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 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 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:Transcriptional Alterations of Hamstring Muscle Contractures in Children with Cerebral Palsy

Project description:Limb contractures are a debilitating and progressive consequence of a wide range of pediatric conditions that affect skeletal muscles, including perinatal brain injury causing cerebral palsy (CP). While several rehabilitation therapies are currently used in the clinical setting, their long-term effectiveness in treating contractures is marginal since they do not change underlying muscle biological properties. Therefore, new therapies based on a biological understanding of contracture development are needed. Here we show that myoblast progenitor cells from contractured muscle in children with CP had higher rates of proliferation than control cells from typically developing children. This phenotype was associated with upregulation of DNMT3a and patterns of DNA hypermethylation and gene expression that favored cell expansion over quiescence. Treatment of CP progenitors with 5-azacytidine, a DNMT inhibitor and hypomethylating agent, normalized this epigenetic imprint and promoted exit from mitosis. Together with previous studies demonstrating reduction in myoblast differentiation capacity, these data suggest that mechanisms of early myofiber growth and establishment of an adult population of quiescent stem cells could be compromised in CP. Hypomethylating agents like 5-azacytidine could be used to rescue myogenesis and promote muscle growth in contractured muscle and thus may represent a new approach to treating this devastating condition

Project description:Limb contractures are a debilitating and progressive consequence of a wide range of pediatric conditions that affect skeletal muscles, including perinatal brain injury causing cerebral palsy (CP). While several rehabilitation therapies are currently used in the clinical setting, their long-term effectiveness in treating contractures is marginal since they do not change underlying muscle biological properties. Therefore, new therapies based on a biological understanding of contracture development are needed. Here we show that myoblast progenitor cells from contractured muscle in children with CP had higher rates of proliferation than control cells from typically developing children. This phenotype was associated with upregulation of DNMT3a and patterns of DNA hypermethylation and gene expression that favored cell expansion over quiescence. Treatment of CP progenitors with 5-azacytidine (AZA), a DNMT inhibitor and hypomethylating agent, normalized this epigenetic imprint and promoted exit from mitosis. Together with previous studies demonstrating reduction in myoblast differentiation capacity, these data suggest that mechanisms of early myofiber growth and establishment of an adult population of quiescent stem cells could be compromised in CP. Hypomethylating agents like AZA could be used to rescue myogenesis and promote muscle growth in contractured muscle and thus may represent a new approach to treating this devastating condition

Project description:Unique Transcriptional Profile in Wrist Muscles From Cerebral Palsy Patients

Project description:Intraventricular hemorrhage (IVH) remains a major neurological complication of prematurity that results in cerebral palsy, hydrocephalus, and cognitive deficits. No effective therapy exists to prevent these disorders in infants with IVH. IVH triggers inflammation, cellular infiltration and white matter injury following neurobehavioural deficits.

Project description:Intraventricular hemorrhage (IVH) remains a major neurological complication of prematurity that results in cerebral palsy, hydrocephalus, and cognitive deficits. No effective therapy exists to prevent these disorders in infants with IVH. IVH triggers inflammation, cellular infiltration and white matter injury following neurobehavioural deficits.

Project description:Non-syndromic facial asymmetry is commonly found in dentofacial deformity populations with skeletal malocclusions. Asymmetry of this type may result from imbalanced growth and function of both the jaw and associated muscles. Among the multiple genes that interact to affect the craniofacial musculoskeletal complex during pre and postnatal growth and development, NODAL signaling pathwy (NSP) genes are active in adult skeletal muscle and may be key factors in development, growth and maintenance of facial asymmetry. It is of interest to determine whether expression of NODAL pathway genes might differ in masseter muscles between individuals with malocclusion that have facial asymmetry and normal symmetry. Human Transcriptome 2.0 GeneChips (HTA2.0) were used to examine global gene expression in masster muscles between malocclusion subjects with posterior facial asymmetry and with normal facial symmetry. Eleven patients undergoing orthoganthic surgery were selected for comparison of masseter muscle gene expression on microarrays. Two subjects had posterior facial asymmetry (one with class II open bite and one with class III open bite malocclusion) and nine subjects had normal facial symmetry (three with class II open bite, two with class III open bite and four with class II deep bite malocclusion). RNA representative of total gene expression in masseter muscles of the malocclusion subjects with and without posterior facial asymmetry was prepared for labeling and hybridization on HTA2.0 chips. The two subjects with facial asymmetry clustered separately from eight other malocclusion subjects by a principle component analysis (PCA), even though one had a class II and the other a class III malocclusion. Sample 4L_Open_II is from a subject who has sleep apnea. Data from 4L_Open_II clustered independent of the asymmetry group and the eight other subjects of the symmetry group by PCA and was not included in analysis of differential expression with facial symmetry. Masseter muscles are paired jaw muscles (i.e. right and left masseter). In some cases, there was not sufficient quantity/quality of RNA from one side, thus the other side was used. Please note that the following information is provided in the 'source name' field of each sample record; subject ID number; either left or right masseter; J CRANIOFAC SURG_ID# corresponding to the data presented in the manuscript