Hallmarks of ion channel gene expression in end-stage heart failure

doi:10.1096/fj.02-0889com

Hallmarks of ion channel gene expression in end-stage heart failure

JÜRGEN BORLAK¹ and THOMAS THUM

Fraunhofer Institute of Toxicology and Experimental Medicine, Center for Drug Research and Medical Biotechnology, 30625 Hannover, Germany

¹ Correspondence: Fraunhofer Institute of Toxicology and Experimental Medicine (ITEM), Center for Drug Research and Medical Biotechnology, Nicolai-Fuchs-Str. 1, D-30659 Hannover, Germany. E-mail: Borlak{at}item.fraunhofer.de

Electrical conductance is greatly altered in end-stage heartfailure, but little is known about the underlying events. Wetherefore investigated the expression of genes coding for majorinward and outward ion channels, calcium binding proteins, ionreceptors, ion exchangers, calcium ATPases, and calcium/calmodulin-dependentprotein kinases in explanted hearts (n=13) of patients diagnosedwith end-stage heart failure. With the exception of K_v11.1 andK_ir3.1 and when compared with healthy controls, major sodium,potassium, and calcium ion channels, ion transporters, and exchangerswere significantly repressed, but expression of K_v7.1, HCN4,troponin C and I, SERCA1, and phospholamban was elevated. Hierarchicalgene cluster analysis provided novel insight into regulatedgene networks. Significant induction of the transcriptionalrepressor m-Bop and the translational repressor NAT1 coincidedwith repressed cardiac gene expression. The statistically significantnegative correlation between repressors and ion channels pointsto a mechanism of disease. We observed coregulation of ion channelsand the androgen receptor and propose a role for this receptorin ion channel regulation. Overall, the reversal of repressedion channel gene expression in patients with implanted assistdevices exemplifies the complex interactions between pressureload/stretch force and heart-specific gene expression.—Borlak,J., Thum, T. Hallmarks of ion channel gene expression in end-stageheart failure.

Key Words: ion channels • gene expression • repressors • heart failure • assist device

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