Project description:Reprogramming somatic cells to induced pluripotent stem cells (iPSCs) sets their identity back to an embryonic age. This presents a fundamental hurdle for modeling late-onset disorders using iPSC-derived cells. We therefore developed a strategy to induce age-like features in multiple iPSC-derived lineages and tested its impact on modeling Parkinson’s disease (PD). We first describe markers that predict fibroblast donor age and observed the loss of these age-related markers following iPSC induction and re-differentiation into fibroblasts. Remarkably, age-related markers were readily induced in iPSC-derived fibroblasts or neurons following exposure to progerin including dopamine neuron-specific phenotypes such as neuromelanin accumulation. Induced aging in PD-iPSC-derived dopamine neurons revealed disease phenotypes requiring both aging and genetic susceptibility such as frank dendrite degeneration, progressive loss of tyrosine-hydroxylase expression and enlarged mitochondria or Lewy body-precursor inclusions. Our study presents a strategy for inducing age-related cellular properties and enables the modeling of late-onset disease features. Induced pluripotent stem cell-derived midbrain dopamine neurons from a young and old donor overexpressing either GFP or Progerin.

Project description:Parkinson’s disease (PD) is a prevalent neurodegenerative disorder that is characterized by the selective loss of midbrain dopamine (DA)-producing neurons and the formation of α-synuclein (α-syn)-containing inclusions named Lewy bodies (LBs). Here, we report that the loss of glucocerebrosidase (GCase), coupled with α-syn overexpression, result in substantial accumulation of detergent-resistant α-syn aggregates and Lewy body-like inclusions (LBLIs) in human midbrain-like organoids (hMLOs). These LBLIs exhibit a highly similar structure to PD-associated LBs, by displaying a spherically symmetric morphology with an eosinophilic core, and containing α-syn and ubiquitin. Importantly, hMLOs generated from PD patient-derived inducible pluripotent stem cells (iPSCs) harboring SNCA triplication also exhibit subsequent degeneration of DA neurons and LBLI formation upon chronic GCase inhibitor treatment. Taken together, our hMLOs harbouring two major PD risk factors (GCase deficiency and overproduced α-syn) successfully recapitulate major pathophysiological signatures of the disease, and highlight the broad utility of brain organoid technology in modeling human neurodegenerative diseases.

Project description:Induced pluripotent stem cell (iPSC)-derived dopamine neurons provide an opportunity to model Parkinson’s disease (PD) but neuronal cultures are confounded by cellular heterogeneity. By applying high-resolution single cell transcriptomic analyses to Parkinson’s iPSC-derived dopamine neurons carrying the GBA-N370S risk variant, we exploited intra-culture cellular heterogeneity to identify a progressive axis of gene expression variation leading to endoplasmic reticulum stress. Analysis of genes differentially-expressed (DE) along this axis identified the transcriptional repressor histone deacetylase 4 (HDAC4) as an upstream regulator of disease progression. HDAC4 was mislocalized to the nucleus in PD iPSC-derived dopamine neurons and repressed genes early in the disease axis, leading to late deficits in protein homeostasis. Treatment of iPSC-derived dopamine neurons with compounds known to modulate HDAC4 activity upregulated genes early in the DE axis, and corrected Parkinson’s-related cellular phenotypes. Our study demonstrates how single cell transcriptomics can exploit cellular heterogeneity to reveal disease mechanisms and identify therapeutic targets.

Project description:Reprogramming somatic cells to induced pluripotent stem cells (iPSCs) sets their identity back to an embryonic age. This presents a fundamental hurdle for modeling late-onset disorders using iPSC-derived cells. We therefore developed a strategy to induce age-like features in multiple iPSC-derived lineages and tested its impact on modeling Parkinson’s disease (PD). We first describe markers that predict fibroblast donor age and observed the loss of these age-related markers following iPSC induction and re-differentiation into fibroblasts. Remarkably, age-related markers were readily induced in iPSC-derived fibroblasts or neurons following exposure to progerin including dopamine neuron-specific phenotypes such as neuromelanin accumulation. Induced aging in PD-iPSC-derived dopamine neurons revealed disease phenotypes requiring both aging and genetic susceptibility such as frank dendrite degeneration, progressive loss of tyrosine-hydroxylase expression and enlarged mitochondria or Lewy body-precursor inclusions. Our study presents a strategy for inducing age-related cellular properties and enables the modeling of late-onset disease features.

