School of Biomedical Sciences and Pharmacy, Faculty of Health and Hunter Medical Research Institute, The University of Newcastle, Callaghan, NSW 2308, Australia.
Neuroscience. 2010 Sep 29;170(1):348-60. doi: 10.1016/j.neuroscience.2010.06.040. Epub 2010 Jun 23.
Spontaneous activity in medial vestibular nucleus (MVN) neurons is modulated by synaptic inputs. These inputs are crucial for maintaining gaze and posture and contribute to vestibular compensation after lesions of peripheral vestibular organs. We investigated how chronically attenuated glycinergic input affects excitability of MVN neurons. To this end we used three mouse strains (spastic, spasmodic, and oscillator), with well-characterized naturally occurring mutations in the inhibitory glycine receptor (GlyR). First, using whole-cell patch-clamp recordings, we demonstrated that the amplitude of the response to rapidly applied glycine was dramatically reduced by 25 to 90% in MVN neurons from mutant mice. We next determined how reduced GlyR function affected MVN neuron output. Neurons were classified using two schemas: (1) the shape of their action potential afterhyperpolarization (AHP); and (2) responses to hyperpolarizing current injection. In the first schema, neurons were classified as types A, B and C. The prevalence of type C neurons in the mutant strains was significantly increased. In the second schema, the proportion of neurons lacking post inhibitory rebound firing (PRF-deficient) was increased. In both schemas an increase in AHP amplitude was a common feature of the augmented neuron group (type C, PRF-deficient) in the mutant strains. We suggest increased AHP amplitude reduces overall excitability in the MVN and thus maintains network function in an environment of reduced glycinergic input.
前庭神经核(MVN)神经元的自发性活动受到突触输入的调节。这些输入对于维持凝视和姿势至关重要,并有助于外周前庭器官损伤后的前庭代偿。我们研究了慢性减弱的甘氨酸能输入如何影响 MVN 神经元的兴奋性。为此,我们使用了三种具有特征性的自然发生突变的抑制性甘氨酸受体(GlyR)的小鼠品系(痉挛型、痉挛性抽搐型和振荡器型)。首先,使用全细胞膜片钳记录,我们证明了突变小鼠 MVN 神经元对快速施加甘氨酸的反应幅度显著降低了 25%至 90%。接下来,我们确定了 GlyR 功能降低如何影响 MVN 神经元的输出。使用两种方案对神经元进行分类:(1)动作电位后超极化(AHP)的形状;(2)对超极化电流注入的反应。在第一种方案中,神经元被分为 A、B 和 C 型。突变株中 C 型神经元的患病率显著增加。在第二种方案中,缺乏抑制后反弹放电(PRF 缺乏)的神经元比例增加。在这两种方案中,AHP 幅度的增加是突变株中增强神经元群(C 型、PRF 缺乏)的共同特征。我们认为,AHP 幅度的增加降低了 MVN 的整体兴奋性,从而在甘氨酸能输入减少的环境中维持了网络功能。
