Project description:GGC repeat expansion within NOTCH2NLC gene has been identified as the genetic cause of neuronal intranuclear inclusion disease (NIID). To understand the molecular pathogenesis of NIID, here we have established both a transgenic mouse model and a human neural progenitor cell (hNPC) model. We show that the expression of the NOTCH2NLC gene with expanded GGC repeats produces multiple forms of polypeptides, including polyglycine (polyG), polyalanine (polyA) and polyarginine (polyR), and leads to widespread intranuclear inclusions, severe neurodegeneration, motor dysfunction and cognitive deficits, which faithfully mimics the clinical manifestations and pathological features associated with NIID. We further performed RNA-seq on the prefrontal cortex, cerebellum and hippocampus of the transgenic mice and on the hNPC model and identified a large proportion of conserved alternative splicing between the NIID mouse and hNPC cell models. Analyses of the conserved alternative splicing revealed the enrichment of the binding motif of hnRNPM. We found that hnRNPM could interact with and be sequestered by expanded NOTCH2NLC-polyG and -polyA. Functional expression of hnRNPM could ameliorate the cellular toxicity caused by expanded GGC repeats within NOTCH2NLC. These results together suggest that dysregulated alternative splicing could play a vital role in the molecular pathogenesis of NIID.

Project description:Neuronal intranuclear inclusion disease (NIID) is a neurodegenerative disease caused by GGC repeat expansion of NOTCH2NLC. Despite the identification of uN2CpolyG, a toxic polyglycine (polyG) protein, the pathogenic mechanisms of NIID remain unclear. Herein, we investigated the role of polyG by expressing wild-type NOTCH2NLC, expanded NOTCH2NLC with 100 GGC repeats (translating or not translating into uN2CpolyG), or mutated NOTCH2NLC that encodes a pure polyG without GGC-repeat RNA and C-terminal stretch (uN2CpolyG-dCT) in mice. Both uN2CpolyG and uN2CpolyG-dCT induced the formation of inclusions composed by filamentous materials and caused neurodegenerative phenotypes in mice, including impaired motor and cognitive performance, shortened lifespan, and pathological lesions such as white matter lesions, microgliosis, and astrogliosis. By contrast, the sole expression of GGC-repeat RNA was non-pathogenic. Combining with bulk and single-nuclei RNA-seq, we determined the common molecular signatures associated with expressing uN2CpolyG and uN2CpolyG-dCT in the brain, especially the up-regulation of inflammation and microglia markers whereas down-regulation of immediate early genes and splicing factors. Importantly, microglia-mediated inflammation was visualized in NIID patients by positron emission tomography, which correlated with white matter atrophy levels. Moreover, microglia ablation ameliorated neurodegeneration in uN2CpolyG-expressing mice but did not alter polyG inclusions. Together, these results demonstrate that polyG is critical for the pathogenesis of NIID, and microglia contribute to polyG-induced neurodegeneration.

Project description:Neuronal intranuclear inclusion disease (NIID) is a neurodegenerative disease caused by GGC repeat expansion of NOTCH2NLC. Despite the identification of uN2CpolyG, a toxic polyglycine (polyG) protein, the pathogenic mechanisms of NIID remain unclear. Herein, we investigated the role of polyG by expressing wild-type NOTCH2NLC, expanded NOTCH2NLC with 100 GGC repeats (translating or not translating into uN2CpolyG), or mutated NOTCH2NLC that encodes a pure polyG without GGC-repeat RNA and C-terminal stretch (uN2CpolyG-dCT) in mice. Both uN2CpolyG and uN2CpolyG-dCT induced the formation of inclusions composed by filamentous materials and caused neurodegenerative phenotypes in mice, including impaired motor and cognitive performance, shortened lifespan, and pathological lesions such as white matter lesions, microgliosis, and astrogliosis. By contrast, the sole expression of GGC-repeat RNA was non-pathogenic. Combining with bulk and single-nuclei RNA-seq, we determined the common molecular signatures associated with expressing uN2CpolyG and uN2CpolyG-dCT in the brain, especially the up-regulation of inflammation and microglia markers whereas down-regulation of immediate early genes and splicing factors. Importantly, microglia-mediated inflammation was visualized in NIID patients by positron emission tomography, which correlated with white matter atrophy levels. Moreover, microglia ablation ameliorated neurodegeneration in uN2CpolyG-expressing mice but did not alter polyG inclusions. Together, these results demonstrate that polyG is critical for the pathogenesis of NIID, and microglia contribute to polyG-induced neurodegeneration.

