人类冠状病毒调节宿主抗病毒天然免疫分子机制

SARS冠状病毒和正在全球流行的猪源H1N1型流感病毒等人类新发呼吸道病毒对人类生命健康构成严重威胁.人类重要呼吸道病毒与宿主抗病毒天然免疫的关系是近年来研究热点.SARS冠状病毒等很多RNA病毒能够编码某种蛋白质,抑制干扰素表达以及干扰素介导的抗病毒信号通路.人类冠状病毒木瓜样蛋白酶(papain-like protease,PLP)利用其自身去泛素化酶(DUB)活性,使干扰素表达通路中重要调节蛋白发生去泛素化,从而抑制干扰素信号传导.同时,PLP蛋白酶通过阻碍干扰素表达信号通路中最新发现的重要调节蛋白ERIS(也称MITA/STING)二聚化,使其失活并丧失激活干扰素通路的功能,这些发现对于阐明人类重要呼吸道病毒对宿主细胞抗病毒天然免疫反应的调节作用及其机制具有重要意义,为人类新发病毒致病机理、免疫防治以及抗病毒药物研究提供新的思路.     

猪流行性腹泻病毒与宿主抗病毒天然免疫抑制

猪流行性腹泻病毒(porcine epidemic diarrhea virus,PEDV)能引起猪腹泻等肠道疾病,属于α属冠状病毒,它的爆发给很多国家养猪业造成了严重的经济损失。2010年以来,PEDV感染在中国出现大规模爆发,一种突变型PEDV也于2013年在美国出现并迅速传播。 RNA病毒能够通过Toll样受体通路3（TLR3）和RIG-I样受体通路（RLR）诱导I型干扰素的产生。但以往的研究表明,PEDV感染能抑制I型干扰素的合成。近年来有关PEDV调节宿主天然免疫应答的研究取得了很大进展。PEDV主要通过编码作为干扰素拮抗剂的病毒蛋白以及隐藏病毒自身病原相关分子模式（PAMP）等两种方式逃逸宿主天然免疫应答。目前已报道,PEDV非结构蛋白1可通过降解CBP阻碍干扰素调节因子3(IRF-3)组装成增强子复合体;木瓜蛋白酶样蛋白酶可通过其去泛素化酶活性阻断天然免疫信号通路传递;3C样蛋白酶可通过剪切NEMO发挥干扰素拮抗剂活性;核衣壳蛋白通过结合TBK1抑制I型干扰素产生。PEDV也可通过合成加帽酶隐藏其病原相关分子dsRNA来避免激活天然免疫通路。PEDV抗病毒天然免疫机制阐明为研究PEDV感染免疫和致病机制提供了重要的理论依据,为研发抗PEDV新型疫苗和药物提供了基础。     

NL63冠状病毒木瓜样蛋白酶去泛素化酶活性和对宿主抗病毒天然免疫反应调节作用

引起人类呼吸道感染的冠状病毒已多达5种．冠状病毒与宿主相互作用决定了其致病性和免疫特性．冠状病毒感染后宿主会立即启动抗病毒天然免疫反应,而人类冠状病毒往往会编码特定蛋白逃逸或抑制宿主的天然免疫反应．NL63冠状病毒是一种新型人类冠状病毒,其非结构蛋白nsp3编码2个木瓜样蛋白酶(PLP)核心结构域PLP1和PLP2．前期研究发现,人类冠状病毒PLP2是一种病毒编码的去泛素化酶(DUB),但是对其DUB特性和功能还不清楚．研究发现,NL63冠状病毒PLP1和PLP2两个核心结构域中只有PLP2具有DUB活性,而且,PLP2的DUB活性对K48和K63连接的多聚泛素化修饰不表现明显特异性．同时,蛋白酶活性催化位点C1678和H1836突变后对其DUB活性有明显抑制作用,而蛋白酶活性催化位点D1849突变后对DUB活性无影响．其次,PLP2而非PLP1核心结构域能够明显抑制仙台病毒和重要信号蛋白(RIG-I、ERIS/STING/MITA)激活的干扰素表达,表明PLP2是一种冠状病毒编码的干扰素拮抗剂,而且PLP2的干扰素拮抗作用不完全依赖其蛋白酶活性．机制研究表明,PLP2能够与干扰素表达通路中的重要调节蛋白RIG-I和ERIS发生相互作用,通过对RIG-I和ERIS的去泛素化负调控宿主抗病毒天然免疫反应．此外,PLP2除利用DUB活性抑制干扰素表达外,很可能存在不依赖自身催化活性的其他组分共同抑制干扰素的产生．以上研究对阐明人类新发冠状病毒免疫和致病机理以及抗病毒药物研发具有重要参考价值．     

