Project description:Cerebral palsy is caused be an upper motor neuron lesion which casues spasticity as well as secondary effects on muscle . Muscle from cerebral palsy patients is has been shown to be smaller, with more ECM and longer sarcomere lengths; We used microarrays to globally investigate the transcriptional adaptations of cerebral palsy muscle and research which muscle pathways are altered in the diseased state Experiment Overall Design: Muscle biopsies were taken from children undergoing surgery which exposed wrist muscle extensors (n=8) and flexors (n=8) in both cerebral palsy patients (n=6) and control patients (n=2) for RNA extraction and hybridization to Affymetrix GeneChips . Cerebral palsy patients were classified by a number of clinical scores.

Project description:Cerebral palsy is primarily an upper motor neuron disease that results in a spectrum of progressive movement disorders. Secondary to the neurological lesion, muscles from patients with cerebral palsy are often spastic and form debilitating contractures that limit range of motion and joint function. With no genetic component, the pathology of skeletal muscle in cerebral palsy is a response to aberrant neurological input in ways that are not fully understood. This study was designed to gain further understanding of the skeletal muscle response to cerebral palsy using microarrays and correlating the transcriptional data with functional measures. Hamstring biopsies from gracilis and semitendinosus muscles were obtained from a cohort of patients with cerebral palsy (n=10) and typically developing patients (n=10) undergoing surgery. Affymetrix HG-U133A 2.0 chips (n=40) were used and expression data was verified for 6 transcripts using quantitative real-time PCR, as well as for two genes not on the microarray. Chips were clustered based on their expression and those from patients with cerebral palsy clustered separately. Significant genes were determined conservatively based on the overlap of three summarization algorithms (n=1,398). Significantly altered genes were analyzed for over-representation among gene ontologies, transcription factors, pathways, microRNA and muscle specific networks. These results centered on an increase in extracellular matrix expression in cerebral palsy as well as a decrease in metabolism and ubiquitin ligase activity. The increase in extracellular matrix products was correlated with mechanical measures demonstrating the importance in disability. These data lay a framework for further studies and novel therapies. Skeletal muscle biopsies from both the gracilis and semitendinosus were obtained during surgery for 20 pediatric subjects for affymetrix microarray analysis. We obtained a group of 10 patients undergoing medial hamstring lengthening in the cerebral palsy group and 10 patients undergoing ACL reconstruction with hamstring autograft in the control group. This provided 40 microarrays in 4 groups to analyze the effect of cerebral palsy and also differences between muscles.

Project description:Cerebral palsy is caused be an upper motor neuron lesion which casues spasticity as well as secondary effects on muscle . Muscle from cerebral palsy patients is has been shown to be smaller, with more ECM and longer sarcomere lengths We used microarrays to globally investigate the transcriptional adaptations of cerebral palsy muscle and research which muscle pathways are altered in the diseased state Keywords: Disease state analysis

Project description:Cerebral palsy is primarily an upper motor neuron disease that results in a spectrum of progressive movement disorders. Secondary to the neurological lesion, muscles from patients with cerebral palsy are often spastic and form debilitating contractures that limit range of motion and joint function. With no genetic component, the pathology of skeletal muscle in cerebral palsy is a response to aberrant neurological input in ways that are not fully understood. This study was designed to gain further understanding of the skeletal muscle response to cerebral palsy using microarrays and correlating the transcriptional data with functional measures. Hamstring biopsies from gracilis and semitendinosus muscles were obtained from a cohort of patients with cerebral palsy (n=10) and typically developing patients (n=10) undergoing surgery. Affymetrix HG-U133A 2.0 chips (n=40) were used and expression data was verified for 6 transcripts using quantitative real-time PCR, as well as for two genes not on the microarray. Chips were clustered based on their expression and those from patients with cerebral palsy clustered separately. Significant genes were determined conservatively based on the overlap of three summarization algorithms (n=1,398). Significantly altered genes were analyzed for over-representation among gene ontologies, transcription factors, pathways, microRNA and muscle specific networks. These results centered on an increase in extracellular matrix expression in cerebral palsy as well as a decrease in metabolism and ubiquitin ligase activity. The increase in extracellular matrix products was correlated with mechanical measures demonstrating the importance in disability. These data lay a framework for further studies and novel therapies.

Project description:Our results revealed that hypoxic-ischemic brain injury decreased the overall 5hmC abundance in rat temporal cortex, and these results suggest that 5hmC modifications are involved in the cerebral palsy pathogenesis.

