AMPA受体的磷酸化与突触可塑性

突触可塑性在学习记忆中发挥了重要作用,AMPA(α-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid,AMPA)受体功能和运输的调节是突触可塑性机制研究的重要环节。在突触可塑性发生过程中,激酶和磷酸酶能够调节AMPA受体C末端的磷酸化水平,进而影响AMPA受体运输。对于AMPA受体磷酸化的研究能够加深我们对突触可塑性机制的理解。     

国家“重大新药创制”科技重大专项重点关注靶点分析解读——AMPA 受体

AMPA 受体是兴奋性神经递质谷氨酸的非N- 甲基-D- 天冬氨酸型离子型跨膜受体,其介导中枢神经系统快速兴奋性突触传递,在中枢神经系统的信号传导、神经发育以及突触的可塑性等方面有重要的影响。研究表明,多种疾病如神经精神系统疾病、心血管疾病、肿瘤、呼吸系统疾病、内分泌系统疾病的发生发展与AMPA 受体数量或功能的异常密切相关。近年来,AMPA 受体作为一种理想的药物作用靶点,受到了越来越多的关注。结合汤森路透数据库资源——Thomson Reuters Integrity 和Cortellis for Competitive Intelligence,对AMPA 受体的机制、相关药物研究进展、适应证、研发机构、交易、专利、文献等情报进行数据层面的分析。     

受体、突触和记忆

大脑中神经元突触间的信号传递是由许多神经递质受体介导的。在过去,Richard L．Huganir实验室一直致力于神经递质受体功能调节的分子机制。而最近,该实验室又聚焦到大脑中一种最主要的兴奋性受体的研究——谷氨酸受体。谷氨酸受体主要可以分为两大类：AMPA受体和NMDA受体。AMPA受体主要介导了快速的兴奋性突触传递;而NMDA受体则在神经可塑性和发育中起到重要作用。实验发现,AMPA受体和NMDA受体都可以被一系列的蛋白激酶磷酸化,而磷酸化的水平则直接影响了这些受体的功能特性,包括通道电导和受体膜定位等。AMPA受体磷酸化的水平同时还在学习和记忆的细胞模型中发生改变,如长时程增强（LTP）和长时程抑制（LTD）。此外,AMPA受体中GluR1亚单位的磷酸化对于各种形式的可塑性以及空间记忆的维持有重要的作用。实验室主要研究突触部位谷氨酸受体在亚细胞水平的定位和聚集的分子机制。最近,一系列可以直接或间接与AMPA和NMDA受体相互作用的蛋白质得以发现,其中包括一个新发现的蛋白家族GRIPs（glutamate receptor interacting proteins）。GRIPs可以直接和AMPA受体的GluR2／3亚单位的C端结合。GRIPs包含7个PDZ结构域,可以介导蛋白与蛋白直接的相互连接,从而把各个AMPA受体交互连接在一起并与其他蛋白相连。另外,GluR2亚单位的c端还可以和兴奋性突触中的蛋白激酶C结合蛋白（PICK1）的PDZ结构域相互作用。另外,GluR2亚单位的C端也可以与一种参与膜融合的蛋白NSF相互作用。这些与AMPA受体相互作用的蛋白质对于受体在膜上的运输以及定位有至关重要的作用。同时,受体与PICK1和GRIP的结合对于小脑运动学习中的LTD有重要作用。总体上说,该实验室发现了一系列可以调节神经递质受体功能的分子机制,这些工作提示受体功能的调节可能是?     

Thy1-αSYN基因小鼠出现代谢紊乱和胰岛形态及功能的改变

帕金森病(PD) 是第二大神经退行性疾病。PD的发病机制仍然不明确,普遍认为 α-突触核蛋白(α-synuclein) 的聚集和传播引起的神经损伤、线粒体功能障碍、炎症和氧化应激,自噬功能障碍等在PD 的发生发展中发挥作用。越来越多的研究认为,代谢紊乱也是PD的发病机制之一。我们检测了过表达α-突触核蛋白是否能引起小鼠代谢紊乱以及可能的机制。研究分为Thy1-αSYN转基因小鼠组(TG)及同窝对照野生小鼠组（WT）,分别检测它们在转棒仪上的停留时间,体重情况,血浆中胰岛素含量,小鼠糖耐量及胰岛素耐量等外周代谢情况。使用苏木精-伊红染色法对两组小鼠胰岛的形态进行观察,分离小鼠胰岛并使用葡萄糖刺激胰岛素分泌检测胰岛素分泌功能。结果显示, 12月龄的TG组小鼠与WT组相比运动耐力下降23.1%（P < 0.05）,体重增加7%（P < 0.01）,糖耐量降低（P < 0.05）,胰岛素耐量降低（P < 0.05）,外周血中胰岛素含量降低20%（P < 0.05）。TG组小鼠胰腺内α-突触核蛋白水平较WT组增加1.32倍（P < 0.05）,TG组小鼠的胰岛面积变小（P < 0.05）,胰岛个数减少（P < 0.01）,胰岛素分泌功能下降（P < 0.01）。我们的研究提示,α-突触核蛋白在PD中的作用不局限于对多巴胺能神经元的损伤,它能影响代谢及外周器官的形态及功能,这为PD的发病机制提供新的理论依据。     