SARS冠状病毒PLpro蛋白酶的结构与功能

SARS冠状病毒基因组编码2种病毒蛋白酶,即木瓜样蛋白酶（PLpro）和3C样蛋白酶(3CLpro).其中,PLpro蛋白酶结构与功能研究是近年来冠状病毒分子生物学研究的热点之一. PLpro蛋白酶参与SARS冠状病毒1a(1ab)复制酶多聚蛋白N端部分的切割加工,是SARS冠状病毒复制酶复合体(RC)形成的重要调节蛋白分子;最新研究表明,SARS冠状病毒PLpro蛋白酶是一种病毒编码的去泛素化酶（DUB）,对细胞蛋白具有明显去泛素化作用;而且对泛素(Ub)和泛素样分子ISG15均具有活性. PLpro蛋白酶对宿主抗病毒天然免疫反应具有负调节作用,是SARS冠状病毒的一种重要干扰素拮抗分子.PLpro蛋白酶是一种多功能病毒蛋白酶.本文结合作者课题组研究工作,对SARS冠状病毒PLpro蛋白酶结构和功能研究最新进展进行综述.     

猪流行性腹泻病毒(PEDV)与抗病毒天然免疫

猪流行性腹泻病毒(porcine epidemic diarrhea virus,PEDV)是引起猪流行性腹泻病等肠道疾病的一种动物冠状病毒.PEDV与宿主系统相互作用,特别是其对宿主抗病毒天然免疫调节作用和机制是目前动物冠状病毒研究的基础科学问题之一.基于作者近几年来对人类重要冠状病毒对宿主抗病毒天然免疫系统调节作用的研究,本文对PEDV基因组与编码蛋白主要功能以及PEDV调节宿主抗病毒天然免疫反应及其可能机制的进展和现状进行了分析.与人类冠状病毒相似,PEDV编码的木瓜样蛋白酶(papain like protease,PLP)是一个多功能蛋白酶,除了蛋白酶活性外,还具有去泛素化酶(DUB)活性和宿主干扰素拮抗活性,是PEDV编码的一种新型病毒来源DUB和宿主干扰素拮抗蛋白.这些研究为阐明PEDV对宿主抗病毒天然免疫反应调节作用和其致病机制提供了重要的理论依据,为研制新型PEDV免疫防治措施提供了重要理论基础.     

干扰素调节因子的抑制肿瘤作用

干扰素（interferon,IFN）具有调节机体免疫功能、抗病毒、抗肿瘤等多种作用,是机体防御系统的重要组成部分。目前,基因工程生产的干扰素已广泛应用于临床治疗多种肿瘤。干扰素调节因子（IRF）家族在IFN的诱导表达中起着重要的调节作用。已发现了9个IRF成员,其中IRF-1和IRF-2的表达水平与宫颈癌、乳腺癌等有关;IRF-3与食管癌、宫颈癌等密切相关;IRF-5可以抑制B细胞淋巴瘤;IRF-7与乳腺癌相关;IRF-8和IRF-4参与慢性髓细胞性白血病的发病机制。     

STING在宿主天然免疫信号通路中的调节作用

STING(stimulator of interferon genes)是天然免疫信号通路中一种新发现的蛋白质,在防御病毒及胞内细菌感染、介导Ⅰ型IFN产生过程中发挥重要功能.来自病原体的B型DNA与5′-3p dsRNA暴露在宿主细胞中后被相应的模式识别受体识别,通过不同的通路传递信号给STING.STING随后通过相似的机制招募TBK1激活IRF3,诱导干扰素表达.对细菌中的环二核苷酸c-di-GMP和c-di-AMP,STING则可以直接作为模式识别受体引发Ⅰ型干扰素反应.此外STING还能激活STAT6诱导特异趋化因子产生,吸引各种免疫细胞抵抗病毒感染.本文通过对STING的发现、结构、定位、功能、机理以及调节机制进行综述,以期为揭示病毒逃逸天然免疫调节机制和抗病毒新型免疫调节剂提供新的思路.     

