Synapses: Multitasking Global Players in the Brain

Q3 Medicine

Neuroforum Pub Date : 2019-12-05 DOI:10.1515/nf-2019-0015

J. Lübke, A. Rollenhagen

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Abstract

Abstract Synapses are key elements in the communication between neurons in any given network of the normal adult, developmental and pathologically altered brain. Synapses are composed of nearly the same structural subelements: a presynaptic terminal containing mitochondria with an ultrastructurally visible density at the pre- and postsynaptic apposition zone. The presynaptic density is composed of a cocktail of various synaptic proteins involved in the binding, priming and docking of synaptic vesicles inducing synaptic transmission. Individual presynaptic terminals (synaptic boutons) contain a couple of hundred up to thousands of synaptic vesicles. The pre- and postsynaptic densities are separated by a synaptic cleft. The postsynaptic density, also containing various synaptic proteins and more importantly various neurotransmitter receptors and their subunits specifically composed and arranged at individual synaptic complexes, reside at the target structures of the presynaptic boutons that could be somata, dendrites, spines or initial segments of axons. Beside the importance of the network in which synapses are integrated, their individual structural composition critically determines the dynamic properties within a given connection or the computations of the entire network, in particular, the number, size and shape of the active zone, the structural equivalent to a functional neurotransmitter release site, together with the size and organization of the three functionally defined pools of synaptic vesicles, namely the readily releasable, the recycling and the resting pool, are important structural subelements governing the ‘behavior’ of synaptic complexes within a given network such as the cortical column. In the late last century, neuroscientists started to generate quantitative 3D-models of synaptic boutons and their target structures that is one possible way to correlate structure with function, thus allowing reliable predictions about their function. The re-introduction of electron microscopy (EM) as an important tool achieved by modern high-end, high-resolution transmission-EM, focused ion beam scanning-EM, CRYO-EM and EM-tomography have enormously improved our knowledge about the synaptic organization of the brain not only in various animal species, but also allowed new insights in the ‘microcosms’ of the human brain in health and disease.

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突触：大脑中的多任务全局参与者

摘要突触是正常成年、发育和病理改变大脑中任何特定网络中神经元之间交流的关键元件。突触由几乎相同的结构亚元件组成：突触前末端含有线粒体，在突触前和突触后并置区具有超微结构可见的密度。突触前密度由各种突触蛋白的混合物组成，这些突触蛋白参与诱导突触传递的突触小泡的结合、启动和对接。单个突触前终端（突触突）包含几百到数千个突触小泡。突触前和突触后的密度被突触间隙分开。突触后密度也包含各种突触蛋白，更重要的是，各种神经递质受体及其亚基专门组成和排列在单个突触复合体中，位于突触前突的目标结构，可能是胞体、树突、棘或轴突的初始段。除了突触整合在其中的网络的重要性之外，它们各自的结构组成关键地决定了给定连接内的动态特性或整个网络的计算，特别是活性区的数量、大小和形状，相当于功能性神经递质释放位点的结构，再加上三个功能定义的突触小泡池（即易释放池、再循环池和静息池）的大小和组织，是控制给定网络（如皮层柱）内突触复合体“行为”的重要结构子元素。上世纪末，神经科学家开始生成突触发作及其目标结构的定量3D模型，这是将结构与功能联系起来的一种可能方式，从而可以可靠地预测其功能。电子显微镜（EM）作为现代高端、高分辨率透射EM、聚焦离子束扫描EM、CRYO-EM和EM断层扫描实现的重要工具的重新引入，极大地提高了我们对大脑突触组织的认识，不仅在各种动物物种中，但也为人类大脑在健康和疾病方面的“微观世界”提供了新的见解。

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来源期刊

Neuroforum NEUROSCIENCES-

CiteScore

1.70

自引率

0.00%

发文量

期刊介绍： Neuroforum publishes invited review articles from all areas in neuroscience. Readership includes besides basic and medical neuroscientists also journalists, practicing physicians, school teachers and students. Neuroforum reports on all topics in neuroscience – from molecules to the neuronal networks, from synapses to bioethics.