Expression and kinetic properties of Na + currents in rat cardiac dorsal root ganglion neurons

Abstract

The expression and properties of voltage-gated Na + currents in cardiac dorsal root ganglion (DRG) neurons were assessed in this study. Cardiac DRG neurons were labelled by injecting the Fast Blue fluorescent tracer into the pericardium. Recordings were performed from 138 cells. Voltage-dependent Na + currents were found in 115 neurons. There were 109 neurons in which both tetrodotoxin-sensitive (TTX-S, blocked by 1 μM of TTX) and tetrodotoxin-resistant (TTX-R, insensitive to 1 μM of TTX) Na + currents were present. Five cells expressed TTX-R current only and one cell only the TTX-S current. The kinetic properties of Na + currents and action potential waveform parameters were measured in neurons with cell membrane capacitance ranging from 15 to 75 pF. The densities of TTX-R (110.0 pA/pF) and TTX-S (126.1 pA/pF) currents were not significantly different. Current threshold was significantly higher for TTX-R (−34 mV) than for TTX-S (−40.4 mV) currents. V 1/2 of activation for TTX-S current (−19.6 mV) was significantly more negative than for TTX-R current (−9.2 mV), but k factors did not differ significantly. V 1/2 and the k constant for inactivation for TTX-S currents were −35.6 and −5.7 mV, respectively. These values were significantly lower than those recorded for TTX-R current for which V 1/2 and k were −62.3 and −7.7 mV, respectively. The action potential threshold was lower, the 10–90% rise time and potential width were shorter before than after the application of TTX. Based on this we drew the conclusion that action potential recorded before adding tetrodotoxin was mainly TTX-S current dependent, while the action potential recorded after the application of toxin was TTX-R current dependent. We also found 23 cells with mean membrane capacitance ranging from 12 to 35 pF (the smallest labelled DRG cells found in this study) that did not express the Na + current. The function of these cells is unclear. We conclude that the overwhelming majority of cardiac dorsal root ganglion neurons in which voltage-dependent Na + currents were present, exhibited both TTX-S and TTX-R Na + currents with remarkably similar expression and kinetic properties.