PDZ支架蛋白 PDZK1通过PDZ1与PDZ3结构域与磷脂酶Cβ2羧基末端PDZ结合模块相互作用

磷脂酶C β (PLCβ)在G蛋白偶联受体 (GPCR)介导的细胞信号转导中发挥重要作用. 通过水解磷脂酰肌醇4,5二磷酸 (PIP2),磷脂酶C β可以产生3种重要的第二信使分子：二乙酰甘油 (DAG)、三磷酸肌醇 (IP3)和质子. 在果蝇中,磷脂酶C β通过它的羧基末端盘状同源区域结合模块 (PBM)与盘状同源区域 (PDZ)支架蛋白-失活无后电位D蛋白 (INAD)相互作用,从而调节果蝇的光信号传导 . 在哺乳动物中,磷脂酶C β家族有4个亚型,每1个亚型的羧基末端都有1个典型的盘状同源区域结合模块. 这一结构特点提示我们,磷脂酶C β可能通过其羧基末端的盘状同源区域结合模块与盘状同源区域支架蛋白相互作用,进而调节它们自身的细胞定位和功能. 然而,目前仍对哺乳动物磷脂酶C β家族的盘状同源区域结合蛋白知之甚少. 本文运用分析型凝胶过滤和等温滴定量热技术,系统地研究了不同磷脂酶Cβ亚型的羧基末端盘状同源区域结合模块与不同盘状同源区域蛋白质的结合. 结果表明,磷脂酶Cβ2的羧基末端盘状同源区域结合模块,可以特异地与含有4个盘状同源区域的支架蛋白-盘状同源区域蛋白1 (PDZK1）以2∶1的方式相互结合. 进一步的测定显示,磷脂酶C β2羧基末端盘状同源区域结合模块在盘状同源区域蛋白1上的结合位点为第1和第3个盘状同源区域,而它们与磷脂酶Cβ2的解离常数分别为11.8±3.4 μmol/L 和33.3±8.7 μmol/L.     

PDZ支架蛋白PDZK1通过PDZ1与PDZ3结构域与磷脂酶Cβ2羧基末端PDZ结合模块相互作用（英文）

磷脂酶Cβ(PLCβ)在G蛋白偶联受体(GPCR)介导的细胞信号转导中发挥重要作用.通过水解磷脂酰肌醇4,5二磷酸(PIP2),磷脂酶Cβ可以产生3种重要的第二信使分子:二乙酰甘油(DAG)、三磷酸肌醇(IP3)和质子.在果蝇中,磷脂酶Cβ通过它的羧基末端盘状同源区域结合模块(PBM)与盘状同源区域(PDZ)支架蛋白—失活无后电位D蛋白(INAD)相互作用,从而调节果蝇的光信号传导.在哺乳动物中,磷脂酶Cβ家族有4个亚型,每1个亚型的羧基末端都有1个典型的盘状同源区域结合模块.这一结构特点提示我们,磷脂酶Cβ可能通过其羧基末端的盘状同源区域结合模块与盘状同源区域支架蛋白相互作用,进而调节它们自身的细胞定位和功能.然而,目前仍对哺乳动物磷脂酶Cβ家族的盘状同源区域结合蛋白知之甚少.本文运用分析型凝胶过滤和等温滴定量热技术,系统地研究了不同磷脂酶Cβ亚型的羧基末端盘状同源区域结合模块与不同盘状同源区域蛋白质的结合.结果表明,磷脂酶Cβ2的羧基末端盘状同源区域结合模块,可以特异地与含有4个盘状同源区域的支架蛋白—盘状同源区域蛋白1(PDZK1)以2∶1的方式相互结合.进一步的测定显示,磷脂酶Cβ2羧基末端盘状同源区域结合模块在盘状同源区域蛋白1上的结合位点为第1和第3个盘状同源区域,而它们与磷脂酶Cβ2的解离常数分别为11.8±3.4μmol/L和33.3±8.7μmol/L.     

PDZ domains – glue and guide

PDZ domains are small globular building blocks that are amongst the most abundant protein interaction domains in organisms. Over the past several years an avalanche of data has implicated these modules in the clustering, targeting and routing of associating proteins. An overview is given of the types of interactions displayed by PDZ domains and how this relates to the current knowledge on their spatial structure. Furthermore, the different levels on which PDZ – ligand binding can be regulated and the consequences of PDZ domain-mediated clustering for activity, routing and targeting of interacting proteins will be addressed. Finally, some cell and animal models that illustrate the impact of PDZ domain-containing proteins on (multi-) cellular processes will be discussed.     

