Friedreich ataxia(FRDA)is a rare genetic multisystem disorder caused by a pathological GAA trinucleotide repeat expansion in the FXN gene.The numerous drawbacks of historical cellular and rodent models of FRDA have ca...Friedreich ataxia(FRDA)is a rare genetic multisystem disorder caused by a pathological GAA trinucleotide repeat expansion in the FXN gene.The numerous drawbacks of historical cellular and rodent models of FRDA have caused difficulty in performing effective mechanistic and translational studies to investigate the disease.The recent discovery and subsequent development of induced pluripotent stem cell(iPSC)technology provides an exciting platform to enable enhanced disease modelling for studies of rare genetic diseases.Utilising iPSCs,researchers have created phenotypically relevant and previously inaccessible cellular models of FRDA.These models enable studies of the molecular mechanisms underlying GAA-induced pathology,as well as providing an exciting tool for the screening and testing of novel disease-modifying therapies.This review explores how the use of iPSCs to study FRDA has developed over the past decade,as well as discussing the enormous therapeutic potentials of iPSC-derived models,their current limitations and their future direction within the field of FRDA research.展开更多
基金supported in part by LifeArc Project 10312,and partly by the Friedreich’s Ataxia Research Alliance,Ataxia UK and EndFA.G.V.-Esupported by the Ecuadorian government through Secretaría Nacional de Educación Superior,Ciencia,Tecnología e Innovación Act 063-CIBAE-2015.
文摘Friedreich ataxia(FRDA)is a rare genetic multisystem disorder caused by a pathological GAA trinucleotide repeat expansion in the FXN gene.The numerous drawbacks of historical cellular and rodent models of FRDA have caused difficulty in performing effective mechanistic and translational studies to investigate the disease.The recent discovery and subsequent development of induced pluripotent stem cell(iPSC)technology provides an exciting platform to enable enhanced disease modelling for studies of rare genetic diseases.Utilising iPSCs,researchers have created phenotypically relevant and previously inaccessible cellular models of FRDA.These models enable studies of the molecular mechanisms underlying GAA-induced pathology,as well as providing an exciting tool for the screening and testing of novel disease-modifying therapies.This review explores how the use of iPSCs to study FRDA has developed over the past decade,as well as discussing the enormous therapeutic potentials of iPSC-derived models,their current limitations and their future direction within the field of FRDA research.