Exocytosis from large dense cored vesicles as a mechanism for neuropeptide release in the peripheral and central nervous system.

Scanning electron microscopy Pub Date : 1986-01-01
A Thureson-Klein, R L Klein, P C Zhu
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Abstract

Nerve terminals often contain morphologically distinct populations of large (75-110 nm) and small (45-55 nm) vesicles. The small vesicles are speculated to account for release of transmitter quanta as they accumulate at presynaptic membranes. Large vesicles can co-store neuropeptides and classical transmitters but their function in neurotransmission has been disputed because they do not appear to accumulate at chemical synapses. However, there is now evidence that the large vesicles play a role in neurotransmission or its modulation even though they may not be eminently involved in synaptic release. Thus, exocytosis occurs along the synapse-lacking membranes of peripheral noradrenergic varicosities. Large vesicles may continue to function in peptide release even after the classical transmitter has been depleted as demonstrated in the pig vas deferens. Three days of reserpine administration causes a parallel loss of noradrenaline and small vesicle contents but does not decrease enkephalin-like immunoreactivity or large vesicle electron density. In the central nervous system of the rat, where substance P and enkephalin have been localized to large vesicles, exocytosis occurs from several types of terminals. The large vesicles appear preferentially to release their contents at morphologically non-specialized sites even when characteristic synapses are present. Thus different mechanisms of transmitter and neuropeptide release may coexist. The nonsynaptic discharge may allow substances to diffuse over a wider distance whereas release into a synaptic cleft could restrict receptor interaction.

外周和中枢神经系统神经肽释放的一种机制:来自大而致密的囊泡的胞吐。
神经末梢通常包含形态不同的大(75-110纳米)和小(45-55纳米)囊泡。据推测,这些小囊泡可以解释在突触前膜积聚的递质量子的释放。大囊泡可以共同储存神经肽和经典递质,但它们在神经传递中的功能一直存在争议,因为它们似乎不积聚在化学突触上。然而,现在有证据表明,大囊泡在神经传递或其调节中发挥作用,即使它们可能不显著参与突触释放。因此,胞外分泌沿着外周去肾上腺素能性静脉曲张的突触缺乏膜发生。在猪输精管中证明,即使在经典递质被耗尽后,大囊泡也可能继续在肽释放中发挥作用。给予3天利血平可引起去甲肾上腺素和小囊泡含量的平行损失,但不降低脑啡肽样免疫反应性或大囊泡电子密度。在大鼠的中枢神经系统中,P物质和脑啡肽已定位于大囊泡,在几种末梢发生胞外分泌。即使存在特征性突触,大囊泡似乎也优先在形态上非特化的部位释放其内容物。因此,不同的递质和神经肽释放机制可能共存。非突触放电可能允许物质扩散更大的距离,而释放到突触间隙可能限制受体的相互作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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