TLR9介导DNA病毒的免疫识别

Toll样受体(toll-like receptor,TLR)是免疫细胞表面的模式识别受体(patttern recognition receptoi,PRR),参与微生物病原体相关分子模式(pathogen associated molecular patterns,PAMPs)的识别,从而诱导天然免疫应答。迄今在人类已经确定了10个TLRs家族成员。不同的TLRs识别不同的PAMPs,如TLR9是免疫细胞识别病毒和细菌中非甲基化DNA的必需成分;     

TLR9免疫识别CpG DNA的机制与途径

Toll样受体介导的信号转导通路在对抗外来病原微生物的天然免疫应答中起重要作用。新发现的Toll样受体9(TLR9)是哺乳动物识别细菌DNA中非甲基化的胞嘧啶-磷酸-鸟嘌呤基序(CpG DNA)的主要受体。经典的信号转导途径如NF-κB活化通路,MAPK通路在对CpG DNA的应答中均被启动。     

Toll样受体识别机制及其生物学意义

Toll样受体介导的信号转导通路在对抗外来病原体的天然免疫应答中起重要作用。Toll样受体是一个天然模板识别受体家族,能识别固有性模板(微生物和哺乳动物所共有的病原相联的分子模板PAMPs)。Toll样受体通过巨噬细胞和其他免疫细胞来识别,其中TLR4识别内毒素、TLR2识别肽聚糖、TLR9识别细菌DNA、TLR5识别鞭毛蛋白、TLR3识别双链RNA等。本探讨了多种Toll受体家族成员在动物体内识别机理及功能,概述了其应用研究进展。     

双链RNA病毒的复制机制

本文对双链ＲＮＡ（ｄｓＲＮＡ）病毒复制机制的研究进展进行了综述。根据ｄｓＲＮＡ病毒复制周期,分以下几方面对其复制的有关分子进行分析：转录、转录本释放和“满头”复制模型、（＋）ＲＮＡ转译、病毒包装、（－）ＲＮＡ合成等。此外,还简要分析了宿主基因及其产物在病毒复制中的作用。     

EB病毒免疫逃逸的分子机制

EB病毒(Epstein-Barr vius,EBV)是一种最广泛的对人类感染的γ疱疹病毒,与人类多种疾病尤其是恶性肿瘤有关。其致病的一个重要条件是能够在人体B细胞中长期潜伏,并且在人体免疫力低下时被激活并增殖,这表明EB病毒存在逃逸宿主细胞免疫的机制。从潜伏期EB病毒基因表达的下调、干扰抗原加工和提呈、调节细胞毒性T细胞(Cytotoxic lymphocyte,CTL)免疫应答、干扰细胞因子的作用、干扰CTL的活动及抑制宿主细胞凋亡、抑制辅助性T细胞1(Helper T cell 1,Th1)免疫应答等方面,对EB病毒免疫逃逸的分子机制作一简要综述。     

TLR/MyD88信号通路与自身免疫性疾病

Toll样受体(Toll-like receptor,TLR)是近年来发现的一类模式识别受体,通过识别病原相关分子模式(pathogen-associated molecular pattern,PAMP),激活天然免疫.TLR信号还通过上调抗原提呈细胞(antigen presenting cells,APC)表面共刺激分子及APC分泌的炎症细胞因子调节获得性免疫.TLR/MyD88信号在自身免疫性疾病的发病过程中起重要作用.本文介绍了TLR/MYD88信号通路及其在自身免疫病如实验性自身免疫脑脊髓膜炎、类风湿性关节炎、实验性自身免疫性葡萄膜炎、实验性自身免疫性心肌炎和自身免疫性肾小球肾炎等发生发展中的作用.     