突触长时程增强形成机制的研究进展

高等动物脑内突触传递的可塑性是近30年来神经科学研究的热点,突触传递长时程增强（long-term potentiation,LTP)是神经元可塑性的反映,其形成主要与突触后机制有关。过去关于LTP机制的研究主要集中于N－甲基－D门冬氨酸（NMDA）受体的特征及该受体被激活后的细胞内级联反应,现认为脑内存在只具有NMDA受体而不具有α－氨基羟甲基恶唑丙酸（AMPA）受体的“静寂突触（silent synapse)”,这一概念的提出,使人们认识到AMPA受体在LTP表达的突触后机制中的重要作用。     

终纹床核神经元AMPA／NMDA的受体比例与可卡因复吸

研究成瘾药物复吸的神经机制是此类研究的核心问题。最近,美国俄勒冈健康与科学大学学者John TWilliams等人发现:被动接受成瘾药物和主动复吸有不同的神经机制。此研究从兴奋性突触强度变化和AMPA/NMDA受体比例变化入手,观察到大鼠腹侧终纹床核(ventral lateral bed nucleus of     

谷氨酸下调培养海马神经元AMPA受体G1uR2亚单位的表达

目的 研究在癫痫发病过程中,谷氨酸对AMPA受体G1uR2亚单位表达变化的影响。方法 用RT-PCR和Western Blot方法观察谷氨酸诱导培养大鼠海马神经元AMPA受体G1uR2亚单位mRNA和蛋白的表达变化。结果 在谷氨酸刺激后2h,8h,12h,培养海马神经元G1uR2 mRNA和蛋白表达明显下降,与对照组相比,差异有显著性（P〈0．05）,而非NMDA受体拮抗剂CNQX能阻断此变化。结论 在癫痫等疾病中,谷氨酸能通过激活AMAP／KA受体下调AMPA受体G1uR2亚单位的表达,参与发病过程。     

兴奋性突触传入对皮层神经元形态发育的影响

目的:探讨离子型谷氨酸受体中的AMPA受体(α-amino-3-hydroxy-5-methyl-4-isoxazole propionate receptor, AMPA受体)和NMDA受体(N-methyl-D-aspartic acid receptor)对抑制性中间神经元以及兴奋性神经元的形态发育的影响。方法:采用原代培养皮层神经元,通过药物干预AMPA受体和/或NMDA受体的方法阻断神经元的离子型谷氨酸受体,并采用GAD67-GFP鼠的绿色荧光来显示混合细胞群中抑制性神经元、CaMKII免疫荧光染色显示兴奋性神经元。结果:当阻断AMPA和/或NMDA受体时,光镜下显示神经元网络的密度降低,且随着药物浓度的增加,神经元网络的变化更明显。对于GFP阳性的抑制性神经元,当阻断AMPA受体时,神经元突起分支数降低至对照组的约65%(低浓度)和55%(高浓度),突起长度缩短至对照组的大约43%(低浓度)和36%(高浓度);当阻断NMDA受体时,分支数降低至约70%(低浓度)和45%(高浓度),长度缩短至约43%(低浓度)和31%(高浓度);联合用药时,分支数和长度分别为对照的约42%和38%。对于CaMKII阳性的兴奋性神经元,尽管变化程度稍弱,但其形态也出现类似变化。当阻断AMPA受体时,神经元的分支数降低至对照组的64%(高浓度),突起长度变化不大;当阻断NMDA受体时,分支数降低至约50%(高浓度),长度缩短至约77%(低浓度)和71%(高浓度);联合用药时,分支数和长度分别为对照的约69%和62%。结论:在神经元发育的过程中,离子型谷氨酸受体介导的兴奋性突触传入可影响抑制性神经元和兴奋性神经元的形态发育,最终对神经环路的形成发挥重要的调控作用。     

