INTRODUCTION: Mutations in the pore domain of the human ether-a-go-go-related gene (hERG) potassium channel are associated with higher risk of sudden death. However, in many kindreds clinical presentation is variable, making it hard to predict risk. We hypothesized that in vitro phenotyping of the intrinsic severity of individual mutations can assist with risk stratification. METHODS AND RESULTS: We analyzed 2 hERG pore domain mutations, G572S and G584S. Similar to 90% of hERG missense mutations, G572S-hERG subunits did not traffic to the plasma membrane but could coassemble with WT subunits and resulted in a dominant negative suppression of hERG current density. The G584S-hERG subunits traffic normally but have abnormal inactivation gating. Computer models of human ventricular myocyte action potentials (AP), incorporating Markov models of the hERG mutants, indicate that G572S-hERG channels would cause more severe AP prolongation than that seen with G584S-hERG channels. CONCLUSIONS: hERG-G572S and -G584S are 2 pore domain mutations that involve the same change in sidechain but have very different in vitro phenotypes; G572S causes a dominant negative trafficking defect, whereas G584S is the first hERG missense mutation where the cause of disease can be exclusively attributed to enhanced inactivation. The G572S mutation is intrinsically more severe than the G584S mutation, consistent with the overall clinical presentation in the 2 small kindreds studied here. Further investigation, involving a larger number of cohorts, to test the hypothesis that in vitro phenotyping of the intrinsic severity of a given mutation will assist with risk stratification is therefore warranted.
INTRODUCTION: Mutations in the pore domain of the human ether-a-go-go-related gene (hERG) potassium channel are associated with higher risk of sudden death. However, in many kindreds clinical presentation is variable, making it hard to predict risk. We hypothesized that in vitro phenotyping of the intrinsic severity of individual mutations can assist with risk stratification. METHODS AND RESULTS: We analyzed 2 hERG pore domain mutations, G572S and G584S. Similar to 90% of hERG missense mutations, G572S-hERG subunits did not traffic to the plasma membrane but could coassemble with WT subunits and resulted in a dominant negative suppression of hERG current density. The G584S-hERG subunits traffic normally but have abnormal inactivation gating. Computer models of human ventricular myocyte action potentials (AP), incorporating Markov models of the hERG mutants, indicate that G572S-hERG channels would cause more severe AP prolongation than that seen with G584S-hERG channels. CONCLUSIONS:hERG-G572S and -G584S are 2 pore domain mutations that involve the same change in sidechain but have very different in vitro phenotypes; G572S causes a dominant negative trafficking defect, whereas G584S is the first hERG missense mutation where the cause of disease can be exclusively attributed to enhanced inactivation. The G572S mutation is intrinsically more severe than the G584S mutation, consistent with the overall clinical presentation in the 2 small kindreds studied here. Further investigation, involving a larger number of cohorts, to test the hypothesis that in vitro phenotyping of the intrinsic severity of a given mutation will assist with risk stratification is therefore warranted.
Authors: Kevin Phan; Chai Ann Ng; Erikka David; Dmitry Shishmarev; Philip W Kuchel; Jamie I Vandenberg; Matthew D Perry Journal: J Biol Chem Date: 2017-03-09 Impact factor: 5.157
Authors: Arash Sadrieh; Stefan A Mann; Rajesh N Subbiah; Luke Domanski; John A Taylor; Jamie I Vandenberg; Adam P Hill Journal: J Physiol Date: 2013-04-03 Impact factor: 5.182
Authors: Matthew D Perry; Chai Ann Ng; Kevin Phan; Erikka David; Kieran Steer; Mark J Hunter; Stefan A Mann; Mohammad Imtiaz; Adam P Hill; Ying Ke; Jamie I Vandenberg Journal: J Physiol Date: 2016-05-27 Impact factor: 5.182