泛素化调控抗病毒天然免疫的研究进展

天然免疫是宿主防御病原微生物入侵的第一道防线,其活化主要通过天然免疫细胞上的模式识别受体(pattern recognition receptors, PRRs)识别病原微生物上相对保守的相关分子模式(pathogen-associated molecular patterns, PAMPs).病毒相关的核酸成分可以被机体Toll样受体(Toll-like receptors, TLRs)、维甲酸诱导基因Ⅰ受体(RIG-I-like receptors, RLRs)以及胞浆DNA受体(cytoplasmic DNA sensors)等识别,通过一系列复杂的细胞信号通路诱导Ⅰ型干扰素(typeⅠinterferon)及炎症因子的表达,从而激发机体抗病毒反应.泛素化修饰是细胞内广泛存在的蛋白质翻译后修饰方式,在宿主防御病原微生物感染的动态调控过程中发挥着重要的作用.已有大量文献报道,天然免疫抗病毒信号通路中的多个关键接头分子可发生泛素化修饰,进而调控机体抗病毒免疫应答反应.本文综述了泛素化修饰在抗病毒天然免疫中的作用及其调控机制.     

长链非编码RNA——抗病毒天然免疫应答的新兴调控因子

长链非编码RNA(long non-coding RNAs, lncRNAs)是长度超过200nt的非编码RNA分子的总称。作为一类重要的基因调控因子,lncRNAs在表观遗传学、转录及转录后等多个水平调控靶基因的表达。近年来的研究表明,许多lncRNAs可被病毒或干扰素(interferon, IFN)诱导表达,并作为调控因子在IFN介导的抗病毒天然免疫应答中调节抗病毒相关基因的表达。本文重点阐述了lncRNAs在IFN介导的抗病毒天然免疫应答中的调控作用,尤其是对干扰素刺激基因(interferon-stimulated genes, ISGs)转录的调控作用,并归纳了lncRNAs、IFN和ISGs形成的调控网络,以期为从事lncRNAs调控IFN介导的抗病毒天然免疫应答机制研究的相关科研人员提供参考。     

RIG-Ⅰ介导的TLR非依赖性模式识别

天然免疫在机体抗病毒感染的过程中发挥重要作用.近年来,识别和感受病原体的一系列模式识别受体受到广泛关注,TLR（Toll-like receptor）便是这一领域中的热点,随着研究的深入,一类TLR非依赖性模式识别受体,逐渐活跃在天然免疫识别的舞台,这其中,解旋酶（helicase）家族中的重要成员--维甲酸诱导基因Ⅰ（retinoic acid-induced geneⅠ,RIG-Ⅰ）,主要识别并直接结合到某些5＇端磷酸化RNA病毒,通过蛋白质-蛋白质接触方式,与其受体MAVS（mitochondrial antiviral signaling protein）也称作VISA（virus induced signaling adaptor）、IPS-1（IFN-promoter stimulating factor）或Cardif结合,活化TBK1和IKKe,激活转录因子NF-kB、IRF-3,引起Ⅰ型干扰素分泌上调,发挥抗病毒效应.RIG-Ⅰ途径除了在天然免疫中发挥抗病毒作用以外,也是一些病毒逃逸机体免疫的靶点,如HCV、HAV、GB病毒等.     

Coronavirus papain-like proteases negatively regulate antiviral innate immune response through disruption of STING-mediated signaling

Viruses have evolved elaborate mechanisms to evade or inactivate the complex system of sensors and signaling molecules that make up the host innate immune response. Here we show that human coronavirus (HCoV) NL63 and severe acute respiratory syndrome (SARS) CoV papain-like proteases (PLP) antagonize innate immune signaling mediated by STING (stimulator of interferon genes, also known as MITA/ERIS/MYPS). STING resides in the endoplasmic reticulum and upon activation, forms dimers which assemble with MAVS, TBK-1 and IKKε, leading to IRF-3 activation and subsequent induction of interferon (IFN). We found that expression of the membrane anchored PLP domain from human HCoV-NL63 (PLP2-TM) or SARS-CoV (PLpro-TM) inhibits STING-mediated activation of IRF-3 nuclear translocation and induction of IRF-3 dependent promoters. Both catalytically active and inactive forms of CoV PLPs co-immunoprecipitated with STING, and viral replicase proteins co-localize with STING in HCoV-NL63-infected cells. Ectopic expression of catalytically active PLP2-TM blocks STING dimer formation and negatively regulates assembly of STING-MAVS-TBK1/IKKε complexes required for activation of IRF-3. STING dimerization was also substantially reduced in cells infected with SARS-CoV. Furthermore, the level of ubiquitinated forms of STING, RIG-I, TBK1 and IRF-3 are reduced in cells expressing wild type or catalytic mutants of PLP2-TM, likely contributing to disruption of signaling required for IFN induction. These results describe a new mechanism used by CoVs in which CoV PLPs negatively regulate antiviral defenses by disrupting the STING-mediated IFN induction.     