AMPA受体失敏和快速兴奋性突触传递

ＡＭＰＡ受体是离子型谷氨酸受体中重要的一类亚型,在中枢神经系统内主要介导快速的兴奋性突触传递。近年来,ＡＭＰＡ受体独特的失敏特性逐渐被阐明,已经确定了一些特异调节ＡＭＰＡ受体失敏的化合物。大量的生理学和药理学证据表明,ＡＭＰＡ受体失敏在快速兴奋性突触传递中起着重要的作用,对单个突触的传递效率、神经元的整合功能和突触的可塑性均有影响。     

1,4,5-三磷酸肌醇受体参与神经退行性疾病发生的研究进展

1,4,5-三磷酸肌醇受体(inositol 1,4,5-trisphosphate receptors,IP3Rs)是由1,4,5-三磷酸肌醇激活的细胞内质网钙离子通道,调节神经递质释放、突触小泡融合、激活钙敏信号通路和触发基因转录、突触后膜反应和突触可塑性等,从时间、空间和浓度多维度调控钙离子而参与细胞的生物学功能,是维持中枢神经系统正常功能的关键分子。IP3R通道的表达或功能异常在神经退行性疾病的发生过程中起重要作用,如脊髓小脑性共济失调、亨廷顿氏病和阿尔茨海默病等,本文归纳整理了IP3Rs结构和生物学功能的研究结果,综述了IP3Rs参与神经退行性疾病发生过程的一些最新进展。     

Soluble oligomers of amyloid-β peptide disrupt membrane trafficking of α-amino-3-hydroxy-5-methylisoxazole-4-propionic acid receptor contributing to early synapse dysfunction

β-Amyloid (Aβ), a peptide generated from the amyloid precursor protein, is widely believed to underlie the pathophysiology of Alzheimer disease (AD). Emerging evidences suggest that soluble Aβ oligomers adversely affect synaptic function, leading to cognitive failure associated with AD. The Aβ-induced synaptic dysfunction has been attributed to the synaptic removal of α-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA) receptors (AMPARs). However, the molecular mechanisms underlying the loss of AMPAR induced by Aβ at synapses are largely unknown. In this study we have examined the effect of Aβ oligomers on phosphorylated GluA1 at serine 845, a residue that plays an essential role in the trafficking of AMPARs toward extrasynaptic sites and the subsequent delivery to synapses during synaptic plasticity events. We found that Aβ oligomers reduce basal levels of Ser-845 phosphorylation and surface expression of AMPARs affecting AMPAR subunit composition. Aβ-induced GluA1 dephosphorylation and reduced receptor surface levels are mediated by an increase in calcium influx into neurons through ionotropic glutamate receptors and activation of the calcium-dependent phosphatase calcineurin. Moreover, Aβ oligomers block the extrasynaptic delivery of AMPARs induced by chemical synaptic potentiation. In addition, reduced levels of total and phosphorylated GluA1 are associated with initial spatial memory deficits in a transgenic mouse model of AD. These findings indicate that Aβ oligomers could act as a synaptic depressor affecting the mechanisms involved in the targeting of AMPARs to the synapses during early stages of the disease.     

Zebrafish TARP Cacng2 is required for the expression and normal development of AMPA receptors at excitatory synapses

Fast excitatory synaptic transmission in the CNS is mediated by the neurotransmitter glutamate, binding to and activating AMPA receptors (AMPARs). AMPARs are known to interact with auxiliary proteins that modulate their behavior. One such family of proteins is the transmembrane AMPA receptor‐related proteins, known as TARPs. Little is known about the role of TARPs during development, or about their function in non‐mammalian organisms. Here we report the presence of TARPs, specifically the prototypical TARP, stargazin, in developing zebrafish. We find that zebrafish express two forms of stargazin, Cacng2a and Cacng2b from as early as 12‐h post fertilization (hpf). Knockdown of Cacng2a and Cacng2b via splice‐blocking morpholinos resulted in embryos that exhibited deficits in C‐start escape responses, showing reduced C‐bend angles, smaller tail velocities and aberrant C‐bend turning directions. Injection of the morphants with Cacng2a or 2b mRNA rescued the morphological phenotype and the synaptic deficits. To investigate the effect of reduced Cacng2a and 2b levels on synaptic physiology, we performed whole cell patch clamp recordings of AMPA mEPSCs from zebrafish Mauthner cells. Knockdown of Cacng2a results in reduced AMPA currents and lower mEPSC frequencies, whereas knockdown of Cacng2b displayed no significant change in mEPSC amplitude or frequency. Non‐stationary fluctuation analysis confirmed a reduction in the number of active synaptic receptors in the Cacng2a but not in the Cacng2b morphants. Together, these results suggest that Cacng2a is required for normal trafficking and function of synaptic AMPARs, while Cacng2b is largely non‐functional with respect to the development of AMPA synaptic transmission. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 76: 487–506, 2016     