Project description:Desmin-related myofibrillar myopathy, a severe muscle disease, is caused by mutations in the desmin-encoding gene, leading to skeletal myopathies and/or cardiomyopathy. Although previous studies suggested that desmin mutations alter the cellular structure and mitochondria function in myocyte, the pathophysiological mechanism by which mutated desmin impairs cardiac function has been poorly explored in physiologically relevant human disease models. In this attempt, we generated cardiomyocytes from induced pluripotent stem cells (hiPSC) of a patient carrying the heterozygous DESE439K mutation together with an isogenic pair of mutant hiPSC harboring the same mutation. Using 2D and 3D models as well as cardiac biopsies, we demonstrated that in mutant cardiomyocytes this heterozygous desmin mutation leads to disorganization in their cytoarchitecture and to a perturbation of their mitochondrial architecture and function. Finally, we then demonstrated that transfer of exogenous healthy mitochondria rescues the phenotypic impairment of mitochondrial function in desmin-mutated cardiomyocytes leading to the reversion of the diseased phenotype. This work advances our understanding on the critical role of mitochondria in the development of cardiomyopathy related to desmin mutation and opens up new potential therapeutic perspectives for this debilitating and still incurable disease.

Project description:DEP exposure is linked to increases in cardiovascular effects. This effect is enhanced in individuals with pre-existing disease. Animal models of cardiovascular disease are used to study this susceptibility. The heart is rich in mitochondria, which produce high levels of free radicals, leading to inactivation of tricarboxylic acid cycle enzymes. We hypothesized that a 4-wk DEP inhalation would result in strain-related structural impairment of cardiac mitochondria and changes in these enzyme activities in WKY and SHR. Male rats (12-14 wks age) were exposed whole body to air or 0.5 or 2.0 mg/m3 DEP for 6h/d, 5 d/wk for 4 wks. Neutrophilic influx was noted in the bronchoalveolar lavage fluid in both strains. A slightly lower level of baseline cardiac mitochondrial aconitase activity was seen in SHR than WKY. Aconitase activity appeared to be decreased in an exposure related manner in both strains. Significantly higher baseline levels of cardiac cytosolic ferritin and aconitase activity were seen in the SHR than WKY. No exposure-related changes were noted in either of these measures. Mitochondrial succinate and isocitrate dehydrogenase activities were not changed following DEP exposure in either strain. Transmission electron microscopy images of the heart indicated abnormalities in cardiac mitochondria of control SHR but not control WKY. No exposure related ultrastructural changes were induced by DEP in either strain. In conclusion, strain differences in cardiac biomarkers of oxidative stress and structure of mitochondria exist between SHR and WKY. DEP exposure results in small changes in cardiac mitochondrial and cytosolic markers of oxidative stress. (Abstract does not represent USEPA policy.) Experiment Overall Design: Two strains of rats (Wistar Kyoto (WKY) and spontaneously hypertensive (SH) rats were exposed to either diesel exhaust particles or clean air. Four biological replicates were used for each strain/treatment exposure. Total number of chips equals 16.

Project description:TDP-43, a DNA/RNA binding protein involved in RNA transcription and splicing has been associated with the pathophysiology of neurodegenerative diseases, including ALS. However, the function of TDP-43 in motor neurons remains undefined. Here, we employ both gain- and loss-of-function approaches to determine roles of TDP-43 in motor neurons. Mice expressing human TDP-43 in neurons exhibited growth retardation and premature death that are characterized by abnormal intranuclear inclusions comprised of TDP-43 and Fused in Sarcoma (FUS), and massive accumulation of mitochondria in TDP-43-negative cytoplasmic inclusions in motor neurons, lack of mitochondria in motor axon terminals and immature neuromuscular junctions. Whereas elevated level of TDP-43 disrupts the normal nuclear distribution of Survival Motor Neuron (SMN)-associated Gemini of coiled bodies (GEMs) in motor neurons, its absence prevents the formation of GEMs in the nuclei of these cells. Moreover, transcriptome-wide deep sequencing analysis revealed that decrease in abundance of neurofilament transcripts contributed to the reduction of caliber of motor axons in TDP-43 mice. In concert, our findings indicate that TDP-43 participates in pathways critical for motor neuron physiology, including those that regulate the normal distributions of SMN-associated GEMs in the nucleus and mitochondria in the cytoplasm. Human TDP-43 coding region were inserted into pThy1.2 expression cassette and subsequently injected into C57BL/6;SJL hybrid mouse embryos to make human TDP-43 transgenic mice

