Wolfart Jakob, Roeper Jochen
Medical Research Council, Anatomical Neuropharmacology Unit, Department of Pharmacology, Oxford University, Oxford OX1 3TH, United Kingdom.
J Neurosci. 2002 May 1;22(9):3404-13. doi: 10.1523/JNEUROSCI.22-09-03404.2002.
Dopaminergic midbrain (DA) neurons display two principal activity patterns in vivo, single-spike and burst firing, the latter coding for reward-related events. We have shown recently that the small-conductance calcium-activated potassium channel SK3 controls pacemaker frequency and precision in DA neurons of the substantia nigra (SN), and previous studies have implicated SK channels in the transition to burst firing. To identify the upstream calcium sources for SK channel activation in DA SN neurons, we studied the sensitivity of SK channel-mediated afterhyperpolarization (AHP) currents to inhibitors of different types of voltage-gated calcium channels in perforated patch-clamp recordings. Cobalt-sensitive AHP currents were not affected by L-type and P/Q-type calcium channel inhibitors and were reduced slightly (26%) by the N-type channel inhibitor omega-conotoxin-GVIA. In contrast, AHP currents were blocked substantially (85-94%) by micromolar concentrations of nickel (IC50, 33.75 microm) and mibefradil (IC50, 4.83 microm), indistinguishable from the nickel and mibefradil sensitivities of T-type calcium currents (IC50 values, 33.86 and 4.59 microm, respectively). These results indicate that SK channels are activated selectively via T-type calcium channels in DA SN neurons. Consequently, SK currents displayed use-dependent inactivation with similar time constants when compared with those of T-type calcium currents and generated a transient rebound inhibition. Both SK and T-type channels were essential for the stability of spontaneous pacemaker activity, and, in some DA SN neurons, T-type channel inhibition was sufficient to induce intrinsic burst firing. The functional coupling of SK to T-type channels has important implications for the temporal integration of synaptic input and might help to understand how DA neurons switch between pacemaker and burst-firing modes in vivo.
多巴胺能中脑(DA)神经元在体内表现出两种主要活动模式,即单峰放电和爆发式放电,后者编码与奖励相关的事件。我们最近发现,小电导钙激活钾通道SK3控制黑质(SN)中DA神经元的起搏器频率和精度,并且先前的研究表明SK通道参与了向爆发式放电的转变。为了确定DA SN神经元中SK通道激活的上游钙源,我们在穿孔膜片钳记录中研究了SK通道介导的超极化后电位(AHP)电流对不同类型电压门控钙通道抑制剂的敏感性。对钴敏感的AHP电流不受L型和P/Q型钙通道抑制剂的影响,而N型通道抑制剂ω-芋螺毒素-GVIA使其略有降低(26%)。相比之下,微摩尔浓度的镍(IC50,33.75 μM)和米贝拉地尔(IC50,4.83 μM)可使AHP电流大幅阻断(85 - 94%),这与T型钙电流对镍和米贝拉地尔的敏感性(IC50值分别为33.86和4.59 μM)无差异。这些结果表明,SK通道在DA SN神经元中通过T型钙通道被选择性激活。因此,与T型钙电流相比,SK电流表现出具有相似时间常数的使用依赖性失活,并产生短暂的反弹抑制。SK通道和T型通道对于自发起搏器活动的稳定性均至关重要,并且在一些DA SN神经元中,T型通道抑制足以诱导内在爆发式放电。SK通道与T型通道的功能耦合对于突触输入的时间整合具有重要意义,并且可能有助于理解DA神经元在体内如何在起搏器模式和爆发式放电模式之间切换。