Your search keyword '"Butler, Kameryn M."' showing total 3 results

1. De novo variants in GABRA2 and GABRA5 alter receptor function and contribute to early-onset epilepsy.

Author

Butler, Kameryn M, Moody, Olivia A, Schuler, Elisabeth, Coryell, Jason, Alexander, John J, Jenkins, Andrew, and Escayg, Andrew

Subjects

*EPILEPSY risk factors, *CELL culture, *CELL receptors, *CYTOLOGICAL techniques, *DEVELOPMENTAL disabilities, *GENE expression, *GENOMES, *GENETIC mutation, *NEURONS, *SEQUENCE analysis

Abstract

GABAA receptors are ligand-gated anion channels that are important regulators of neuronal inhibition. Mutations in several genes encoding receptor subunits have been identified in patients with various types of epilepsy, ranging from mild febrile seizures to severe epileptic encephalopathy. Using whole-genome sequencing, we identified a novel de novo missense variant in GABRA5 (c.880G > C, p.V294L) in a patient with severe early-onset epilepsy and developmental delay. Targeted resequencing of 279 additional epilepsy patients identified 19 rare variants from nine GABAA receptor genes, including a novel de novo missense variant in GABRA2 (c.875C > A, p.T292K) and a recurrent missense variant in GABRB3 (c.902C > T, p.P301L). Patients with the GABRA2 and GABRB3 variants also presented with severe epilepsy and developmental delay. We evaluated the effects of the GABRA5, GABRA2 and GABRB3 missense variants on receptor function using whole-cell patch-clamp recordings from human embryonic kidney 293T cells expressing appropriate α, β and γ subunits. The GABRA5 p.V294L variant produced receptors that were 10-times more sensitive to GABA but had reduced maximal GABA-evoked current due to increased receptor desensitization. The GABRA2 p.T292K variant reduced channel expression and produced mutant channels that were tonically open, even in the absence of GABA. Receptors containing the GABRB3 p.P301L variant were less sensitive to GABA and produced less GABA-evoked current. These results provide the first functional evidence that de novo variants in the GABRA5 and GABRA2 genes contribute to early-onset epilepsy and developmental delay, and demonstrate that epilepsy can result from reduced neuronal inhibition via a wide range of alterations in GABAA receptor function. [ABSTRACT FROM AUTHOR]

Published

2018

2. Diagnostic Yield From 339 Epilepsy Patients Screened on a Clinical Gene Panel.

Author

Butler, Kameryn M., da Silva, Cristina, Alexander, John J., Hegde, Madhuri, and Escayg, Andrew

Subjects

*DIAGNOSIS of epilepsy, *GENETICS of epilepsy, *PSYCHOLOGICAL adaptation, *MEDICAL screening, *GENETIC counseling, *DISEASE susceptibility, *EPILEPSY, *GENETIC mutation, *MOLECULAR pathology, *RETROSPECTIVE studies

Abstract

Background: The contribution of genetic factors to epilepsy has long been recognized and has been estimated to play a role in 70% to 80% of cases. Identification of a pathogenic variant can help families to better cope with the disorder, allows for genetic counseling to determine recurrence risk, and in some cases, can directly influence treatment options. In this study, we determined the diagnostic yield of a clinical gene panel applied to an unselected cohort of epilepsy patients.Methods: Variant reports from 339 clinically referred epilepsy patients screened using a 110-gene panel were retrospectively reviewed. Variants were classified using the American College of Medical Genetics and Genomics guidelines.Results: Pathogenic or likely pathogenic variants were identified in 62 individuals (18%) and potentially causative variants were identified in an additional 21 individuals (6%). Causative and potentially causative variants were most frequently identified in SCN1A (n = 15) and KCNQ2 (n = 10). Other genes in which disease-causing variants were identified in multiple individuals included CDKL5, SCN2A, SCN8A, SCN1B, STXBP1, TPP1, PCDH19, CACNA1A, GABRA1, GRIN2A, SLC2A1, and TSC2. Sixteen additional genes had variants identified in single individuals.Conclusions: We identified 87 variants in 30 different genes that could explain disease, of which 54% were not previously reported. This study confirms the utility of targeted gene panel analysis in epilepsy and highlights several factors to improve the yield of diagnostic genetic testing, including the critical need for clinical phenotype information and parental samples, microarray analysis for whole exon deletions and duplications, and frequent update of panels to incorporate new disease genes. [ABSTRACT FROM AUTHOR]

Published

2017

3. De novo and inherited SCN8A epilepsy mutations detected by gene panel analysis.

Author

Butler, Kameryn M., da Silva, Cristina, Shafir, Yuval, Weisfeld-Adams, James D., Alexander, John J., Hegde, Madhuri, and Escayg, Andrew

Subjects

*PEOPLE with epilepsy, *SODIUM channels, *GENETIC mutation, *DISEASE incidence, *AUTISM spectrum disorders

Abstract

Objectives To determine the incidence of pathogenic SCN8A variants in a cohort of epilepsy patients referred for clinical genetic testing. We also investigated the contribution of SCN8A to autism spectrum disorder, intellectual disability, and neuromuscular disorders in individuals referred for clinical genetic testing at the same testing laboratory. Methods Sequence data from 275 epilepsy panels screened by Emory Genetics Laboratory were reviewed for variants in SCN8A . Two additional cases with variants in SCN8A were ascertained from other testing laboratories. Parental samples were tested for variant segregation and clinical histories were examined. SCN8A variants detected from gene panel analyses for autism spectrum disorder, intellectual disability, and neuromuscular disorders were also examined. Results Five variants in SCN8A were identified in five individuals with epilepsy. Three variants were de novo , one was inherited from an affected parent, and one was inherited from an unaffected parent. Four of the individuals have epilepsy and developmental delay/intellectual disability. The remaining individual has a milder epilepsy presentation without cognitive impairment. We also identified an amino acid substitution at an evolutionarily conserved SCN8A residue in a patient who was screened on the autism spectrum disorder panel. Additionally, we examined the distribution of pathogenic SCN8A variants across the Na v 1.6 channel and identified four distinct clusters of variants. These clusters are primarily located in regions of the channel that are important for the kinetics of channel inactivation. Conclusions Variants in SCN8A may be responsible for a spectrum of epilepsies as well as other neurodevelopmental disorders without seizures. The predominant pathogenic mechanism appears to involve disruption of channel inactivation, leading to gain-of-function effects. [ABSTRACT FROM AUTHOR]

Published

2017