Abstract
Mutations in the cyclic nucleotide binding domain (CNBD) of the human ether-a-go-go-related gene (HERG) K+ channel are associated with LQT2, a form of hereditary Long QT syndrome (LQTS). Elevation of cAMP can modulate HERG K+ channels both by direct binding and indirect regulation through protein kinase A. To assess the physiological significance of cAMP binding to HERG, we introduced mutations to disrupt the cyclic nucleotide binding domain. Eight mutants including two naturally occurring LQT2 mutants V822M and R823W were constructed. Relative cAMP binding capacity was reduced or absent in CNBD mutants. Mutant homotetramers carry little or no K+ current despite normal protein abundance and surface expression. Co-expression of mutant and wild-type HERG resulted in currents with altered voltage dependence but without dominant current suppression. The data from co-expression of V822M and wild-type HERG best fit a model where one normal subunit within a tetramer allows nearly normal current expression. The presence of KCNE2, an accessory protein that associates with HERG, however, conferred a partially dominant current suppression by CNBD mutants. Thus KCNE2 plays a pivotal role in determining the phenotypic severity of some forms of LQT2, which suggests that the CNBD of HERG may be involved in its interaction with KCNE2.
Highlights
Long QT syndrome is an inherited cardiac disorder that causes sudden death from tachyarrhythmias
In this study we have examined the function of cyclic nucleotide binding domain (CNBD) in human ether-a-go-go-related gene (HERG) Kϩ channels in a heterologous mammalian expression system
We selectively introduced mutations at the key sites in the cyclic nucleotide binding domain, which we predicted would disrupt cAMP binding
Summary
Long QT syndrome is an inherited cardiac disorder that causes sudden death from tachyarrhythmias. The cardiac Ikr was originally thought to be insensitive to cAMP-dependent regulation [3, 8], recent studies provided evidence that HERG channels can be modulated via cAMP-dependent protein kinase (PKA) phosphorylation pathway (9 –11). Previous studies of the CNBD in cyclic nucleotide-dependent protein kinase and bacterial cAMP-regulated catabolic gene activator protein (CAP) identified six invariant key amino acid residues for cyclic nucleotide binding [13]. Three of these are glycine residues that are essential for maintenance of the -barrel structure that is required to form a pocket for cyclic nucleotide binding. Coexpression with the accessory subunit KCNE2, converts the CNBD mutants into partially dominant-negative suppressors
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