Homeostatic synaptic scaling is regulated by protein SUMOylation

Homeostatic scaling allows neurons to alter synaptic transmission to compensate for changes in network activity. Here, we show that suppression of network activity with tetrodotoxin, which increases surface expression of AMPA receptors (AMPARs), dramatically reduces levels of the deSUMOylating (where SUMO is small ubiquitin-like modifier) enzyme SENP1, leading to a consequent increase in protein SUMOylation. Overexpression of the catalytic domain of SENP1 prevents this scaling effect, and we identify Arc as a SUMO substrate involved in the tetrodotoxin-induced increase in AMPAR surface expression. Thus, protein SUMOylation plays an important and previously unsuspected role in synaptic trafficking of AMPARs that underlies homeostatic scaling.     

Nedd4-mediated AMPA receptor ubiquitination regulates receptor turnover and trafficking

α-Amino-3-hydroxy-5-methyl-isoxazole-4-propionic acid receptors (AMPARs) are the primary mediators of excitatory synaptic transmission in the brain. Alterations in AMPAR localization and turnover have been considered critical mechanisms underpinning synaptic plasticity and higher brain functions, but the molecular processes that control AMPAR trafficking and stability are still not fully understood. Here, we report that mammalian AMPARs are subject to ubiquitination in neurons and in transfected heterologous cells. Ubiquitination facilitates AMPAR endocytosis, leading to a reduction in AMPAR cell-surface localization and total receptor abundance. Mutation of lysine residues to arginine residues at the glutamate receptor subunit 1 (GluA1) C-terminus dramatically reduces GluA1 ubiquitination and abolishes ubiquitin-dependent GluA1 internalization and degradation, indicating that the lysine residues, particularly K868, are sites of ubiquitination. We also find that the E3 ligase neural precursor cell expressed, developmentally down-regulated 4 (Nedd4) is enriched in synaptosomes and co-localizes and associates with AMPARs in neurons. Nedd4 expression leads to AMPAR ubiquitination, leading to reduced AMPAR surface expression and suppressed excitatory synaptic transmission. Conversely, knockdown of Nedd4 by specific siRNAs abolishes AMPAR ubiquitination. These data indicate that Nedd4 is the E3 ubiquitin ligase responsible for AMPAR ubiquitination, a modification that regulates multiple aspects of AMPAR molecular biology including trafficking, localization and stability.     

Regulation of AMPA receptor trafficking and synaptic plasticity

AMPA receptors (AMPARs) mediate the majority of fast excitatory synaptic transmission in the brain. Dynamic changes in neuronal synaptic efficacy, termed synaptic plasticity, are thought to underlie information coding and storage in learning and memory. One major mechanism that regulates synaptic strength involves the tightly regulated trafficking of AMPARs into and out of synapses. The life cycle of AMPARs from their biosynthesis, membrane trafficking, and synaptic targeting to their degradation are controlled by a series of orchestrated interactions with numerous intracellular regulatory proteins. Here we review recent progress made toward the understanding the regulation of AMPAR trafficking, focusing on the roles of several key intracellular AMPAR interacting proteins.     

The role of transmembrane AMPA receptor regulatory proteins (TARPs) in neurotransmission and receptor trafficking (Review)

AMPA receptors (AMPAR) mediate the majority of fast excitatory neurotransmission in the central nervous system (CNS). Transmembrane AMPAR regulatory proteins (TARPs) have been identified as a novel family of proteins which act as auxiliary subunits of AMPARs to modulate AMPAR trafficking and function. The trafficking of AMPARs to regulate the number of receptors at the synapse plays a key role in various forms of synaptic plasticity, including long-term potentiation (LTP) and long-term depression (LTD). Expression of the prototypical TARP, stargazin/TARPγ2, is ablated in the stargazer mutant mouse, an animal model of absence epilepsy and cerebellar ataxia. Studies on the stargazer mutant mouse have revealed that failure to express TARPγ2 has widespread effects on the balance of expression of both excitatory (AMPAR) and inhibitory receptors (GABA_A receptors, GABAR). The understanding of TARP function has implications for the future development of AMPAR potentiators, which have been shown to have therapeutic potential in both psychological and neurological disorders such as schizophrenia, depression and Parkinson's disease.     