PDZ结构域介导的PIP脂质信号转导

PDZ结构域是调控蛋白质/蛋白质相互作用的一类重要结构域,能特异结合蛋白质C末端一段有规律的氨基酸序列。含有PDZ结构域的支架蛋白能够组装成超大的蛋白质复合体来调控细胞内的信号转导通路。最新研究表明,PDZ结构域还能与PIP脂质直接相互作用,从而参与调控PIP脂质信号通路。将综合最新研究进展,阐明PDZ结构域与PIP脂质的作用方式,以及对相关PIP脂质信号转导的调控过程。     

PDZ Ligand Binding-Induced Conformational Coupling of the PDZ–SH3–GK Tandems in PSD-95 Family MAGUKs

Discs large (DLG) MAGUKs are abundantly expressed in glutamatergic synapses, crucial for synaptic transmission, and plasticity by anchoring various postsynaptic components including glutamate receptors, downstream scaffold proteins and signaling enzymes. Different DLG members have shared structures and functions, but also contain unique features. How DLG family proteins function individually and cooperatively is largely unknown. Here, we report that PSD-95 PDZ3 directly couples with SH3–GK tandem in a PDZ ligand binding-dependent manner, and the coupling can promote PSD-95 dimerization and multimerization. Aided by sortase-mediated protein ligation and selectively labeling, we elucidated the PDZ3/SH3–GK conformational coupling mechanism using NMR spectroscopy. We further demonstrated that PSD-93, but not SAP102, can also undergo PDZ3 ligand binding-induced conformational coupling with SH3–GK and form homo-oligomers. Interestingly, PSD-95 and PSD-93 can also form ligand binding-induced hetero-oligomers, suggesting a cooperative assembly mechanism for the mega-N-methyl-d-aspartate receptor synaptic signaling complex. Finally, we provide evidence showing that ligand binding-induced conformational coupling between PDZ and SH3–GK is a common feature for other MAGUKs including CASK and PALS1.     

PDZ连接激酶，又一新的原癌基因

PDZ连接激酶(PBK)是一种丝-苏氨酸激酶,属于丝裂原活化蛋白激酶激酶(MAPKK)家族成员.PBK能调控细胞周期进程,促进细胞增殖.近年发现,其在乳腺癌、结肠癌、皮肤癌和前列腺癌等多种恶性肿瘤组织中均呈高表达,与多种癌症预后不良关联密切.PBK主要通过Wnt、PI3K/AKT/mTOR和MAPK等信号通路,调控肿瘤细胞有丝分裂,参与多种癌症的增殖、侵袭转移和耐药等,并受miR-216b-3p、miR-770-5p和miR-372-5p等多种microRNA调控.提示PBK可能作为又一新的原癌基因,有望成为抑癌药物新的分子靶点.     

验证性筛选PDZ结构域结合配体文库快速研究HtrA2/Omi PDZ结构域的结合特性

HtrA2/Omi是一种线粒体丝氨酸蛋白酶, 在哺乳动物细胞中具有双重功能, 即诱导细胞凋亡和参与维持线粒体活性的动态平衡. PDZ结构域是最重要的蛋白质相互作用结构域之一, 参与多种生物学过程, 如细胞信号转导、蛋白质降解、细胞骨架组织等. 最近研究发现, HtrA2/Omi蛋白的PDZ结构域与配体的相互作用, 可以调节HtrA2/Omi蛋白自身的水解酶活性.以HtrA2/Omi PDZ结构域为研究对象, 用酵母双杂交系统验证性筛选PDZ结构域结合配体文库, 快速研究该结构域的结合特性, 并在人类全蛋白质组范围内预测并发现该结构域新的相互作用蛋白, 最后分析这些新的相互作用所能够形成的最小相互作用网络来评估其可信度. 研究结果揭示了HtrA2/Omi PDZ结构域新的结合特性, 即: 不仅能够结合已报道的II类PDZ配体而且还可以结合I类和III类PDZ配体, 并且配体-3位氨基酸具有一定范围内的可变性. 而且, 发现了7个新的HtrA2/Omi PDZ结构域相互作用蛋白, 为进一步阐明HtrA2/Omi蛋白的生物学功能提供了重要线索. 同时证明了验证性筛选目的结构域结合配体文库, 这一结构域结合特性研究新策略的实用性和高效性.     

