冠状病毒PLpro蛋白酶对泛素样分子的DUB活性

SARS冠状病毒基因组中非结构基因nsp3编码的木瓜样蛋白酶 (PLpro) 在病毒基因组复制及逃避宿主天然免疫中发挥重要作用,是研发抗病毒药物的重要靶标．SARS冠状病毒PLpro是一种病毒编码的去泛素化酶 (DUB)．为深入研究SARS冠状病毒 PLpro对泛素样分子 (ubiquitin-like protein,UBL) 的DUB特性,本研究构建缺失 PLpro N末端泛素样结构域 (Ubl) 和下游跨膜结构域 (TM) 的PLpro构建体（constructs）,并构建3种缺失蛋白酶催化活性的突变体,检测PLpro对泛素样分子干扰素刺激基因15 (ISG15)及SUMO-1的作用．实验结果表明,PLpro和PLpro-TM 在细胞内具有很强的去ISG(DeISGylation) 活性;缺失PLpro N末端泛素样结构域(Ubl) 对PLpro 的去ISG15 活性没有影响;对PLpro蛋白酶活性位点C1651 和 H1812 突变后,PLpro-TM的去ISG15活性消失,而对D1826位点突变后不影响此活性．PLpro 不具有去SUMO (DeSUMOylation)活性,而PLpro-TM具有一定的去SUMO活性;PLpro催化活性相关的3个关键氨基酸残基 Cys-His-Asp突变后对去SUMO活性有一定的影响．研究结果提示,SARS PLpro除了具有DUB的活性,还具有体内去ISG活性和去SUMO活性;PLpro蛋白酶活性与其去ISG活性之间有一定相关性;PLpro去SUMO-1 活性具有TM 依赖性．SARS冠状病毒PLpro 对泛素样分子作用特性的研究为阐明病毒逃避宿主天然免疫机制和开发新型抗病毒药物提供重要的理论依据．     

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.     

新型冠状病毒PLpro蛋白酶结构与功能的生物信息学分析

2019年12月,由新型冠状病毒(SARS-CoV-2)引起的新型冠状病毒肺炎(COVID-19)在中国武汉暴发。SARS-CoV-2的基因组编码2种病毒蛋白酶,即木瓜样蛋白酶(Papain-like protease,PLpro)和3C样蛋白酶(3C-like protease)。其中PLpro是SARS-CoV-2复制酶复合体(RC)形成的重要调节蛋白分子,对于病毒基因组转录和复制至关重要。因此,将SARS-CoV-2 PLpro作为药物的靶点对COVID-19的治疗具有积极意义。本研究应用生物信息学工具分析新型冠状病毒的木瓜样蛋白酶的结构和功能,首先利用BLAST和BioEdit获取SARS-CoV-2 PLpro蛋白酶(SC2-PLpro)及其同源蛋白的氨基酸序列,并利用BLAST和MEGA 6.0进行同源性分析。之后,利用ProParam和Proscale分别对SC2-PLpro蛋白酶的理化性质、亲水性和疏水性进行分析。然后,通过SOMPA、ScanProsite和InterPro分别预测SC2-PLpro蛋白酶的二级结构和功能区域,进一步利用SignalP 4.0和TMHMM对SC2-PLpro蛋白酶的信号肽和跨膜区进行分析。最后,通过SWISS-MODEL对SARS-CoV-2 PLpro蛋白酶进行三级结构同源建模。结果显示,对SARS-CoV-2 PLpro蛋白酶与已报道的PLpro蛋白酶进行多序列比对后,发现SARS-CoV-2 nsp3的746~1063段氨基酸与多种冠状病毒PLpro蛋白酶氨基酸序列高度相似。同时,同源性分析发现SARS-CoV-2与蝙蝠冠状病毒的PLpro蛋白酶具有同源性,其中与QHR63299、AVP78030相似性最高。对SC2-PLpro进行理化性质预测结果显示,其由318个氨基酸所组成,为稳定亲水性蛋白。二级结构预测结果显示SC2-PLpro主要含有α-螺旋、延伸链、β-转角、无规卷曲,四种结构贯穿整条氨基酸链。进一步进行功能分析,发现其具有完整的催化三联体、锌结合域、泛素样N末端结构域,故推测该蛋白具有去泛素化的功能。然后,信号肽假说和跨膜结构域分析结果表明,SC2-PLpro既不是分泌蛋白,也不属于跨膜蛋白。本研究提示,生物信息学分析SC2-PLpro为稳定性亲水蛋白,属于非跨膜蛋白,比较保守,具有去泛素化的功能,利用此功能可以进一步规避宿主的固有免疫反应。通过制备PLpro蛋白酶小分子抑制剂,可能有助于治疗新型冠状病毒肺炎。     

