Bloch V, Laroche S
J Physiol. 1985 Mar;360:215-31. doi: 10.1113/jphysiol.1985.sp015613.
The possibility that post-trial stimulation of the mesencephalic reticular formation (m.r.f.) may modulate long-term potentiation (l.t.p.) at the perforant path to dentate granule cell synapses was studied in freely moving rats. Extracellular potentials evoked in the dentate gyrus by test pulses to the perforant path were recorded before and at various delays after a series of high-frequency stimulus trains to the perforant path (ten trains of eight pulses at 400 Hz, delivered at 5 min intervals). We have compared the magnitude and duration of l.t.p. of the population spike in this control condition with that observed when a low-intensity m.r.f. stimulation was delivered 10 s after each train to the perforant path. Post-event m.r.f. stimulation enhanced the amount of l.t.p. induced by the series of high-frequency stimulus trains and prolonged its duration for several days. The size of the population spike was unaffected by repeated m.r.f. stimulation in the absence of perforant path high-frequency stimulation, or when this failed to induce significant l.t.p. The temporal gradient of efficacy of m.r.f. stimulation was investigated. M.r.f. stimulation delivered 10 s after a single high-frequency stimulation of perforant path fibres resulted in an enhanced l.t.p. of both the population excitatory post-synaptic potential (e.p.s.p.) and population spike. L.t.p. was unaffected by m.r.f. stimulation given either before, or 120 s after perforant path high-frequency stimulation. These results show that low-intensity m.r.f. stimulation enhances lasting changes in synaptic function in the dentate gyrus when delivered during a critical period following high-frequency activation of perforant path fibres. These results are discussed in the light of our previous findings on the effects of post-event m.r.f. stimulation on memory and on the development of associative changes in hippocampal multiunit activity during conditioning. It is hypothesized that l.t.p.-like mechanisms may be involved in the stabilization of neural networks by experience and that this process might be reinforced by diffuse m.r.f. activation.
在自由活动的大鼠中,研究了试验后刺激中脑网状结构(m.r.f.)是否可能调节穿通通路至齿状颗粒细胞突触处的长时程增强(l.t.p.)。在对穿通通路进行一系列高频刺激序列(以400 Hz施加十组每组八个脉冲,间隔5分钟)之前和之后的不同延迟时间,记录由穿通通路的测试脉冲在齿状回中诱发的细胞外电位。我们将这种对照条件下群体峰电位的l.t.p.幅度和持续时间与在每组穿通通路刺激后10秒施加低强度m.r.f.刺激时观察到的情况进行了比较。事件后m.r.f.刺激增强了由一系列高频刺激序列诱导的l.t.p.量,并将其持续时间延长了数天。在没有穿通通路高频刺激或未能诱导出显著l.t.p.时,重复的m.r.f.刺激对群体峰电位的大小没有影响。研究了m.r.f.刺激效果的时间梯度。在对穿通通路纤维进行单次高频刺激后10秒施加m.r.f.刺激,导致群体兴奋性突触后电位(e.p.s.p.)和群体峰电位的l.t.p.增强。穿通通路高频刺激之前或之后120秒给予m.r.f.刺激,l.t.p.不受影响。这些结果表明,在穿通通路纤维高频激活后的关键时期内施加低强度m.r.f.刺激,可增强齿状回中突触功能的持久变化。根据我们之前关于事件后m.r.f.刺激对记忆的影响以及在条件反射期间海马多单位活动中联想变化发展的研究结果,对这些结果进行了讨论。据推测,类似l.t.p.的机制可能参与通过经验对神经网络的稳定作用,并且这个过程可能会因弥散性m.r.f.激活而得到加强。