Core DThe Developmental Genomics Core (Core D) represents a new component of the DAB MRRC created byintegrating the resources from three existing groups - the Genomics Core Laboratory of the GCRC, theHeflin Center for Human Genetics, and the Medical Genomics Laboratory of the Department of Genetics -enabling an increase in the scope of activities and support to the core. The completion of the humangenome sequence has revealed the full complement of human genes, but the function of most of thesegenes and their RNA or protein products remains unknown. Careful study of the phenotypes associatedwith human genetic disorders offers a major opportunity to annotate the genome sequence by documentingthe phenotypes associated with sequence changes throughout the genome. Achieving this goal requiresprovision of tools for standardized phenotypic assessment and storage of data; genotyping patient DMA forvariation in known genes; and discovery of genes responsible for novel phenotypes. The DevelopmentalGenomics Core will facilitate a more complete characterization of the function of human genes involved indevelopmental disorders and will enhance the ability of investigators to translate their research findings toclinical application. Specific services will include: Clinical Study Coordination: Assistance with collection ofclinical information and DNA or tissue samples. This includes coordination of patient and family recruitment,creation and maintenance of phenotypic databases, and DNA and tissue collection and storage;Genotyping: Genotyping services for genetic linkage analysis or mutation screening of candidate loci.Services include consultation on experimental design, genotypic analysis, and data interpretation; andTranslational Genomics: Development of clinical molecular genetic diagnostic assays that can beperformed in a CLIA-licensed clinical laboratory. This relieves the research laboratory of the demand forclinical testing while maintaining the researcher's access to samples for phenotype-genotype correlationstudy.
Wadsworth, Heather M; Maximo, Jose O; Donnelly, Rebecca J et al. (2018) Action simulation and mirroring in children with autism spectrum disorders. Behav Brain Res 341:1-8 |
Tarquinio, Daniel C; Hou, Wei; Neul, Jeffrey L et al. (2018) The course of awake breathing disturbances across the lifespan in Rett syndrome. Brain Dev 40:515-529 |
Killian, John T; Lane, Jane B; Lee, Hye-Seung et al. (2017) Scoliosis in Rett Syndrome: Progression, Comorbidities, and Predictors. Pediatr Neurol 70:20-25 |
Tarquinio, Daniel C; Hou, Wei; Berg, Anne et al. (2017) Longitudinal course of epilepsy in Rett syndrome and related disorders. Brain 140:306-318 |
Butler, Anderson A; Webb, William M; Lubin, Farah D (2016) Regulatory RNAs and control of epigenetic mechanisms: expectations for cognition and cognitive dysfunction. Epigenomics 8:135-51 |
Heaven, Michael R; Flint, Daniel; Randall, Shan M et al. (2016) Composition of Rosenthal Fibers, the Protein Aggregate Hallmark of Alexander Disease. J Proteome Res 15:2265-82 |
Robert, Stephanie M; Buckingham, Susan C; Campbell, Susan L et al. (2015) SLC7A11 expression is associated with seizures and predicts poor survival in patients with malignant glioma. Sci Transl Med 7:289ra86 |
Parrish, R Ryley; Buckingham, Susan C; Mascia, Katherine L et al. (2015) Methionine increases BDNF DNA methylation and improves memory in epilepsy. Ann Clin Transl Neurol 2:401-16 |
Tarquinio, Daniel C; Hou, Wei; Neul, Jeffrey L et al. (2015) The Changing Face of Survival in Rett Syndrome and MECP2-Related Disorders. Pediatr Neurol 53:402-11 |
Tarquinio, Daniel C; Hou, Wei; Neul, Jeffrey L et al. (2015) Age of diagnosis in Rett syndrome: patterns of recognition among diagnosticians and risk factors for late diagnosis. Pediatr Neurol 52:585-91.e2 |
Showing the most recent 10 out of 129 publications