Díaz Elva
Department of Pharmacology; UC Davis School of Medicine; Davis, CA USA.
Commun Integr Biol. 2010 Jul;3(4):347-9. doi: 10.4161/cib.3.4.11765.
Excitatory synapses are composed of several specialized domains including the presynaptic bouton containing several hundred synaptic vesicles (svs), the presynaptic active zone where svs dock and fuse with the plasma membrane, and the juxtaposed postsynaptic density (psd) composed of an electron dense meshwork of proteins including nmda and ampa receptors, ion channels, and various signaling components. cell adhesion molecules (cams) extend across the synaptic cleft to stabilize this macromolecular complex. during development of the central nervous system (cns), certain cams also serve as inductive signals that trigger the establishment of pre- and postsynaptic specializations.1-4 Early events in synapse development include clustering of SVs to the active zone and NMDA receptors to the PSD, whereas later events include targeting of AMPA receptors and synaptic activity that might direct whether synapses will be stabilized, eliminated or strengthened. Regulating the number of AMPA receptors located at the PSD is a key mechanism underlying synaptic strength and plasticity implicated in learning and memory.5-10 Thus, a current avenue of investigation is the identification of interacting proteins that influence targeting of synaptic AMPA receptors. The discovery that the transmembrane protein stargazin controls synaptic AMPA-R targeting represented a major paradigm shift in the field.11 My colleagues and I recently reported the discovery of a novel type II transmembrane protein SynDIG1 (Synapse Differentiation Induced Gene I) that functions as a critical regulator of excitatory synapse development in dissociated rat hippocampal neurons.12 Specifically, knock-down of SynDIG1 in cultured neurons reduces AMPA receptor content at developing synapses by approximately 50% as determined by immunocytochemistry and electrophysiology.12 The magnitude of this effect matches that of TARPs and PSD-95 identifying SynDIG1 as a previously unknown central regulator of postsynaptic AMPA receptor targeting. In this addendum I further discuss the implications of these data.
兴奋性突触由几个特殊结构域组成,包括含有数百个突触小泡(SVs)的突触前终扣、SVs停靠并与质膜融合的突触前活性区,以及由包括NMDA和AMPA受体、离子通道及各种信号成分的蛋白质电子致密网络构成的并列突触后致密区(PSD)。细胞黏附分子(CAMs)跨越突触间隙延伸,以稳定这种大分子复合物。在中枢神经系统(CNS)发育过程中,某些CAMs还作为诱导信号,触发突触前和突触后特化的建立。1 - 4突触发育的早期事件包括SVs聚集到活性区以及NMDA受体聚集到PSD,而后期事件包括AMPA受体的靶向定位和突触活动,这些活动可能决定突触是会稳定、消除还是增强。调节位于PSD的AMPA受体数量是学习和记忆中涉及的突触强度和可塑性的关键机制。5 - 10因此,当前的一个研究途径是鉴定影响突触AMPA受体靶向定位的相互作用蛋白。跨膜蛋白stargazin控制突触AMPA - R靶向定位的发现代表了该领域的一个重大范式转变。11我和我的同事最近报道了一种新型II型跨膜蛋白SynDIG1(突触分化诱导基因I)的发现,它在解离的大鼠海马神经元中作为兴奋性突触发育的关键调节因子发挥作用。12具体而言,通过免疫细胞化学和电生理学测定,在培养的神经元中敲低SynDIG1会使发育中突触处的AMPA受体含量降低约50%。12这种效应的程度与TARPs和PSD - 95的效应相当,这表明SynDIG1是一种先前未知的突触后AMPA受体靶向定位的核心调节因子。在本附录中,我将进一步讨论这些数据的意义。