Núñez-Abades P A, Pattillo J M, Hodgson T M, Cameron W E
Department of Neuroscience, University of Pittsburgh, Pittsburgh, Pennsylvania 15260, USA.
J Neurophysiol. 2000 Nov;84(5):2317-29. doi: 10.1152/jn.2000.84.5.2317.
The contribution of synaptic input to input resistance was examined in 208 developing genioglossal motoneurons in 3 postnatal age groups (5-7 day, 13-16 day, and 18-24 day) using sharp electrode recording in a slice preparation of the rat brain stem. High magnesium (Mg(2+); 6 mM) media generated significant increases (21-38%) in both the input resistance (R(n)) and the first time constant (tau(0)) that were reversible. A large percent of the conductance blocked by high Mg(2+) was also sensitive to tetrodotoxin (TTX). Little increase in resistance was attained by adding blockers of specific amino acid (glutamate, glycine, and GABA) transmission over that obtained with the high Mg(2+). Comparing across age groups, there was a significantly larger percent change in R(n) with the addition of high Mg(2+) at postnatal days 13 to 15 (P13-15; 36%) than that found at P5-6 (21%). Spontaneous postsynaptic potentials were sensitive to the combined application of glycine receptor antagonist, strychnine, and the GABA(A) receptor antagonist, bicuculline. Application of either 10 microM strychnine or bicuculline separately produced a reversible increase in both R(n) and tau(0). Addition of 10 microM bicuculline to a strychnine perfusate failed to further increase either R(n) or tau(0). The strychnine/bicuculline-sensitive component of the total synaptic conductance increased with age so that this form of neurotransmission constituted the majority (>60%) of the observed percent decrease in R(n) and tau(0) in the oldest age group. The proportion of change in tau(0) relative to R(n) following strychnine or high magnesium perfusate varied widely from cell to cell and from age to age without pattern. Based on a model from the literature, this pattern indicates a nonselective distribution of the blocked synaptic conductances over the cell body and dendrites. Taken together, the fast inhibitory synapses (glycine, GABA(A)) play a greater role in determining cell excitability in developing brain stem motoneurons as postnatal development progresses. These findings suggest that synaptically mediated conductances effect the membrane behavior of developing motoneurons.
在大鼠脑干切片标本中,使用尖锐电极记录法,对3个出生后年龄组(5 - 7日龄、13 - 16日龄和18 - 24日龄)的208个发育中的颏舌肌运动神经元的突触输入对输入电阻的贡献进行了研究。高镁(Mg(2 +);6 mM)培养基使输入电阻(R(n))和第一时间常数(tau(0))均显著增加(21% - 38%),且这种增加是可逆的。被高镁阻断的大部分电导也对河豚毒素(TTX)敏感。与高镁处理相比,添加特定氨基酸(谷氨酸、甘氨酸和GABA)传递的阻断剂后,电阻增加幅度很小。在不同年龄组之间进行比较,出生后第13至15天(P13 - 15;36%)添加高镁时R(n)的百分比变化显著大于出生后第5至6天(21%)。自发性突触后电位对甘氨酸受体拮抗剂士的宁和GABA(A)受体拮抗剂荷包牡丹碱的联合应用敏感。单独应用10 microM士的宁或荷包牡丹碱均可使R(n)和tau(0)产生可逆性增加。在士的宁灌流液中添加10 microM荷包牡丹碱未能进一步增加R(n)或tau(0)。总突触电导中对士的宁/荷包牡丹碱敏感的成分随年龄增加,因此在最年长的年龄组中,这种神经传递形式构成了观察到的R(n)和tau(0)百分比下降的大部分(>60%)。士的宁或高镁灌流后,tau(0)相对于R(n)的变化比例在不同细胞之间以及不同年龄之间差异很大,且无规律可循。根据文献中的一个模型,这种模式表明被阻断的突触电导在细胞体和树突上呈非选择性分布。综上所述,随着出生后发育的进行快速抑制性突触(甘氨酸、GABA(A))在决定发育中的脑干运动神经元的细胞兴奋性方面发挥着更大的作用。这些发现表明,突触介导的电导影响发育中运动神经元的膜行为。