Equilibrium unfolding of the PDZ domain of β2-syntrophin

β2-syntrophin, a dystrophin-associated protein, plays a pivotal role in insulin secretion by pancreatic β-cells. It contains a PDZ domain (β2S-PDZ) that, in complex with protein-tyrosine phosphatase ICA512, anchors the dense insulin granules to actin filaments. The phosphorylation state of β2-syntrophin allosterically regulates the affinity of β2S-PDZ for ICA512, and the disruption of the complex triggers the mobilization of the insulin granule stores. Here, we investigate the thermal unfolding of β2S-PDZ at different pH and urea concentrations. Our results indicate that, unlike other PDZ domains, β2S-PDZ is marginally stable. Thermal denaturation experiments show broad transitions and cold denaturation, and a two-state model fit reveals a significant unfolded fraction under physiological conditions. Furthermore, T(m) and T(max) denaturant-dependent shifts and noncoincidence of melting curves monitored at different wavelengths suggest that two-state and three-state models fail to explain the equilibrium data properly and are in better agreement with a downhill scenario. Its higher stability at pH >9 and the results of molecular dynamics simulations indicate that this behavior of β2S-PDZ might be related to its charge distribution. All together, our results suggest a link between the conformational plasticity of the native ensemble of this PDZ domain and the regulation of insulin secretion.     

抑癌蛋白PTEN及PDZ蛋白对其的调节

pten基因是迄今为止发现的第1个具有双特异性磷酸酶活性的抑癌基因,该基因的编码产物PTEN蛋白,是具有蛋白与脂质磷酸酯酶活性的双特异性磷酸酯酶,作为1种重要的信号分子参与细胞增殖、分化、黏附、迁移、凋亡以及基因转录的调控. 最近,关于PTEN在信号转导中的作用以及细胞内PTEN的调节机制研究较多,尤其是PDZ蛋白对PTEN的调节作用. PTEN蛋白包括1个氨基端（N端）磷酸酯酶区域,1个与脂质结合的C2区域和1个含有PDZ结合序列的羧基端（C端）区域. PDZ结构域通过识别目标蛋白羧基端PDZ结合序列与目标蛋白相互作用,调控多种重要的细胞生理过程和信号传导途径.本文就抑癌基因pten编码产物PTEN蛋白的结构、PTEN的生物学功能和PDZ蛋白对PTEN调节的研究进展进行综述.     

PDZ结构域的结构特点及其识别特异性配体的机制

PDZ结构域作为介导蛋白质之间相互作用的重要结构域之一,参与到细胞内运输、离子通道、以及各种信号传导通路等多种生物学过程.PDZ结构域是由80~100个氨基酸组成的小的球状结构域,对某些多PDZ结构域蛋白来说,需要一前一后形成串联体才能正确折叠.另外,PDZ结构域相互之间也可以形成同源或异源二聚体.这些PDZ结构域的突出特点是能特异性地识别配体靶蛋白C末端短的氨基酸序列,但有些也能识别靶蛋白的内部β发夹结构.而一些支架蛋白的PDZ结构域与细胞膜上脂类的相互作用则增加了其与膜的亲和性.本文简要概括了PDZ结构域的结构特点及其对配体的各种特异性识别的机制,从而为研究各种PDZ蛋白的功能提供了结构基础.     