USP18介导的蛋白质去ISG化及其在结核病等传染病中的作用

干扰素诱导基因15 (interferon-stimulated gene 15,isg15)的表达受Ⅰ型干扰素诱导,该基因编码的蛋白ISG15可以分别通过E1、E2和E3酶的作用共价修饰靶蛋白,此过程被称为ISG化(ISGylation)。宿主蛋白的ISG化广泛参与天然免疫例如宿主的抗病毒过程。泛素特异性蛋白酶18 (ubiquitin-specific protease 18,USP18)作为一种去泛素化酶(deubiquitinase,DUB)可以去除靶蛋白偶联的ISG15,并通过抑制Ⅰ型干扰素信号通路来抑制宿主的免疫应答。ISG15介导的ISG化和USP18介导的去ISG化(deISGylation)建立的动态平衡对结核病的发生、发展和转归有重要影响。此外,同ISG15一样,USP18也广泛参与病毒感染和宿主细胞抗病毒反应,多种先天性免疫疾病和免疫信号通路都受到USP18的调节。本文综述了ISG15和USP18相关的研究进展,重点介绍了ISG15介导的ISGylation和USP18介导的去ISG化在结核病及其他重要疾病中的调控作用,以期为靶向宿主蛋白的结核病等重要疾病防治提供...     

泛素样蛋白ISG15抗病毒机制研究进展

ISG15(Interferon stimulated gene 15,ISG15)蛋白是由干扰素诱导产生的一种泛素样蛋白分子,分子量大小约为15kD。ISG15同泛素分子相类似可以被共价结合于其他蛋白分子上,这种现象称为ISG化(ISGylation)现象。ISG化系统包括ISG15、UBE1L、UBCH8和HERC5四类蛋白分子,协同完成ISG化过程。ISG15及ISG化系统在抗病毒反应中具有重要作用。近几年对于ISG15的抗病毒作用和机制的研究已经有了很大的突破,ISG15的抗病毒作用也越来越受到人们重视,了解清楚ISG15抗病毒机制对于研制新的抗病毒药物及提出新的抗病毒策略具有重要意义。本文对ISG15在不同种病毒中的抗病毒机制研究进展进行了简要综述。     

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．     

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.     

抗病毒天然免疫通路中IRF-3调控新机制

干扰素调节因子-3(interferon regulatory factor-3,IRF-3)是IRF家族中重要 转录因子之一,在调控干扰素(interferon, IFN)基因表达和抗病毒天然免疫反应中具有重要作 用. 最新发现的MITA (mediator of IRF-3 activation, 又称STING/ERIS)蛋白是宿主抗病 毒天然免疫反应中的一种重要调节分子. 病毒侵染时,MITA与IRF-3相互作用,特异性激活 IRF-3,并募集TANK结合激酶1（TANK binding kinase 1, TBK1）与IFN通路中的线粒体抗 病毒信号蛋白MAVS(mitochondrial anti-viral signaling protein)形成复合物,且MITA可 被TBK1磷酸化,诱导Ⅰ型IFN及IFN刺激基因(interferon stimulate genes, ISG)的表达 ,诱发抗病毒天然免疫反应. 同时还发现,泛素连接酶RNF5（ring finger protein 5）可对MITA 发生泛素化修饰从而抑制其对IRF-3活化,实现对宿主抗病毒天然免疫反应负调节作用. 本 室研究发现,严重性急性呼吸系统综合症冠状病毒(severe acute respiratory syndrome co ronavirus, SARS-CoV）和人类新型冠状病毒（human coronavirus NL63, HCoV-NL63）的 木瓜样蛋白酶（papain-like protease, PLP）利用其特有的去泛素化酶（deubiquitinase, DUB）活性,通过宿主细胞泛素-蛋白酶体信号系统对IRF-3的泛素化等翻译后修饰进行调节 ,从而成为该种病毒逃逸机体抗病毒防御系统主要手段之一.     

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.     

