Beyond gene-disease validity : capturing structured data on inheritance, allelic requirement, disease-relevant variant classes, and disease mechanism for inherited cardiac conditions

Beyond gene-disease validity : capturing structured data on inheritance, allelic requirement, disease-relevant variant classes, and disease mechanism for inherited cardiac conditions

BackgroundAs the availability of genomic testing grows, variant interpretation will increasingly be performed by genomic generalists, rather than domain-specific experts. Demand is rising for laboratories to accurately classify variants in inherited cardiac condition (ICC) genes, including secondary...

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Hauptverfasser: Josephs, Katherine S, Roberts, Angharad M, Theotokis, Pantazis, Walsh, Roddy, Ostrowski, Philip J, Edwards, Matthew, Fleming, Andrew, Thaxton, Courtney, Roberts, Jason D, Care, Melanie, Zareba, Wojciech, Adler, Arnon, Sturm, Amy C, Tadros, Rafik, Novelli, Valeria, Owens, Emma, Bronicki, Lucas, Jarinova, Olga, Callewaert, Bert, Peters, Stacey, Lumbers, Tom, Jordan, Elizabeth, Asatryan, Babken, Krishnan, Neesha, Hershberger, Ray E, Chahal, C. Anwar A, Landstrom, Andrew P, James, Cynthia, Mcnally, Elizabeth M, Judge, Daniel P, van Tintelen, Peter, Wilde, Arthur, Gollob, Michael, Ingles, Jodie, Ware, James S
Format: Artikel
Sprache:eng
Schlagworte:
Allelic requirement
AMERICAN-COLLEGE
ASSOCIATION
Biology and Life Sciences
CLINICAL EXOME
Disease mechanism
Gene curation
Genomic variant filtering
GENOMICS
HYPERTROPHIC CARDIOMYOPATHY
Inheritance
Inherited cardiac conditions
KCNQ1 MUTATION
MEDICAL GENETICS
Medicine and Health Sciences
MISSENSE MUTATION
SHORT QT SYNDROME
STATEMENT
Variant classification
Variant interpretation
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Zusammenfassung:BackgroundAs the availability of genomic testing grows, variant interpretation will increasingly be performed by genomic generalists, rather than domain-specific experts. Demand is rising for laboratories to accurately classify variants in inherited cardiac condition (ICC) genes, including secondary findings.MethodsWe analyse evidence for inheritance patterns, allelic requirement, disease mechanism and disease-relevant variant classes for 65 ClinGen-curated ICC gene-disease pairs. We present this information for the first time in a structured dataset, CardiacG2P, and assess application in genomic variant filtering.ResultsFor 36/65 gene-disease pairs, loss of function is not an established disease mechanism, and protein truncating variants are not known to be pathogenic. Using the CardiacG2P dataset as an initial variant filter allows for efficient variant prioritisation whilst maintaining a high sensitivity for retaining pathogenic variants compared with two other variant filtering approaches.ConclusionsAccess to evidence-based structured data representing disease mechanism and allelic requirement aids variant filtering and analysis and is a pre-requisite for scalable genomic testing.
ISSN:1756-994X
1756-994X