大鼠MUPP1蛋白PDZ8结构域的生化及晶体结构特性

多重PDZ结构域蛋白1型（MUPP1）是一种存在于上皮细胞和神经细胞内含有13个PDZ结构域的重要支架蛋白.在上皮细胞中,MUPP1蛋白在紧密连接结构的形成和上皮细胞的极化过程中发挥重要作用.而在中枢神经系统中,MUPP1基因的1个提前终止突变导致了其最后12个PDZ结构域的缺失,以及严重的先天性脑积水.此外,MUPP1蛋白的表达水平与酒精依赖性和药物戒断的严重性也具有显著的相关性.因此,对MUPP1蛋白所含的PDZ结构域进行纯化和性质鉴定,将有助于深入研究MUPP1蛋白的功能和分子机制.在本文研究中,利用亲和纯化和分子筛技术,对大鼠来源的MUPP1蛋白的第8个PDZ结构域进行了表达和纯化.多角度激光光散射的数据表明: MUPP1-PDZ8结构域在溶液中为单体,分子量为16.4 kD.圆二色谱结果表明,MUPP1-PDZ8结构域具有较好的二级结构折叠,测得其熔解温度为71.6摄氏度,暗示该PDZ结构域在溶液中非常稳定.最后,MUPP1-PDZ8结构域的晶体结构显示,该结构域属于I 型PDZ 结构域,包含3个α螺旋和6个β折叠.其中GLGL模块、β折叠B上的1 351位亮氨酸,以及α螺旋B上的1 405位异亮氨酸/1 398位组氨酸形成的PDZ结合口袋,可以特异性地与其目标蛋白质的羧基末端相结合.综上所述,本文的研究提供了MUPP1-PDZ8结构域的生化特性,以及该结构域与其目标蛋白质相互作用的分子机制,这将为MUPP1蛋白的功能研究提供生物化学与结构生物学的理论基础.     

Subtype-specific roles of phospholipase C-β via differential interactions with PDZ domain proteins

Since we first identified the PLC-β isozyme, enormous studies have been conducted to investigate the functional roles of this protein (Min et al., 1993; Suh et al.,1988). It is now well-known that the four PLC-β subtypes are major effector molecules in GPCR-mediated signaling, especially for intracellular Ca2+ signaling. Nonetheless, it is still poorly understood why multiple PLC-β subtype exist. Most cells express multiple subtypes of PLC-β in different combinations, and each subtype is involved in somewhat different signaling pathways. Therefore, studying the differential roles of each PLC-β subtype is a very interesting issue. In this regard, we focus here on PDZ domain proteins which are novel PLC-β interacting proteins. As scaffolders, PDZ domain proteins recruit various target proteins ranging from membrane receptors to cytoskeletal proteins to assemble highly organized signaling complexes; this can give rise to efficiency and diversity in cellular signaling. Because PLC-β subtypes have different PDZ-binding motifs, it is possible that they are engaged with different PDZ domain proteins, and in turn participate in distinct physiological responses. To date, several PDZ domain proteins, such as the NHERF family, Shank2, and Par-3, have been reported to selectively interact with certain PLC-β subtypes and GPCRs. Systematic predictions of potential binding partners also suggests differential binding properties between PLC-β subtypes. Furthermore, we elucidated parallel signaling processes for multiple PLC-β subtypes, which still perform distinct functions resulting from differential interactions with PDZ domain proteins within a single cell. Therefore, these results highlight the novel function of PDZ domain proteins as intermediaries in subtype-specific role of PLC-β in GPCR-mediated signaling. Future studies will focus on the physiological meanings of this signaling complex formation by different PDZ domain proteins and PLC-β subtypes. It has been observed for a long time that the expression of certain PLC-β subtype fluctuates during diverse physiological conditions. For example, the expression of PLC-β1 is selectively increased during myoblast and adipocyte differentiation (Faenza et al., 2004; O'Carroll et al., 2009). Likewise, PLC-β2 is highly up-regulated during breast cancer progression and plays a critical role in cell migration and mitosis (Bertagnolo et al., 2007). Although PLC-β3 is selectively down-regulated in neuroendocrine tumors, the expression of PLC-β1 is increased in small cell lung carcinoma (Stalberg et al., 2003; Strassheim et al., 2000). In our hypothetical model, it is most likely that up- and down regulation of certain PLC-β subtypes are due to their selective coupling with specific GPCR-mediated signaling, implicated in these pathophysiologic conditions. Therefore, better understanding of selective coupling between PLC-β subtypes, PDZ domain proteins, and GPCRs will shed light on new prognosis and therapy of diverse diseases, and provide potential targets for drug development.     