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:Defining the transcriptional profiles of SNc and VTA dopamine neurons could reveal mechanisms underlying their differential susceptibilities in Parkinson’s disease. To conclusively identify genes stably enriched in either VTA or SNc dopamine neurons we conducted transcriptomic profiling across 18 human subjects and revealed novel genes in human that stably define dopamine neuron subtypes by random pooling algorithm.

Project description:Analysis of human dopamine (DA) from postmortem brains of 8 patients with Parkinson’s disease (PD). Results provide insight into the molecular processes perturbed in the PD substantia nigra. Human dopamine (DA) neurons from 8 PD and 9 control subjects were obtained. Double-stranded complementary DNA was made with a biotinylated T7(dT)-24 primer. Biotinylated complementary RNA was fragmented and hybridized to Affymetrix human genome U133_X3P microarrays. The Affymetrix .CEL files were normalized to “all probe sets” in a standardized matter, and scaled to 100 by the MAS5 algorithm implemented in the Bioconductor package.

Project description:The transcription factor nurr1 plays a pivotal role in the development and maintenance of neurotransmitter phenotype in midbrain dopamine neurons. Conversely, decreased nurr1 expression is associated with a number of dopamine-related CNS disorders, including Parkinson’s disease and drug addiction. In order to better understand the nature of nurr1-responsive genes and their potential roles in dopamine neuron differentiation and survival, we used a neural cellular background in which to generate a number of stable clonal lines with graded nurr1 gene expression that approximated that seen in DA cell-rich human substantia nigra. Gene expression profiling data from these nurr1-expressing clonal lines were validated by quantitative RT-PCR and subjected to bioinformatic analyses. The present study identified a large number of nurr1-responsive genes and demonstrated the potential importance of concentration-dependent nurr1 effects in the differential regulation of distinct nurr1 target genes and biological pathways. These data support the promise of nurr1-based CNS therapeutics for the neuroprotection and/or functional restoration of DA neurons. Total RNA obtained from nurr1-overexpressing SKNAS neuroblastoma clonal cell lines (SKNAS_E & SKNAS_G) compared to empty vector transfected control (SKNAS_C)

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:The pesticide rotenone, a neurotoxin that inhibits the mitochondrial complex I, and destabilizes microtubules (MT) has been linked to Parkinson disease (PD) etiology and is often used to model this neurodegenerative disease (ND). Many of the mechanisms of action of rotenone are posited mechanisms of neurodegeneration; however, they are not fully understood. Therefore, the study of rotenone-affected functional pathways is pertinent to the understanding of NDs pathogenesis. This report describes the transcriptome analysis of a neuroblastoma (NB) cell line chronically exposed to marginally toxic and moderately toxic doses of rotenone. The results revealed a complex pleiotropic response to rotenone that impacts a variety of cellular events, including cell cycle, DNA damage response, proliferation, differentiation, senescence and cell death, which could lead to survival or neurodegeneration depending on the dose and time of exposure and cell phenotype. The response encompasses an array of physiological pathways, modulated by transcriptional and epigenetic regulatory networks, likely activated by homeostatic alterations. Pathways that incorporate the contribution of MT destabilization to rotenone toxicity are suggested to explain complex I-independent rotenone-induced alterations of metabolism and redox homeostasis. The postulated mechanisms involve the blockage of mitochondrial voltage-dependent anions channels (VDACs) by tubulin, which coupled with other rotenone-induced organelle dysfunctions may underlie many presumed neurodegeneration mechanisms associated with pathophysiological aspects of various NDs including PD, AD and their variant forms. Thus, further investigation of such pathways may help identify novel therapeutic paths for these NDs.