Project description:Nogo, also called RTN4, functions through three isoforms including Nogo-A, -B, and -C. Although Nogo-A is a well-known CNS inhibitor and the level of Nogo-A is increased in muscles of ALS patients, its role in the regulation of skeletal muscle homeostasis and regeneration is still vague. In this study, we analyzed various pathological muscle condition of human and mouse model, and discovered significant increase of Nogo-A and myogenic factors. To understand the role of Nogo in skeletal muscle, muscle transcripts from Nogo+/+ and Nogo-/- mouse were analyzed and observed intensified gene expression involved in adipocyte differentiation and lipid metabolism, and reduced gene expression related to muscle differentiation and structure organization suggesting muscle disorder from muscle replacement with fat deposition. Skeletal muscle structure from Nogo null mice displayed dystrophic phenotypes including impaired myofiber structure and immune cell infiltrations, and dysregulated homeostatic features such as higher level of MyoD, procaspase 3, CHOP, and AKT compared to wild-type muscle. Notexin-injured Nogo deficient muscle resulted higher level of immune cell infiltration but defective in IL-6 production, a well-known myokine from immune cells, and abnormally upregulated regenerative muscle fibers than normal muscle. Therefore we hypothesized that increased Nogo-A in pathological conditions may regulate muscle regeneration. Then differentiating C2C12 cells and induced myogenic stem cells(iMSC) showed upregulated Nogo-A and Myogenin, and Nogo-A silencing in C2C12 cells abrogated the capability to differentiate into myotubes. In conclusion, Nogo functions to maintain muscle homeostasis and integrity, and altered Nogo-A expression in pathological muscle condition mediates muscle regeneration. These understanding suggests Nogo-A as a novel differentiation target for the treatment of myopathies at clinical set.

Project description:WGS Cram files from the Childhood Cerebral Palsy Integrated Neuroscience Discovery Network "CP-NET" - Clinical Database Platforms - Phase 3 project.

Project description:In this study, the properties of circulating EVs were examined in cerebral palsy (CP) and typically developed (TD) individuals at rest and after aerobic exercise. We performed smallRNA-seq anf focused on the microRNA cargo of EVs

Project description:The elevation of Nogo-B expression in T2DM mice and Nogo-B knockdown alleviated diabetic symptoms in db/db mice prompted us to further investigate the involvement of Nogo-B in the insulin signaling pathway and T2DM. The three isoforms of Nogo are derived from various RNA splicing events, so deleting Nogo-B exons 2-4 results in the deficiency of other Nogo members, resulting in Nogo knockout (Nogo-/-) mice. As the liver is the key organ in the systemic response to insulin and controls glucose and lipid metabolism, we conducted RNA-seq of livers isolated from 8-week-old Nogo-/- mice and WT littermates.

Project description:Cerebral palsy (CP) represents a group of non-progressive clinically heterogeneous disorders that are characterized by motor impairment and early age-of-onset, frequently accompanied by co-morbidities. The cause of CP has historically been attributed to environmental stressors resulting in brain damage. While genetic risk factors are also implicated, guidelines for diagnostic assessment of CP do not recommend for routine genetic testing. Given numerous reports of etiologic copy number variations (CNVs) in other neurodevelopmental disorders, we used microarrays to genotype a population-based prospective cohort of children with CP and their parents. Here we identify de novo CNVs in 8/115 (7.0%) CP patients (~1% rate in controls). In four children, large chromosomal abnormalities deemed pathogenic were found, and they were significantly more likely to have severe neuro-motor impairments than those CP subjects without such alterations. Overall the CNV data would have impacted our diagnosis or classification of CP in 11/115 (9.6%) families. Dr. Maryam Oskoui* , Mr. Matthew Gazzellone* , Ms. Bhooma Thiruvahindrapuram , Dr. Mehdi Zarrei , Dr. John Andersen , Dr. John Wei , Dr. Zhouzhi Wang , Dr. Richard Wintle , Dr. Christian Marshall , Dr. Ronald Cohn , Dr. Rosanna Weksberg , Dr. James Stavropoulos , Dr. Darcy Fehlings , Dr. Michael Shevell, Dr. Stephen Scherer. Clinically Relevant Copy Number Variations Detected in Cerebral Palsy. Nature Communications, 2015. Following our rigorous quality control procedure, we successfully genotyped 147 proband samples from individuals with cerebral palsy (81 males and 66 females) and 282 samples obtained from parents (134 males and 148 females). This facilitated the identification of de novo and rare inherited copy number variations of clinical interest.