疫苗诱导机体免疫应答机制研究

人类接种疫苗已有200多年的历史,疫苗的应用使得历史上流行的多种传染病得以消灭或控制,挽救了无数人的生命。疫苗免疫机制是全世界疫苗研究者亟待解决的问题。对疫苗免疫机制的一些新认识,极大地促进了疫苗研发。对疫苗天然免疫机制的揭示,在疫苗株的筛选、疫苗免疫效果预测等方面展现了巨大的应用价值。某些疫苗在接种后存在的低应答与无应答现象,在对其免疫机制的探索中得到了解释。此外,对疫苗佐剂免疫机制的揭示,加速了新型疫苗佐剂的研发与应用。对疫苗免疫机制研究中的一些新进展进行了综述。     

肠道病毒调控固有免疫的分子机制研究进展

肠道病毒属于小核糖核酸病毒科,包括脊髓灰质炎病毒等多种重要人类病原体,已成为全球公共卫生安全的重大威胁之一。固有免疫是机体早期抵御病毒感染的重要防线。不同肠道病毒在进化中已经具备了多种途径躲避免疫识别或诱导固有免疫系统失活。本文重点对肠道病毒调控宿主固有免疫的相关分子机制进行综述,系统整理了肠道病毒逃避干扰素依赖与干扰素非依赖的抗病毒固有免疫防御的分子特征与作用规律,为肠道病毒致病机制的探究和抗病毒药物的研发提供参考。     

RIG-Ⅰ样受体信号通路介导的小RNA病毒免疫逃逸研究进展

病毒与宿主在长期的斗争中共同进化,病毒形成各种逃逸机制来躲避宿主的免疫应答.本文针对小RNA病毒科成员如何通过逃逸RIG-Ⅰ样模式识别受体介导的先天免疫反应进行介绍,为深入了解RNA病毒的逃逸机制奠定基础,同时也为相关疫苗及药物的研制提供思路.     

Lateral clustering of TLR3:dsRNA signaling units revealed by TLR3ecd:3Fabs quaternary structure

Toll-like receptor 3 (TLR3) recognizes dsRNA and initiates an innate immune response through the formation of a signaling unit (SU) composed of one double-stranded RNA (dsRNA) and two TLR3 molecules. We report the crystal structure of human TLR3 ectodomain (TLR3ecd) in a quaternary complex with three neutralizing Fab fragments. Fab15 binds an epitope that overlaps the C-terminal dsRNA binding site and, in biochemical assays, blocks the interaction of TLR3ecd with dsRNA, thus directly antagonizing TLR3 signaling through inhibition of SU formation. In contrast, Fab12 and Fab1068 bind TLR3ecd at sites distinct from the N- and C-terminal regions that interact with dsRNA and do not inhibit minimal SU formation with short dsRNA. Molecular modeling based on the co-structure rationalizes these observations by showing that both Fab12 and Fab1068 prevent lateral clustering of SUs along the length of the dsRNA ligand. This model is further supported by cell-based assay results using dsRNA ligands of lengths that support single and multiple SUs. Thus, their antagonism of TLR3 signaling indicates that lateral clustering of SUs is required for TLR3 signal transduction.     

植物抗病毒分子机制的研究进展

植物在进化过程中为微生物提供了丰富的物质环境,微生物的生存依赖于植物的生物合成和产生能量的能力.有近450种植物致病病毒,可导致一系列的疾病.但植物不是被动地面对病毒的攻击,而是进化了精细而有效的防御机制来抵抗、限制或损害病毒的感染.植物抗病基因(R-gene)可以抵抗包括病毒在内的多种病原体.由特定病毒而引发的防御反应是先天固有的,而且研究人员已经鉴定了与这种防御反应相关的细胞学和生理学特性.作为抵抗外来核酸(包括病毒)的重要细胞防御途径,RNA沉默近来获得了显著性的研究进展.在植物中这些途径的协同作用有效地防御了病毒的感染.     