Mechanism of inhibiting type I interferon induction by hepatitis B virus X protein

Hepatitis B virus (HBV) is regarded as a stealth virus, invading and replicating efficiently in human liver undetected by host innate antiviral immunity. Here, we show that type I interferon (IFN) induction but not its downstream signaling is blocked by HBV replication in HepG2.2.15 cells. This effect may be partially due to HBV X protein (HBx), which impairs IFNβ promoter activation by both Sendai virus (SeV) and components implicated in signaling by viral sensors. As a deubiquitinating enzyme (DUB), HBx cleaves Lys63-linked polyubiquitin chains from many proteins except TANK-binding kinase 1 (TBK1). It binds and deconjugates retinoic acid-inducible gene I (RIG I) and TNF receptor-associated factor 3 (TRAF3), causing their dissociation from the downstream adaptor CARDIF or TBK1 kinase. In addition to RIG I and TRAF3, HBx also interacts with CARDIF, TRIF, NEMO, TBK1, inhibitor of kappa light polypeptide gene enhancer in B-cells, kinase epsilon (IKKi) and interferon regulatory factor 3 (IRF3). Our data indicate that multiple points of signaling pathways can be targeted by HBx to negatively regulate production of type I IFN.     

RNF26 Temporally Regulates Virus-Triggered Type I Interferon Induction by Two Distinct Mechanisms

Viral infection triggers induction of type I interferons (IFNs), which are critical mediators of innate antiviral immune response. Mediator of IRF3 activation (MITA, also called STING) is an adapter essential for virus-triggered IFN induction pathways. How post-translational modifications regulate the activity of MITA is not fully elucidated. In expression screens, we identified RING finger protein 26 (RNF26), an E3 ubiquitin ligase, could mediate polyubiquitination of MITA. Interestingly, RNF26 promoted K11-linked polyubiquitination of MITA at lysine 150, a residue also targeted by RNF5 for K48-linked polyubiquitination. Further experiments indicated that RNF26 protected MITA from RNF5-mediated K48-linked polyubiquitination and degradation that was required for quick and efficient type I IFN and proinflammatory cytokine induction after viral infection. On the other hand, RNF26 was required to limit excessive type I IFN response but not proinflammatory cytokine induction by promoting autophagic degradation of IRF3. Consistently, knockdown of RNF26 inhibited the expression of IFNB1 gene in various cells at the early phase and promoted it at the late phase of viral infection, respectively. Furthermore, knockdown of RNF26 inhibited viral replication, indicating that RNF26 antagonizes cellular antiviral response. Our findings thus suggest that RNF26 temporally regulates innate antiviral response by two distinct mechanisms.     

Expression profiles of carp IRF-3/-7 correlate with the up-regulation of RIG-I/MAVS/TRAF3/TBK1, four pivotal molecules in RIG-I signaling pathway

