The long-term goals of this project are to complete our understanding of the genetic basis for the nemaline myopathies (NMs) with the aim of developing rapid genetic diagnostic tests suitable for newborn screening programs, and to develop effective and innovative therapies for one of the common causes of NM that would be identified through such screening. The nemaline myopathies are a genetically heterogeneous group of closely related congenital myopathies, defined on the basis of congenital presentation of moderate to profound skeletal muscle weakness and muscle biopsy revealing nemaline rods in myofibers of affected children. The unifying molecular feature of these conditions is that fact that six of the seven known genes encode components of the actin thin filament, making this a disease of the sarcomere. Despite extensive genetic investigations utilizing mapping and candidate gene analysis, the genetic basis for many cases remains unknown. However, the advent of next generation DNA sequencing, and availability of whole exome and genome sequencing makes comprehensive genetic studies feasible in a rapid and cost-effective manner. Whole exome sequencing will be utilized to complete the genetic analysis of a large and well- characterized cohort of NM patients, and on the basis of these results, a specific DNA capture chip will be designed to facilitate rapid analysis of all the genes for NM and related congenital myopathies for use in screening hypotonic and weak newborns. Effective therapies for NM are lacking, and a major hurdle to their development is absence of model systems suitable for screening potential therapeutic compounds. To address this problem, zebrafish models of skeletal actin (ACTA1 gene) related NM (NEM3) will be developed and characterized, and utilized in high throughput drug screens to identify lead compounds with therapeutic potential for NM and related disorders in patients with primary skeletal myopathies and muscular dystrophies. Development of this efficient and sensitive newborn DNA-based screening protocol will allow for rapid and accurate diagnosis, eliminating the need for more invasive and risky procedures such as muscle biopsy, and will allow for early prognostic determinations, carrier testing in at risk relatives to prevent births of future affected children, and will allow for optial early medical management. Identification of new therapeutic compounds and approaches will set the stage for preclinical testing of new therapies that may one day be used to treat children with these devastating neuromuscular diseases. These advances will also increase our knowledge of basic muscle biology with implications for our understanding of other neuromuscular diseases.
Neuromuscular diseases, such as the nemaline myopathies that are the focus of this proposal, typically present in the newborn period and lead to severe skeletal muscle weakness, inability to walk, difficulty in conduct of daily activities, and prematue death, often in infancy or early childhood. 'Genetic screening and therapies for nemaline myopathies' is highly relevant to public health because it will result in identification of the remaining genes responsible for these conditions, and the development of rapid, sensitive and specific DNA-based screening tests that will allow for accurate diagnosis, early detection of disease, and prenatal diagnosis to help families ensure the birth of healthy children. In addition, through the creation and use of innovative zebrafish disease models, new drugs and therapies will be identified and tested, leading to development of future treatments for children and adults born with these crippling diseases.
|Widrick, Jeffrey J; Gibbs, Devin E; Sanchez, Benjamin et al. (2018) An open source microcontroller based flume for evaluating swimming performance of larval, juvenile, and adult zebrafish. PLoS One 13:e0199712|
|Huntoon, Virginia; Widrick, Jeffrey J; Sanchez, Colline et al. (2018) SPEG-deficient skeletal muscles exhibit abnormal triad and defective calcium handling. Hum Mol Genet 27:1608-1617|
|Bennett, Alexis H; O'Donohue, Marie-Francoise; Gundry, Stacey R et al. (2018) RNA helicase, DDX27 regulates skeletal muscle growth and regeneration by modulation of translational processes. PLoS Genet 14:e1007226|
|Genetti, Casie A; Schwartz, Talia S; Robinson, Jill O et al. (2018) Parental interest in genomic sequencing of newborns: enrollment experience from the BabySeq Project. Genet Med :|
|Joureau, Barbara; de Winter, Josine Marieke; Conijn, Stefan et al. (2018) Dysfunctional sarcomere contractility contributes to muscle weakness in ACTA1-related nemaline myopathy (NEM3). Ann Neurol 83:269-282|
|Oates, Emily C; Jones, Kristi J; Donkervoort, Sandra et al. (2018) Congenital Titinopathy: Comprehensive characterization and pathogenic insights. Ann Neurol 83:1105-1124|
|Karakaya, Mert; Ceyhan-Birsoy, Ozge; Beggs, Alan H et al. (2017) A Novel Missense Variant in the AGRN Gene; Congenital Myasthenic Syndrome Presenting With Head Drop. J Clin Neuromuscul Dis 18:147-151|
|Cao, Siqi; Smith, Laura L; Padilla-Lopez, Sergio R et al. (2017) Homozygous EEF1A2 mutation causes dilated cardiomyopathy, failure to thrive, global developmental delay, epilepsy and early death. Hum Mol Genet 26:3545-3552|
|Mack, David L; Poulard, Karine; Goddard, Melissa A et al. (2017) Systemic AAV8-Mediated Gene Therapy Drives Whole-Body Correction of Myotubular Myopathy in Dogs. Mol Ther 25:839-854|
|Ceyhan-Birsoy, Ozge; Machini, Kalotina; Lebo, Matthew S et al. (2017) A curated gene list for reporting results of newborn genomic sequencing. Genet Med 19:809-818|
Showing the most recent 10 out of 20 publications