体外动作电位与神经垂体激素释放
Action potentials and release of neurohypophysial hormones in vitro.
作者信息
Dreifuss J J, Kalnins I, Kelly J S, Ruf K B
出版信息
J Physiol. 1971 Jul;215(3):805-17. doi: 10.1113/jphysiol.1971.sp009499.
Abstract
- Isolated rat neurohypophyses were studied in vitro and the hormones released on electrical stimulation of the pituitary stalk or on exposure to excess potassium were estimated by a milk-ejection assay.2. The stalk was stimulated with trains of 500 stimuli, or multiples thereof, applied at different frequencies. Below frequencies of ca. 35 c/s, hormone release was found to depend on the total number of stimuli applied as well as on the frequency of stimulation. Above ca. 35 c/s, identical numbers of stimuli were progressively less effective as the frequency of stimulation was increased, and the dependence of the hormone output on the total number of stimuli was less apparent.3. The amplitude of the compound action potential recorded from the neurohypophysis following electrical stimulation of the stalk was found to decrease as a function of the frequency of stimulation. Stimulation at 50 c/s reduced its amplitude about sevenfold within 30 sec.4. The addition of tetrodotoxin (TTX) to the incubation media abolished the compound action potential recorded from the neural lobe as well as the release of hormones evoked by electrical stimulation. Resting release, however, was unaffected by TTX.5. In TTX-treated neural lobes, excess potassium was still effective in eliciting graded secretory responses. This indicates the independence of the release process from the action potential generating mechanism and suggests that TTX-paralysed preparations represent a useful model for the study of hormone release in the absence of conducted action potentials.6. The release of hormones from the neurohypophysis and the release of neurotransmitters at chemical synapses both depend on the entry of calcium into the nerve terminals following their depolarization by invading action potentials. In both systems, experimental separation of the release mechanism can be achieved by the use of TTX. These and other parallels suggest that the release process is similar.
摘要
对离体大鼠神经垂体进行了体外研究,并通过催乳反射试验评估了电刺激垂体柄或暴露于过量钾时释放的激素。
以不同频率施加500次刺激或其倍数的刺激序列来刺激垂体柄。在约35次/秒以下的频率时,发现激素释放取决于施加的刺激总数以及刺激频率。在约35次/秒以上,随着刺激频率增加,相同数量的刺激效果逐渐减弱,且激素输出对刺激总数的依赖性不太明显。
发现电刺激垂体柄后从神经垂体记录的复合动作电位的幅度随刺激频率的增加而降低。以50次/秒刺激时,其幅度在30秒内降低约7倍。
向孵育培养基中添加河豚毒素(TTX)可消除从神经叶记录的复合动作电位以及电刺激诱发的激素释放。然而,静息释放不受TTX影响。
在经TTX处理的神经叶中,过量钾仍能有效引发分级分泌反应。这表明释放过程独立于动作电位产生机制,并表明TTX麻痹的制剂是研究无传导动作电位时激素释放的有用模型。
神经垂体激素的释放和化学突触处神经递质的释放都依赖于钙在动作电位侵入使神经末梢去极化后进入神经末梢。在这两个系统中,可通过使用TTX实现释放机制的实验分离。这些以及其他相似之处表明释放过程是相似的。
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