The cytoplasmic helicase protein RIG-I (retinoic acid-inducible gene I) and downstream signaling molecules, MAVS (mitochondrial antiviral signaling protein), TRAF3 (TNF-receptor-associated factor 3) and TBK1 (TANK-binding kinase 1), have significant roles in the recognition of cytoplasmic 5'-triphosphate ssRNA and short dsRNA, and phosphorylation of IRF-3 (interferon regulatory factor 3) and IRF-7 which is responsible for the induction of type I interferons (IFN). In the present study, the full-length cDNAs of RIG-I, MAVS, TRAF3 and TBK1 were cloned and identified in common carp (Cyprinus carpio L.). The deduced protein of carp RIG-I is of 946 aa (amino acids), consisting of two CARDs (caspase-recruitment domain), a DEXDc (DExD/H box-containing domain), a HELICc (helicase superfamily c-terminal domain) and a RD (regulatory domain). Carp MAVS is of 585 aa, containing a CARD, a proline-rich region and a TM (transmembrane domain). Carp TRAF3 encodes a protein of 573 aa, including a RING (really interesting new gene), two TRAF-type zinc fingers, a coiled coil and a MATH-TRAF3 (meprin and TRAF homology) domain. Carp TBK1 is of 727 aa and contains a S_TKc domain (Serine/Threonine protein kinases, catalytic domain). Carp RIG-I, MAVS, TRAF3 and TBK1 mRNAs are ubiquitously expressed in all tissues examined. In response to SVCV infection, carp RIG-I and MAVS mRNAs were up-regulated at different levels in spleen, head kidney and intestine tissues at different time points. Similarly, both carp IRF-3 and IRF-7 mRNAs were significantly up-regulated in the detected tissues. Especially in intestine, the IRF-3 and IRF-7 mRNAs of carp increased and reached 25.3-fold (at 3 dpi) and 224.7-fold (at 5 dpi). Noteworthily, a significant growth of carp TRAF3 and TBK1 mRNA was also mainly found in intestine (7.0-fold and 11.3-fold at 5 dpi, respectively). These data implied that the expression profiles of IRF-3/-7 mRNAs in carp correlate with the up-regulation of RIG-I/MAVS/TRAF3/TBK, and carp RIG-I and MAVS may be involved in antiviral responses through the RIG-I viral recognition signaling pathway in a TRAF3/TBK1-dependent manner.     

Mechanisms of the TRIF-induced interferon-stimulated response element and NF-kappaB activation and apoptosis pathways

Toll-like receptor-3 is critically involved in host defense against viruses through induction of type I interferons (IFNs). Recent studies suggest that a Toll/interleukin-1 receptor domain-containing adapter protein (TRIF) and two protein kinases (TANK-binding kinase-1 (TBK1) and IkappaB kinase (IKK)-epsilon) are critically involved in Toll-like receptor-3-mediated IFN-beta production through activation of IFN regulatory factor (IRF)-3 and IRF-7. In this study, we demonstrate that TRIF interacts with both IRF-7 and IRF-3. In addition to TBK1 and IKKepsilon, our results indicate that IKKbeta can also phosphorylate IRF-3 and activate the IFN-stimulated response element. TRIF-induced IRF-3 and IRF-7 activation was mediated by TBK1 and its downstream kinases IKKbeta and IKKepsilon. TRIF induced NF-kappaB activation through an IKKbeta- and tumor necrosis factor receptor-associated factor-6-dependent (but not TBK1- and IKKepsilon-dependent) pathway. In addition, TRIF also induced apoptosis through a RIP/FADD/caspase-8-dependent and mitochondrion-independent pathway. Furthermore, our results suggest that the TRIF-induced IFN-stimulated response element and NF-kappaB activation and apoptosis pathways are uncoupled and provide a molecular explanation for the divergent effects induced by the adapter protein TRIF.     

IFN-induced TPR protein IFIT3 potentiates antiviral signaling by bridging MAVS and TBK1

Intracellular RNA viruses are sensed by receptors retinoic acid-inducible gene I/MDA5, which trigger formation of the mitochondrial antiviral signaling (MAVS) complex on mitochondria. Consequently, this leads to the activation of TNFR-associated factor family member-associated NF-κB activator-binding kinase 1 (TBK1) and phosphorylation of IFN regulatory factor 3 (IRF3). It remains to be elucidated how MAVS activates TBK1/IRF3. In this study, we report that IFN-induced protein with tetratricopeptide repeats 3 (IFIT3) is significantly induced upon RNA virus infection. Ectopic expression or knockdown of IFIT3 could, respectively, enhance or impair IRF3-mediated gene expression. Mechanistically, the tetratrico-peptide repeat motif (E164/E165) of IFIT3 interacts with the N terminus (K38) of TBK1, thus bridging TBK1 to MAVS on the mitochondrion. Disruption of this interaction markedly attenuates the activation of TBK1 and IRF3. Furthermore, host antiviral responses are significantly boosted or crippled in the presence or absence of IFIT3. Collectively, our study characterizes IFIT3 as an important modulator in innate immunity, revealing a new function of the IFIT family proteins (IFN-induced protein with tetratricopeptide repeats).