative damage. We are currently using this simple model to explore mechanisms of dopaminergic neurodegeneration, with our ultimate goal being the discovery of novel mechanisms for dopaminergic neuroprotection in PD. We will examine gene expression profiles of cultured SK-N-MC cells at several time points during rotenone exposure to determine pathways involved in rotenone toxicity and dopaminergic degeneration. We will compare these profiles to baseline profiles of rodent dopaminergic neurons that we have already obtained, as well as to profiles of dopamine neurons from rotenone-treated rats that we will obtain in the near future. We will also compare these data to published results from SN neurons from human PD patients. This technique will not only help us to detect gene expression changes relevant to dopaminergic neurodegeneration in PD, but it will allow us to determine if the SK-N-MC system can be reliably used to screen for neuroprotective therapies for PD. We anticipate that SK-N-MC cells will show a relevant subset of the gene changes seen in dopamine neurons in vivo and that this will guide us in the sorts of mechanisms and drugs that can be screened in this system. Chronic exposure to low levels of rotenone causes changes in gene expression in SK-N-MC cells that sensitize the cells to toxic insults. We also hypothesize that there are several compensatory protective pathways that are stimulated by chronic rotenone, although these pathways are ultimately ineffective at preventing damage. We anticipate that gene expression profiling of rotenone-treated cells over time will suggest several novel strategies for neuroprotective intervention. SK-N-MC cells will be grown in three different media: media only, vehicle (EtOH), and rotenone (5 nM). All current experimental evidence in our lab indicates that vehicle-treated cells are indistinguishable from media-only cells. Rotenone-treated cellls have a stereotypical response in culture. At one week, the only noticed change is an increase in alph-synuclein aggregation. At two weeks, evidence of increased oxidative stress appears (increased protein carbonyls and lipid peroxidation). At four weeks, the cells are markedly sensitized to oxidative challenge with H2O2. Therefore, we will examine gene expression at baseline, and during 1, 2, and 4 weeks of rotenone treatment. Three experiments will be performed, each lasting 4 weeks. For each experiment, three separate dishes of vehicle-treated, and rotenone-treated cells will be harvested at 1, 2, and 4 weeks (18 independent samples). Untreated, media-only cells will be harvested after 1 week in vitro to serve as baseline cells. Total RNA will be isolated. An equal amount of RNA from one dish per experiment per group will be used to compose the final samples. Therefore, each independent sample will consist of RNA from 3 separate experiments. This will allow us to take advantage of a pooling strategy, yet not sacrifice technical and biological replication. 21 samples will be sent to the Consortium. Three will be from untreated cells. Nine will be vehicle-treated at 1, 2, and 4 weeks (3 each). Nine will be rotenone-treated at 1, 2 , and 4 weeks (3 each). Each sample will be labeled and hybridized to one Affymetrix Human Genome U133 Plus 2.0 Gene Chip. With assistance of the consortium, we will analyze the data using the Signifiance Analysis of Microarrays (SAM) program and self-organizing map algorithms. Keywords: time-course

Project description:SWATH-MS proteomics was used to study protein composition in isolated hippocampal synapses derived from A53T-mutated hα-syn rats respect to WT rats.

Project description:The degenerative process in Parkinson’s disease (PD) causes a progressive loss of dopaminergic neurons (DaNs) in the nigrostriatal system. Resolving the differences in neuronal susceptibility warrants an amenable PD model that, in comparison to post-mortem human specimens, controls for environmental and genetic differences in PD pathogenesis. At present study, we generated a primate model of PD by carotid artery injection of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine MPTP and sampled substantia nigra and putamen of macaque for single cell sequencing analysis.