Genetic Manipulation of Cardiac K + Channel Function in Mice

Abstract

In the mammalian myocardium, potassium (K + ) channels control resting potentials, action potential waveforms, automaticity, and refractory periods and, in most cardiac cells, multiple types of K + channels that subserve these functions are expressed. Molecular cloning has revealed the presence of a large number of K + channel pore forming (α) and accessory (β) subunits in the heart, and considerable progress has been made recently in defining the relationships between expressed K + channel subunits and functional cardiac K + channels. To date, more than 20 mouse models with altered K + channel expression/functioning have been generated using dominant-negative transgenic and targeted gene deletion approaches. In several instances, the genetic manipulation of K + channel subunit expression has revealed the role of specific K + channel subunit subfamilies or individual K + channel subunit genes in the generation of myocardial K + channels. In other cases, however, the phenotypic consequences have been unexpected. This review summarizes what has been learned from the in situ genetic manipulation of cardiac K + channel functioning in the mouse, discusses the limitations of the models developed to date, and explores the likely directions of future research.