PDZ结构域蛋白CAL缓解鱼藤酮引起的MN9D细胞损伤

PDZ(PSD95-DLG1-ZO1) 域蛋白囊性纤维化跨膜电导调节相关配体(CAL)与Ⅰ组代谢型谷氨酸受体(mGluRⅠ)相互作用并且调节其下游信号.近年发现,mGluRⅠ与帕金森病密切相关.然而,CAL蛋白是否在帕金森病中发挥作用,目前尚未见报道.本文选用线粒体复合物Ⅰ 抑制剂鱼藤酮处理小鼠多巴胺能神经元细胞系MN9D,建立帕金森病细胞模型,探讨CAL在鱼藤酮刺激多巴胺能神经元过程中的作用及可能机制.结果显示,鱼藤酮引起CAL蛋白表达减少,过表达CAL蛋白可以部分缓解鱼藤酮引起的MN9D细胞活力下降、细胞凋亡及c-Jun N端激酶(JNK)磷酸化.加入JNK抑制剂SP600125,鱼藤酮引起的细胞活力下降同样有所恢复.提示CAL蛋白可能通过调节JNK信号通路保护多巴胺能神经元.     

高危型HPV E6蛋白与宿主PDZ蛋白相互作用的研究进展

病毒通过自身蛋白与宿主蛋白间的相互作用,营造一种适合于其转化、增殖的体内环境,从而引起一系列疾病的过程。人乳头瘤病毒(HPV)与某些肿瘤发病关系密切,分子机制研究表明,其表达的早期蛋白E6是HPV参与细胞恶性转化的主要蛋白。含有PDZ结构域的蛋白质是细胞内广泛存在的一类蛋白质。本文综述了人乳头瘤病毒的E6蛋白和宿主细胞的PDZ蛋白间的相互作用,讨论了这种作用引发的细胞内生化生理改变及其应用前景。     

Neuronal PDZ domains: a promising new molecular target for inhaled anesthetics?

Despite widespread use of volatile general anesthetics in millions of patients each year, the mechanisms by which they exert multiple effects on the behavior of central neurons are poorly understood. PDZ [postsynaptic density 95 (PSD-95), discs large (Dlg), and zonula occludens-1 (ZO-1)] domains are ubiquitous protein interaction modules that participate in neuronal signaling. Recent studies have indicated that clinically relevant concentrations of inhaled anesthetics dose-dependently and specifically inhibit the PDZ domain-mediated protein interactions among multiprotein signaling complexes. These inhibitory effects are immediate, potent, reversible, and occur at a hydrophobic peptidebinding groove on the surface of the PDZ domain. Thus, the PDZ domain might be a new molecular target for inhalational anesthetics.     

Sequence-specific 1H, 13C, and 15N backbone assignment of the 28 kDa PDZ2/PDZ3 tandem domain of the protein tyrosine phosphatase PTP-BL

Protein tyrosine phosphatase-basophil like (PTP-BL) represents a large multi domain non-transmembrane scaffolding protein that contains five PDZ domains. Here we report the backbone assignments of the PDZ2/PDZ3 tandem domain of PTP-BL. These assignments now provide a basis for the detailed structural investigation of the interaction between the PDZ domains 2 and 3 of PTP-BL. It will lead to a better understanding of the proposed scaffolding function of this tandem domain in multi-protein complexes assembled by PTB-BL. Christian P. Fetzer, Janelle Sauvageau and Gerd Kock contributed equally to this work.     

Reduced PDZ Interactions of Rescued ΔF508CFTR Increases Its Cell Surface Mobility

Deletion of phenylalanine 508 (ΔF508) in the cystic fibrosis transmembrane conductance regulator (CFTR) plasma membrane chloride channel is the most common cause of cystic fibrosis (CF). Though several maneuvers can rescue endoplasmic reticulum-retained ΔF508CFTR and promote its trafficking to the plasma membrane, rescued ΔF508CFTR remains susceptible to quality control mechanisms that lead to accelerated endocytosis, ubiquitination, and lysosomal degradation. To investigate the role of scaffold protein interactions in rescued ΔF508CFTR surface instability, the plasma membrane mobility of ΔF508CFTR was measured in live cells by quantum dot single particle tracking. Following rescue by low temperature, chemical correctors, thapsigargin, or overexpression of GRASP55, ΔF508CFTR diffusion was more rapid than that of wild-type CFTR because of reduced interactions with PDZ domain-containing scaffold proteins. Knock-down of the plasma membrane quality control proteins CHIP and Hsc70 partially restored ΔF508CFTR-scaffold association. Quantitative comparisons of CFTR cell surface diffusion and endocytosis kinetics suggested an association between reduced scaffold binding and CFTR internalization. Our surface diffusion measurements in live cells indicate defective scaffold interactions of rescued ΔF508CFTR at the cell surface, which may contribute to its defective peripheral processing.     

