Landfield P W, Pitler T A, Applegate M D
J Neurophysiol. 1986 Sep;56(3):797-811. doi: 10.1152/jn.1986.56.3.797.
In some central systems, excitatory postsynaptic potential (EPSP) amplitude increases substantially during repetitive synaptic stimulation ("frequency potentiation"), as does the probability of spike generation. An apparently analogous phenomenon at the neuromuscular junction ("frequency facilitation") depends on residual Ca2+ in nerve terminals. However, the mechanisms of central frequency potentiation are not completely defined and it is therefore not clear whether the patterns of Ca2+-dependent synaptic plasticity are fully analogous in central and peripheral systems. In addition, an age-related deficit in hippocampal frequency potentiation has been previously described, and the degree of sensitivity of this deficit to Mg2+-to-Ca2+ balance could yield important insights into its nature. In these studies, we used the hippocampal slice preparation to examine the effects of varying Mg2+-to-Ca2+ ratios in the artificial cerebrospinal fluid (ACF) on frequency potentiation in aged and young rats. Extracellular and intracellular methods were used to assess the responses of hippocampal CA1 neurons during orthodromic stimulation of the monosynaptic Schaffer-commissural pathway. In experiment 1, frequency potentiation of the hippocampal population spike during 7-Hz stimulation was found to be significantly greater in an ACF with a high Mg2+-to-Ca2+ ratio (2.7) than in an ACF with a normal Mg2+-to-Ca2+ ratio (0.5), for both young and aged rat slices. Aged slices exhibited less frequency potentiation than young in both media. In experiment 2, the field EPSP and population spike were monitored concurrently, and the differences in Mg2+-to-Ca2+ ratio between the high Mg2+-to-Ca2+ ACF ratio (2.0) and normal Mg2+-to-Ca2+ ACF ratio (1.0) were reduced, to determine whether aged and young brains differed in sensitivity to smaller variations in Mg2+-to-Ca2+ balance. Under these conditions, the effects of high Mg2+-to-Ca2+ ratios on frequency potentiation (at 7 Hz) were found to be most pronounced in aged rat slices, particularly for potentiation of the spike. No effects were seen of age or Mg2+-to-Ca2+ ratios on presynaptic fiber volley amplitudes. Field EPSP (but not spike) amplitudes were reduced with aging, in an input-output (I/O) stimulation series at control frequency (0.2 Hz). However, the high Mg2+-to-Ca2+ ACF ratio of (2.0), which improved field EPSP frequency potentiation, did not decrease control field EPSP amplitudes in the I/O series. Therefore, the effects of high MG2+-to-Ca2+ ACF ratio on brain frequency potentiation seem to be mediated in part by mechanisms other than the classical reduction of release probability.(ABSTRACT TRUNCATED AT 400 WORDS)
在一些中枢系统中,兴奋性突触后电位(EPSP)的幅度在重复性突触刺激期间(“频率增强”)会大幅增加,产生动作电位的概率也是如此。在神经肌肉接头处一个明显类似的现象(“频率易化”)取决于神经末梢中残留的Ca2+。然而,中枢频率增强的机制尚未完全明确,因此尚不清楚Ca2+依赖性突触可塑性模式在中枢和外周系统中是否完全相似。此外,先前已经描述了海马体频率增强中与年龄相关的缺陷,这种缺陷对Mg2+与Ca2+平衡的敏感程度可能会为其本质提供重要见解。在这些研究中,我们使用海马体脑片标本,来研究人工脑脊液(ACF)中不同的Mg2+与Ca2+比例对老年和幼年大鼠频率增强的影响。采用细胞外和细胞内方法,评估在单突触的Schaffer-连合通路的正向刺激期间海马CA1神经元的反应。在实验1中,发现在Mg2+与Ca2+比例高(2.7)的ACF中,7Hz刺激期间海马群体峰电位的频率增强,对于幼年和老年大鼠脑片而言,均显著大于Mg2+与Ca2+比例正常(0.5)的ACF。在两种培养液中,老年脑片的频率增强均低于幼年脑片。在实验2中,同时监测场兴奋性突触后电位(fEPSP)和群体峰电位,并减小高Mg2+与Ca2+比例的ACF(2.0)和正常Mg2+与Ca2+比例的ACF(1.0)之间的差异,以确定老年和幼年大脑对Mg2+与Ca2+平衡较小变化的敏感性是否不同。在这些条件下,发现高Mg2+与Ca2+比例对频率增强(7Hz时)的影响在老年大鼠脑片中最为明显,尤其是对峰电位的增强。未观察到年龄或Mg2+与Ca2+比例对突触前纤维峰电位幅度有影响。在对照频率(0.2Hz)下的输入-输出(I/O)刺激系列中,场兴奋性突触后电位(但不是峰电位)幅度随年龄增长而降低。然而,高Mg2+与Ca2+比例的ACF(2.0)虽改善了场兴奋性突触后电位频率增强,但在I/O系列中并未降低对照场兴奋性突触后电位幅度。因此,高Mg2+与Ca2+比例的ACF对脑频率增强的影响似乎部分是由不同于经典的释放概率降低的机制介导的。(摘要截于400字)
