신생흰쥐 척수후근신경절 세포에서 전압의존성 K+ 전류의 동정

Characterization of Voltage-Gated Potassium Currents in Dorsal Root Ganglion Neurons of Neonatal Rats

<P> Dorsal root ganglion (DRG) is composed of neuronal cell bodies of primary afferents with diverse functions. Various types of ion channels present on DRG neurons may reflect those functions. In the present study, voltage-gated potassium currents in DRG neurons of neonatal rats were characterized by whole-cell voltage clamp method. Two types of delayed rectifier and three types of transient potassium currents were identified according to their electrophysiological properties. The delayed rectifier currents were named I<SUB>Ke</SUB> (<I>e</I>arly inactivating) and I<SUB>Kl</SUB> (<I>l</I>ate inactivating). Steady state inactivation of I<SUB>Ke</SUB> began from -100 mV lasting until &#8291;20 mV. I<SUB>Kl</SUB> could be distinguished from I<SUB>Ke</SUB> by its inactivation voltage range, from -70 mV to +10 mV. Three transient currents were named I<SUB>Af</SUB> (<I>f</I>ast inactivation), I<SUB>Ai</SUB> (<I>i</I>ntermediate inactivation kinetics), and I<SUB>As</SUB> (<I>s</I>low inactivation). I<SUB>Af</SUB> showed fast inactivation with time constant of 10.6±2.0 msec, I<SUB>Ai</SUB> of 36.9±13.9 msec, and I<SUB>As</SUB> of 60.6±2.9 msec at &#8290;30 mV, respectively. They also had distinct steady state inactivation range of each. Each cell expressed diverse combination of potassium currents. The cells most frequently observed were those which expressed both I<SUB>Kl</SUB> and I<SUB>Af</SUB>, and they had large diameters. The cells expressing I<SUB>Ke</SUB> and expressing I<SUB>Ke</SUB>, I<SUB>Ai</SUB>, and I<SUB>As</SUB> usually had small diameters. Judging from cell diameter, capsaicin sensitivity or action potential duration, candidates for nociceptor were the cells expressing I<SUB>Ke</SUB>, expressing I<SUB>Ke</SUB> and I<SUB>Ai</SUB>, and expressing I<SUB>Ke</SUB> and I<SUB>As</SUB>. The types and distribution of potassium currents in neonatal rat DRG were similar to those of adult rat DRG (Gold et al, 1996b).