Abstract
In the heart, TRPM4 is most abundantly distributed in the conduction system. Previously, a single mutation, ‘E7K’, was identified in its distal N-terminus to cause conduction disorder because of enhanced cell-surface expression. It remains, however, unclear how this expression increase leads to conduction failure rather than abnormally enhanced cardiac excitability. To address this issue theoretically, we mathematically formulated the gating kinetics of the E7K-mutant TRPM4 channel by a combined use of voltage jump analysis and ionomycin-perforated cell-attached recording technique and incorporated the resultant rate constants of opening and closing into a human Purkinje fiber single-cell action potential (AP) model (Trovato model) to perform 1D-cable simulations. The results from TRPM4 expressing HEK293 cells showed that as compared with the wild-type, the open state is much preferred in the E7K mutant with increased voltage-and Ca2+-sensitivities. These theoretical predictions were confirmed by power spectrum and single channel analyses of expressed wild-type and E7K-mutant TRPM4 channels. In our modified Trovato model, the facilitated opening of the E7K mutant channel markedly prolonged AP duration with concomitant depolarizing shifts of the resting membrane potential in a manner dependent on the channel density (or maximal activity). This was, however, little evident in the wild-type TRPM4 channel. Moreover, 1D-cable simulations with the modified Trovato model revealed that increasing the density of E7K (but not of wild-type) TRPM4 channels progressively reduced AP conduction velocity eventually culminating in complete conduction block. These results clearly suggest the brady-arrhythmogenicity of the E7K mutant channel which likely results from its pathologically enhanced activity.
Highlights
TRPM4 is a melastatin subfamily member of the transient receptor potential (TRP)superfamily and acts as a plasmalemmal route selective for Na+ influx and K+ efflux.In physiological settings, the TRPM4 channel is directly activated by intracellular Ca2+elevation upon transmembrane and intracellular Ca2+ mobilizations
The TRPM4 channel is directly activated by intracellular Ca2+
Dependency of β which stay low over the whole Vm and [Ca2+ ]i ranges. These results indicate a preferred sojourn in the open state of E7K channel due to accelerated closed-to-open state (C-O) transition and greatly suppressed O-C transition
Summary
TRPM4 is a melastatin subfamily member of the transient receptor potential (TRP)superfamily and acts as a plasmalemmal route selective for Na+ influx and K+ efflux.In physiological settings, the TRPM4 channel is directly activated by intracellular Ca2+elevation upon transmembrane and intracellular Ca2+ mobilizations. TRPM4 is a melastatin subfamily member of the transient receptor potential (TRP). Superfamily and acts as a plasmalemmal route selective for Na+ influx and K+ efflux. The TRPM4 channel is directly activated by intracellular Ca2+. Elevation upon transmembrane and intracellular Ca2+ mobilizations. The distribution of this channel protein is ubiquitous across the whole body including both excitable (neurons, muscles) and non-excitable (secretory glands, blood cells, etc.) tissues. The TRPM4 channel is regarded as the most likely molecular identification of a broad class of Ca2+ -activated nonselective cation channels [1]. Permeability, major consequences of TRPM4 channel activation are thought to be two-fold, i.e., membrane depolarization and intracellular Na+ loading. In non-excitable cells, the depolarizing effect of TRPM4 channel activation reduces non-voltage-gated Ca2+
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