Ⅱ类囊膜病毒膜融合的分子机制

病毒囊膜与宿主细胞膜的膜融合是囊膜病毒入侵的重要过程,病毒囊膜融合糖蛋白的一系列结构变化引发此过程.综述了Ⅱ类囊膜病毒、弹状病毒及疱疹病毒融合蛋白结构与功能研究的最新进展,介绍了软件分析并定位融合蛋白功能区域的方法.Ⅱ类病毒与Ⅰ类病毒融合蛋白的融合前结构不同,但融合后结构(发夹三聚体结构)相似.弹状病毒与疱疹病毒的融合蛋白集合了Ⅰ/Ⅱ类融合蛋白的某些特征,但其结构变化及融合过程各不相同,被归为新型融合蛋白.上述研究为基础设计的以病毒融合过程为靶标的抑制子,可为抗病毒新药的研制提供新思路.     

Structures of Arenaviral Nucleoproteins with Triphosphate dsRNA Reveal a Unique Mechanism of Immune Suppression

A hallmark of severe Lassa fever is the generalized immune suppression, the mechanism of which is poorly understood. Lassa virus (LASV) nucleoprotein (NP) is the only known 3′-5′ exoribonuclease that can suppress type I interferon (IFN) production possibly by degrading immune-stimulatory RNAs. How this unique enzymatic activity of LASV NP recognizes and processes RNA substrates is unknown. We provide an atomic view of a catalytically active exoribonuclease domain of LASV NP (LASV NP-C) in the process of degrading a 5′ triphosphate double-stranded (ds) RNA substrate, a typical pathogen-associated molecular pattern molecule, to induce type I IFN production. Additionally, we provide for the first time a high-resolution crystal structure of an active exoribonuclease domain of Tacaribe arenavirus (TCRV) NP. Coupled with the in vitro enzymatic and cell-based interferon suppression assays, these structural analyses strongly support a unified model of an exoribonuclease-dependent IFN suppression mechanism shared by all known arenaviruses. New knowledge learned from these studies should aid the development of therapeutics against pathogenic arenaviruses that can infect hundreds of thousands of individuals and kill thousands annually.     

dsRNA induces apoptosis through an atypical death complex associating TLR3 to caspase-8

Toll-like receptor 3 (TLR3) is a pattern-recognition receptor known to initiate an innate immune response when stimulated by double-stranded RNA (dsRNA). Components of TLR3 signaling, including TIR domain-containing adapter inducing IFN-α (TRIF), have been demonstrated to contribute to dsRNA-induced cell death through caspase-8 and receptor interacting protein (RIP)1 in various human cancer cells. We provide here a detailed analysis of the caspase-8 activating machinery triggered in response to Poly(I:C) dsRNA. Engagement of TLR3 by dsRNA in both type I and type II lung cancer cells induces the formation of an atypical caspase-8-containing complex that is devoid of classical death receptors of the TNFR superfamily, but instead is physically associated to TLR3. The recruitment of caspase-8 to TLR3 requires RIP1, and is negatively modulated by cellular inhibitor of apoptosis protein (cIAP)2-TNF receptor-associated factor (TRAF)2-TNFR-associated death domain (TRADD) ubiquitin ligase complex, which regulates RIP1 ubiquitination. Intriguingly, unlike Fas- or TRAILR-dependent death signaling, caspase-8 recruitment and activation within the TLR3 death-signaling complex appears not to be stringently dependent on Fas-associated with death domain (FADD). Our findings uncover a novel aspect of the molecular mechanisms involved during apoptosis induced by the innate immune receptor TLR3 in cancer cells.     

囊膜病毒膜融合分子机制研究进展

囊膜病毒通过病毒与宿主细胞膜融合的方式感染宿主,病毒囊膜蛋白介导了膜融合过程。根据这些囊膜蛋白在病毒囊膜表面的排列、蛋白结构及其在融合肽中的位置不同,可将囊膜病毒分为三类,其利用这些囊膜特殊的蛋白分子与受体相互作用完成膜融合。在分子水平上研究这一过程有助于认识病毒侵染的本质和发现关键环节,达到预防与治疗病毒病的目的。