大鼠MUPP1蛋白PDZ8结构域的生化及晶体结构特性（英文）

多重PDZ结构域蛋白1型(MUPP1)是一种存在于上皮细胞和神经细胞内含有13个PDZ结构域的重要支架蛋白.在上皮细胞中,MUPP1蛋白在紧密连接结构的形成和上皮细胞的极化过程中发挥重要作用.而在中枢神经系统中,MUPP1基因的1个提前终止突变导致了其最后12个PDZ结构域的缺失,以及严重的先天性脑积水.此外,MUPP1蛋白的表达水平与酒精依赖性和药物戒断的严重性也具有显著的相关性.因此,对MUPP1蛋白所含的PDZ结构域进行纯化和性质鉴定,将有助于深入研究MUPP1蛋白的功能和分子机制.在本文研究中,利用亲和纯化和分子筛技术,对大鼠来源的MUPP1蛋白的第8个PDZ结构域进行了表达和纯化.多角度激光光散射的数据表明:MUPP1-PDZ8结构域在溶液中为单体,分子量为16.4 k D.圆二色谱结果表明,MUPP1-PDZ8结构域具有较好的二级结构折叠,测得其熔解温度为71.6摄氏度,暗示该PDZ结构域在溶液中非常稳定.最后,MUPP1-PDZ8结构域的晶体结构显示,该结构域属于I型PDZ结构域,包含3个α螺旋和6个β折叠.其中GLGL模块、β折叠B上的1 351位亮氨酸,以及α螺旋B上的1 405位异亮氨酸/1 398位组氨酸形成的PDZ结合口袋,可以特异性地与其目标蛋白质的羧基末端相结合.综上所述,本文的研究提供了MUPP1-PDZ8结构域的生化特性,以及该结构域与其目标蛋白质相互作用的分子机制,这将为MUPP1蛋白的功能研究提供生物化学与结构生物学的理论基础.     

利用随机多肽文库研究ZO-1中PDZ3结构域的配体结合特点

建立一种研究PDZ结构域配体结合特点的简单方法 .利用酵母双杂交技术从随机多肽文库中寻找所有可能与ZO 1中PDZ3结构域结合的C末端序列 ,从现有蛋白质数据库中检索所有具有该C末端蛋白 .利用液体培养物 β 半乳糖苷酶检测实验 ,比较文库中筛选的C末端序列和已知的PDZ3结构域结合配体———JAM的C末端 (SFLV)与PDZ3结构域结合的强弱 .共筛选到 3个阳性克隆 ,其C末端序列分别为 LGWV、 LVWV和 DEWV .前 2者属于第二类PDZ结构域 ,后者属于第三类 .蛋白质数据库检索结果表明 ,有多个蛋白质具有 LGWV、 LVWV末端 ,没有检索到任何具有 DEWV末端的蛋白质 .结合强度实验结果表明 ,它们与PDZ3结构域结合强度依次为 DEWV > LGWV > LVWV > SFLV ,说明筛选的 3个C末端除了反映ZO 1中PDZ3结构域可能的潜在结合配体外 ,也有可能成为JAM蛋白阻断性试剂甚至药物的重要组成部分之一 .利用随机多肽文库 ,可以尽可能寻找所有可能与PDZ结构域结合的C末端序列 ,大大提高了基因文库筛选的效率     

PSD-95结构域PDZ1过表达拮抗缺氧缺糖诱导的海马神经元凋亡

为了观察突触后致密物质-95（postsynaptic density95,PSD-95）结构域PDZI过表达对缺氧缺糖诱导的海马神经元凋亡的影响,本研究采用培养21d的Sprague—Dawley大鼠海马神经元,加入PDZ2腺病毒颗粒感染24h,收集细胞进行免疫沉淀、免疫印迹实验;缺氧缺糖1．5h后,用DAPI染色后荧光显微镜观察细胞凋亡,并收集细胞进行免疫印迹实验。结果显示：（1）PDZ2在海马神经元中过表达;（2）过表达的PDZ1使缺氧缺糖诱导的海马神经元凋亡数量减少（P〈0．05）;（3）过表达的PDZ1使PSD-95与GluR6结合减少;（4）PDZ1过表达抑制由缺氧缺糖诱导的火鼠海马神经元MLK3和JNK1／2磷酸化。以上结果提示,PDZ1过表达能拈抗缺氧缺糖诱导的海马神经元凋亡。