Identification, clinical manifestation and structural mechanisms of mutations in AMPK associated cardiac glycogen storage disease
Identificadores
Identificadores
Visualización o descarga de ficheros
Visualización o descarga de ficheros
Fecha de publicación
2020Título de revista
EBioMedicine
Tipo de contenido
Journal Article
DeCS
trifosfato de adenosina | muerte | enfermedad por almacenamiento de glucógeno | estabilidad proteica | heterocigoto | adulto | miocardio | simulación de dinámicas moleculares | proteina cinasas activadas por AMP | humanos | linaje | insuficiencia cardíaca | genéticaMeSH
Protein Stability | Adult | Humans | Genetics | Molecular Dynamics Simulation | Pedigree | Adenosine Triphosphate | Heterozygote | Glycogen Storage Disease | AMP-Activated Protein Kinases | Myocardium | Heart Failure | DeathResumen
BACKGROUND: Although 21 causative mutations have been associated with PRKAG2 syndrome, our understanding of the syndrome remains incomplete. The aim of this project is to further investigate its unique genetic background, clinical manifestations, and underlying structural changes. METHODS: We recruited 885 hypertrophic cardiomyopathy (HCM) probands and their families internationally. Targeted next-generation sequencing of sudden cardiac death (SCD) genes was performed. The role of the identified variants was assessed using histological techniques and computational modeling. FINDINGS: Twelve PRKAG2 syndrome kindreds harboring 5 distinct variants were identified. The clinical penetrance of 25 carriers was 100.0%. Twenty-two family members died of SCD or heart failure (HF). All probands developed bradycardia (HRmin, 36.3+/-9.8bpm) and cardiac conduction defects, and 33% had evidence of atrial fibrillation/paroxysmal supraventricular tachycardia (PSVT) and 67% had ventricular preexcitation, respectively. Some carriers presented with apical hypertrophy, hypertension, hyperlipidemia, and renal insufficiency. Histological study revealed reduced AMPK activity and major cardiac channels in the heart tissue with K485E mutation. Computational modelling suggests that K485E disrupts the salt bridge connecting the beta and gamma subunits of AMPK, R302Q/P decreases the binding affinity for ATP, T400N and H401D alter the orientation of H383 and R531 residues, thus altering nucleotide binding, and N488I and L341S lead to structural instability in the Bateman domain, which disrupts the intramolecular regulation. INTERPRETATION: Including 4 families with 3 new mutations, we describe a cohort of 12 kindreds with PRKAG2 syndrome with novel pathogenic mechanisms by computational modelling. Severe clinical cardiac phenotypes may be developed, including HF, requiring close follow-up.