AIMS: Auditory stimulus-induced long QT syndrome (LQTS) is almost exclusively linked to mutations in the hERG potassium channel, which generates the I Kr ventricular repolarization current. Here, a young woman with prior episodes of auditory stimulus-induced syncope presented with LQTS and ventricular fibrillation (VF) with hypomagnesaemia and hypocalcaemia after completing a marathon, followed by subsequent VF with hypokalaemia. The patient was found to harbour a KCNE2 gene mutation encoding a T10M amino acid substitution in MiRP1, an ancillary subunit that co-assembles with and functionally modulates hERG. Other family members with the mutation were asymptomatic, and the proband had no mutations in hERG or other LQTS-linked cardiac ion channel genes. The T10M mutation was absent from 578 unrelated, ethnically matched control chromosomes analysed here and was previously described only once-in an LQTS patient-but not functionally characterized. METHODS AND RESULTS: T10M-MiRP1-hERG currents were assessed using whole-cell voltage clamp of transfected Chinese Hamster ovary cells. T10M-MiRP1-hERG channels showed <or=80% reduced tail current, left-shifted steady-state inactivation, and 50% slower recovery from inactivation when compared with wild-type channels, with mixed wild-type/T10M channels displaying an intermediate phenotype. Lowering bath K+ concentration reduced wild-type and T10M currents equivalently. CONCLUSION: Data suggest a mechanism for reduced penetrance, inherited arrhythmia in which baseline I Kr current reduction by the T10M mutation is exacerbated by superimposition of arrhythmogenic substrates such as auditory stimuli, or electrolyte disturbances that reduce I Kr (hypokalaemia) or otherwise lower the ventricular threshold for fibrillation (hypomagnesaemia and hypocalcaemia). This first example of a MiRP1 mutation associated with auditory stimulus-induced arrhythmia is supportive of the hypothesis that MiRP1 regulates hERG in the human heart.
AIMS: Auditory stimulus-induced long QT syndrome (LQTS) is almost exclusively linked to mutations in the hERG potassium channel, which generates the I Kr ventricular repolarization current. Here, a young woman with prior episodes of auditory stimulus-induced syncope presented with LQTS and ventricular fibrillation (VF) with hypomagnesaemia and hypocalcaemia after completing a marathon, followed by subsequent VF with hypokalaemia. The patient was found to harbour a KCNE2 gene mutation encoding a T10M amino acid substitution in MiRP1, an ancillary subunit that co-assembles with and functionally modulates hERG. Other family members with the mutation were asymptomatic, and the proband had no mutations in hERG or other LQTS-linked cardiac ion channel genes. The T10M mutation was absent from 578 unrelated, ethnically matched control chromosomes analysed here and was previously described only once-in an LQTS patient-but not functionally characterized. METHODS AND RESULTS:T10M-MiRP1-hERG currents were assessed using whole-cell voltage clamp of transfected Chinese Hamster ovary cells. T10M-MiRP1-hERG channels showed <or=80% reduced tail current, left-shifted steady-state inactivation, and 50% slower recovery from inactivation when compared with wild-type channels, with mixed wild-type/T10M channels displaying an intermediate phenotype. Lowering bath K+ concentration reduced wild-type and T10M currents equivalently. CONCLUSION: Data suggest a mechanism for reduced penetrance, inherited arrhythmia in which baseline I Kr current reduction by the T10M mutation is exacerbated by superimposition of arrhythmogenic substrates such as auditory stimuli, or electrolyte disturbances that reduce I Kr (hypokalaemia) or otherwise lower the ventricular threshold for fibrillation (hypomagnesaemia and hypocalcaemia). This first example of a MiRP1 mutation associated with auditory stimulus-induced arrhythmia is supportive of the hypothesis that MiRP1 regulates hERG in the human heart.
Authors: Zhaoyang Hu; Ritu Kant; Marie Anand; Elizabeth C King; Trine Krogh-Madsen; David J Christini; Geoffrey W Abbott Journal: Circ Cardiovasc Genet Date: 2014-01-08
Authors: Elena Burashnikov; Ryan Pfeiffer; Héctor Barajas-Martinez; Eva Delpón; Dan Hu; Mayurika Desai; Martin Borggrefe; Michel Häissaguerre; Ronald Kanter; Guido D Pollevick; Alejandra Guerchicoff; Ruben Laiño; Mark Marieb; Koonlawee Nademanee; Gi-Byoung Nam; Roberto Robles; Rainer Schimpf; Dwight D Stapleton; Sami Viskin; Stephen Winters; Christian Wolpert; Samuel Zimmern; Christian Veltmann; Charles Antzelevitch Journal: Heart Rhythm Date: 2010-10-14 Impact factor: 6.343
Authors: Miriam S Reuter; Susan Walker; Bhooma Thiruvahindrapuram; Joe Whitney; Iris Cohn; Neal Sondheimer; Ryan K C Yuen; Brett Trost; Tara A Paton; Sergio L Pereira; Jo-Anne Herbrick; Richard F Wintle; Daniele Merico; Jennifer Howe; Jeffrey R MacDonald; Chao Lu; Thomas Nalpathamkalam; Wilson W L Sung; Zhuozhi Wang; Rohan V Patel; Giovanna Pellecchia; John Wei; Lisa J Strug; Sherilyn Bell; Barbara Kellam; Melanie M Mahtani; Anne S Bassett; Yvonne Bombard; Rosanna Weksberg; Cheryl Shuman; Ronald D Cohn; Dimitri J Stavropoulos; Sarah Bowdin; Matthew R Hildebrandt; Wei Wei; Asli Romm; Peter Pasceri; James Ellis; Peter Ray; M Stephen Meyn; Nasim Monfared; S Mohsen Hosseini; Ann M Joseph-George; Fred W Keeley; Ryan A Cook; Marc Fiume; Hin C Lee; Christian R Marshall; Jill Davies; Allison Hazell; Janet A Buchanan; Michael J Szego; Stephen W Scherer Journal: CMAJ Date: 2018-02-05 Impact factor: 8.262