Impaired alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor trafficking and function by mutant huntingtin

Emerging evidence from studies of Huntington disease (HD) pathophysiology suggests that huntingtin (htt) and its associated protein HAP1 participate in intracellular trafficking and synaptic function. However, it is largely unknown whether AMPA receptor trafficking, which is crucial for controlling the efficacy of synaptic excitation, is affected by the mutant huntingtin with polyglutamine expansion (polyQ-htt). In this study, we found that expressing polyQ-htt in neuronal cultures significantly decreased the amplitude and frequency of AMPAR-mediated miniature excitatory postsynaptic current (mEPSC), while expressing wild-type huntingtin (WT-htt) increased mEPSC. AMPAR-mediated synaptic transmission was also impaired in a transgenic mouse model of HD expressing polyQ-htt. The effect of polyQ-htt on mEPSC was mimicked by knockdown of HAP1 and occluded by the dominant negative HAP1. Moreover, we found that huntingtin affected mESPC via a mechanism depending on the kinesin motor protein, KIF5, which controls the transport of GluR2-containing AMPARs along microtubules in dendrites. The GluR2/KIF5/HAP1 complex was disrupted and dissociated from microtubules in the HD mouse model. Together, these data suggest that AMPAR trafficking and function is impaired by mutant huntingtin, presumably due to the interference of KIF5-mediated microtubule-based transport of AMPA receptors. The diminished strength of glutamatergic transmission could contribute to the deficits in movement control and cognitive processes in HD conditions.     

Expression mechanisms underlying long-term potentiation: a postsynaptic view, 10 years on

This review focuses on the research that has occurred over the past decade which has solidified a postsynaptic expression mechanism for long-term potentiation (LTP). However, experiments that have suggested a presynaptic component are also summarized. It is argued that the pairing of glutamate uncaging onto single spines with postsynaptic depolarization provides the final and most elegant demonstration of a postsynaptic expression mechanism for NMDA receptor-dependent LTP. The fact that the magnitude of this LTP is similar to that evoked by pairing synaptic stimulation and depolarization leaves little room for a substantial presynaptic component. Finally, recent data also require a revision in our thinking about the way AMPA receptors (AMPARs) are recruited to the postsynaptic density during LTP. This recruitment is independent of subunit type, but does require an adequate reserve pool of extrasynaptic receptors.     

Reinsertion or degradation of AMPA receptors determined by activity-dependent endocytic sorting

Both acute and chronic changes in AMPA receptor (AMPAR) localization are critical for synaptic formation, maturation, and plasticity. Here I report that AMPARs are differentially sorted between recycling and degradative pathways following endocytosis. AMPAR sorting occurs in early endosomes and is regulated by synaptic activity and activation of AMPA and NMDA receptors. AMPAR intemalization triggered by NMDAR activation is Ca2+-dependent, requires protein phosphatases, and is followed by rapid membrane reinsertion. Furthermore, NMDAR-mediated AMPAR trafficking is regulated by PKA and accompanied by dephosphorylation and rephosphorylation of GluR1 subunits at a PKA site. In contrast, activation of AMPARs without NMDAR activation targets AMPARs to late endosomes and lysosomes, independent of Ca2+, protein phosphatases, or PKA. These results demonstrate that activity regulates AMPAR endocytic sorting, providing a potential mechanistic link between rapid and chronic changes in synaptic strength.     

PSD-95-like membrane associated guanylate kinases (PSD-MAGUKs) and synaptic plasticity

Activity-dependent modification of excitatory synaptic transmission is a fundamental mechanism for developmental plasticity of the neural circuits and experience-dependent plasticity. Synaptic glutamatergic receptors including AMPA receptors and NMDA receptors (AMPARs and NMDARs) are embedded in the postsynaptic density, a highly organized protein network. Overwhelming data have shown that PSD-95-like membrane associated guanylate kinases (PSD-MAGUKs), a major family of scaffold proteins at glutamatergic synapses, regulate basal synaptic AMPAR function and trafficking. It is now clear that PSD-MAGUKs have multifaceted functions in regulating both basal synaptic transmission and synaptic plasticity. Here we discuss recent advancements in understanding the roles of PSD-95 and other family members of PSD-MAGUKs in synaptic plasticity, both as an anchoring protein for synaptic AMPARs and as a signaling scaffold for mediating the interaction of the signaling complex and NMDARs.