A short history of the second messenger concept in neurons and lessons from long lasting changes in two neuronal systems producing afterdischarge and circadian oscillations.
{"title":"A short history of the second messenger concept in neurons and lessons from long lasting changes in two neuronal systems producing afterdischarge and circadian oscillations.","authors":"F Strumwasser","doi":"","DOIUrl":null,"url":null,"abstract":"<p><p>This paper gives a short historical summary of how the second messenger concept, introduced by Earl Sutherland some three decades ago, has been refined and applied by neurobiologists to account for long-lasting changes in the membrane properties of certain neurons. Such refinements in the second messenger hypothesis have application to two specific long-lasting changes in neurons in Aplysia. In the bag cell neuroendocrine system, a brief synaptic input induces an afterdischarge lasting about 30 minutes. Both cAMP-dependent and Ca2+ and phospholipid-dependent protein kinases are activated by the synaptic input and a variety of potassium and calcium channels are modulated. In the eye of Aplysia a spontaneous circadian modulation of ion channels takes place over a twenty-four hour period. In addition phase shifts of this circadian oscillator are mediated, for light by cGMP and for serotonin by cAMP. The circadian oscillator, unlike the bag cell afterdischarge mechanism, is sensitive to ionizing radiation as well as to transcriptional inhibitors. Evidence is presented that specific proteins are synthesized at different times in the circadian cycle. One of these proteins (m.w. 41.9, pI 5.5) accumulates linearly with time of day, resembling a sawtooth oscillator. This protein may be the driver for the circadian oscillation itself. The role of second messengers in various forms of plasticity in neuronal systems (sensitization, long-term potentiation, long-term depression, \"learning\") may just be part of a very widespread mechanism by which neurons and other cells can generate long-lasting changes in membrane and other cellular properties with brief inputs (synaptic, hormonal) that are of some special adaptive value to the organism.</p>","PeriodicalId":14735,"journal":{"name":"Journal de physiologie","volume":"83 3","pages":"246-54"},"PeriodicalIF":0.0000,"publicationDate":"1988-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal de physiologie","FirstCategoryId":"1085","ListUrlMain":"","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
This paper gives a short historical summary of how the second messenger concept, introduced by Earl Sutherland some three decades ago, has been refined and applied by neurobiologists to account for long-lasting changes in the membrane properties of certain neurons. Such refinements in the second messenger hypothesis have application to two specific long-lasting changes in neurons in Aplysia. In the bag cell neuroendocrine system, a brief synaptic input induces an afterdischarge lasting about 30 minutes. Both cAMP-dependent and Ca2+ and phospholipid-dependent protein kinases are activated by the synaptic input and a variety of potassium and calcium channels are modulated. In the eye of Aplysia a spontaneous circadian modulation of ion channels takes place over a twenty-four hour period. In addition phase shifts of this circadian oscillator are mediated, for light by cGMP and for serotonin by cAMP. The circadian oscillator, unlike the bag cell afterdischarge mechanism, is sensitive to ionizing radiation as well as to transcriptional inhibitors. Evidence is presented that specific proteins are synthesized at different times in the circadian cycle. One of these proteins (m.w. 41.9, pI 5.5) accumulates linearly with time of day, resembling a sawtooth oscillator. This protein may be the driver for the circadian oscillation itself. The role of second messengers in various forms of plasticity in neuronal systems (sensitization, long-term potentiation, long-term depression, "learning") may just be part of a very widespread mechanism by which neurons and other cells can generate long-lasting changes in membrane and other cellular properties with brief inputs (synaptic, hormonal) that are of some special adaptive value to the organism.
本文简要概述了30年前厄尔·萨瑟兰(Earl Sutherland)提出的第二信使概念是如何被神经生物学家改进和应用于解释某些神经元膜特性的长期变化的。第二信使假说的这种改进适用于澳大利亚神经元的两种特定的持久变化。在袋细胞神经内分泌系统中,短暂的突触输入会引起持续约30分钟的后放电。camp依赖性、Ca2+和磷脂依赖性蛋白激酶都被突触输入激活,多种钾和钙通道被调节。在澳大利亚眼内,离子通道的自发昼夜节律调节在24小时内发生。此外,这种昼夜节律振荡器的相移是由cGMP介导的,而5 -羟色胺是由cAMP介导的。与袋细胞放电后机制不同,昼夜节律振荡器对电离辐射和转录抑制剂都很敏感。有证据表明,特定的蛋白质是在昼夜周期的不同时间合成的。其中一种蛋白质(m.w.41.9, pI 5.5)随时间线性累积,类似于锯齿振荡器。这种蛋白质可能是昼夜节律振荡本身的驱动因素。第二信使在神经元系统中各种形式的可塑性(致敏、长期增强、长期抑制、“学习”)中的作用可能只是一种非常广泛的机制的一部分,通过这种机制,神经元和其他细胞可以通过短暂的输入(突触、激素)在膜和其他细胞特性中产生持久的变化,这些变化对生物体具有某种特殊的适应价值。