Project description:DEP exposure is linked to increases in cardiovascular effects. This effect is enhanced in individuals with pre-existing disease. Animal models of cardiovascular disease are used to study this susceptibility. The heart is rich in mitochondria, which produce high levels of free radicals, leading to inactivation of tricarboxylic acid cycle enzymes. We hypothesized that a 4-wk DEP inhalation would result in strain-related structural impairment of cardiac mitochondria and changes in these enzyme activities in WKY and SHR. Male rats (12-14 wks age) were exposed whole body to air or 0.5 or 2.0 mg/m3 DEP for 6h/d, 5 d/wk for 4 wks. Neutrophilic influx was noted in the bronchoalveolar lavage fluid in both strains. A slightly lower level of baseline cardiac mitochondrial aconitase activity was seen in SHR than WKY. Aconitase activity appeared to be decreased in an exposure related manner in both strains. Significantly higher baseline levels of cardiac cytosolic ferritin and aconitase activity were seen in the SHR than WKY. No exposure-related changes were noted in either of these measures. Mitochondrial succinate and isocitrate dehydrogenase activities were not changed following DEP exposure in either strain. Transmission electron microscopy images of the heart indicated abnormalities in cardiac mitochondria of control SHR but not control WKY. No exposure related ultrastructural changes were induced by DEP in either strain. In conclusion, strain differences in cardiac biomarkers of oxidative stress and structure of mitochondria exist between SHR and WKY. DEP exposure results in small changes in cardiac mitochondrial and cytosolic markers of oxidative stress. (Abstract does not represent USEPA policy.) Keywords: strain differences, exposure differences

Project description:TDP-43, a DNA/RNA binding protein involved in RNA transcription and splicing has been associated with the pathophysiology of neurodegenerative diseases, including ALS. However, the function of TDP-43 in motor neurons remains undefined. Here, we employ both gain- and loss-of-function approaches to determine roles of TDP-43 in motor neurons. Mice expressing human TDP-43 in neurons exhibited growth retardation and premature death that are characterized by abnormal intranuclear inclusions comprised of TDP-43 and Fused in Sarcoma (FUS), and massive accumulation of mitochondria in TDP-43-negative cytoplasmic inclusions in motor neurons, lack of mitochondria in motor axon terminals and immature neuromuscular junctions. Whereas elevated level of TDP-43 disrupts the normal nuclear distribution of Survival Motor Neuron (SMN)-associated Gemini of coiled bodies (GEMs) in motor neurons, its absence prevents the formation of GEMs in the nuclei of these cells. Moreover, transcriptome-wide deep sequencing analysis revealed that decrease in abundance of neurofilament transcripts contributed to the reduction of caliber of motor axons in TDP-43 mice. In concert, our findings indicate that TDP-43 participates in pathways critical for motor neuron physiology, including those that regulate the normal distributions of SMN-associated GEMs in the nucleus and mitochondria in the cytoplasm.

Project description:Familial hypertrophic cardiomyopathy (FHC) is a disease characterized by ventricular hypertrophy, fibrosis, and aberrant systolic and/or diastolic function. Our laboratories have previously developed 2 mouse models that affect cardiac performance. One transgenic mouse model encodes an FHC-associated mutation in α-tropomyosin (Tm180) that displays severe cardiac hypertrophy with fibrosis and impaired physiological performance. The other model was a gene knockout of phospholamban (PLB), a regulator of calcium uptake in the sarcoplasmic reticulum of cardiomyocytes; the hearts of these mice exhibit hypercontractility with no pathological abnormalities. Previous work in our laboratories show that the hearts of mice that were genetically crossed between the Tm180 and PLB KO mice rescues the hypertrophic phenotype and improves their cardiac morphology and function. We used microarrays to detail the global program of gene expression underlying cardiac remodeling and rescue of the hypertrophic cardiomyopathic phenotype and identified distinct classes of regulated genes during this process. To understand the changes in gene expression that occur over time in these animal models (Tm180, PLB KO, Tm180/PLB KO and nontransgenic control mice), we conducted microarray analyses of left ventricular tissue at 4 and 12 months of age.

Project description:β-Catenin signaling pathway regulates cardiomyocytes proliferation and differentiation, though its involvement in metabolic regulation of cardiomyocytes remains unknown. We used one-day-old mice with cardiac-specific knockout of β-catenin and neonatal rat ventricular myocytes treated with β-catenin inhibitor to investigate the role of β-catenin metabolism regulation in perinatal cardiomyocytes. Transcriptomics of perinatal β-catenin-ablated hearts revealed a dramatic shift in the expression of genes involved in metabolic processes. Further analysis indicated an inhibition of lipolysis and glycolysis in both in vitro and in vivo models. Finally, we showed that β-catenin deficiency leads to mitochondria dysfunction via the downregulation of Sirt1/PGC-1α pathway. We conclude that cardiac-specific β-catenin ablation disrupts the energy substrate shift that is essential for postnatal heart maturation, leading to perinatal lethality of homozygous β-catenin knockout mice.