类泛素修饰蛋白质ISG15及其修饰酶系的功能

受干扰素诱导表达的干扰素刺激基因15编码蛋白质(ISG15)是第1个被鉴定的类泛素修饰蛋白质.目前已在病毒感染细胞和肿瘤细胞中发现了多种ISG15的作用靶蛋白,提示ISG15可能在免疫调节和肿瘤发生等方面发挥重要作用.本文介绍ISG15的结构与生化特点,探讨ISG15在相关酶系作用下修饰目标蛋白质的机制,总结ISG15及其修饰酶系的抗病毒和抗肿瘤作用及其相关机制.     

Structural Basis for the Ubiquitin-Linkage Specificity and deISGylating Activity of SARS-CoV Papain-Like Protease

Severe acute respiratory syndrome coronavirus (SARS-CoV) encodes a papain-like protease (PLpro) with both deubiquitinating (DUB) and deISGylating activities that are proposed to counteract the post-translational modification of signaling molecules that activate the innate immune response. Here we examine the structural basis for PLpro''s ubiquitin chain and interferon stimulated gene 15 (ISG15) specificity. We present the X-ray crystal structure of PLpro in complex with ubiquitin-aldehyde and model the interaction of PLpro with other ubiquitin-chain and ISG15 substrates. We show that PLpro greatly prefers K48- to K63-linked ubiquitin chains, and ISG15-based substrates to those that are mono-ubiquitinated. We propose that PLpro''s higher affinity for K48-linked ubiquitin chains and ISG15 stems from a bivalent mechanism of binding, where two ubiquitin-like domains prefer to bind in the palm domain of PLpro with the most distal ubiquitin domain interacting with a “ridge” region of the thumb domain. Mutagenesis of residues within this ridge region revealed that these mutants retain viral protease activity and the ability to catalyze hydrolysis of mono-ubiquitin. However, a select number of these mutants have a significantly reduced ability to hydrolyze the substrate ISG15-AMC, or be inhibited by K48-linked diubuiquitin. For these latter residues, we found that PLpro antagonism of the nuclear factor kappa-light-chain-enhancer of activated B-cells (NFκB) signaling pathway is abrogated. This identification of key and unique sites in PLpro required for recognition and processing of diubiquitin and ISG15 versus mono-ubiquitin and protease activity provides new insight into ubiquitin-chain and ISG15 recognition and highlights a role for PLpro DUB and deISGylase activity in antagonism of the innate immune response.     

Selectivity in ISG15 and ubiquitin recognition by the SARS coronavirus papain-like protease

The severe acute respiratory syndrome coronavirus papain-like protease (SARS-CoV PLpro) carries out N-terminal processing of the viral replicase polyprotein, and also exhibits Lys48-linked polyubiquitin chain debranching and ISG15 precursor processing activities in vitro. Here, we used SDS-PAGE and fluorescence-based assays to demonstrate that ISG15 derivatives are the preferred substrates for the deubiquitinating activity of the PLpro. With k(cat)/K(M) of 602,000 M(-1)s(-1), PLpro hydrolyzes ISG15-AMC 30- and 60-fold more efficiently than Ub-AMC and Nedd8-AMC, respectively. Data obtained with truncated ISG15 and hybrid Ub/ISG15 substrates indicate that both the N- and C-terminal Ub-like domains of ISG15 contribute to this preference. The enzyme also displays a preference for debranching Lys48- over Lys63-linked polyubiquitin chains. Our results demonstrate that SARS-CoV PLpro can differentiate between ubiquitin-like modifiers sharing a common C-terminal sequence, and that the debranching activity of the PLpro is linkage type selective. The potential structural basis for the demonstrated specificity of SARS-CoV PLpro is discussed.     

Modification of BECN1 by ISG15 plays a crucial role in autophagy regulation by type I IFN/interferon

ISG15 (ISG15 ubiquitin-like modifier), a ubiquitin-like protein, is one of the major type I IFN (interferon) effector systems. ISG15 can be conjugated to target proteins (ISGylation) via the stepwise action of E1, E2, and E3 enzymes. Conjugated ISG15 can be removed (deISGylated) from target proteins by USP18 (ubiquitin-specific peptidase 18). Here we investigated the role of deISGylation by USP18 in regulating autophagy and EGFR degradation in cells treated with type I IFNs. We show that type I IFN induced expression of ISG15 leads to ISGylation of BECN1 at Lys117, as well as Lys263, Lys265, and Lys266 which competes with Lys63 ubiquitination of BECN1. We demonstrate that ISGylation of BECN1 at Lys117, as well as Lys263, Lys265, and Lys266 serve an important role in negative regulation of intracellular processes including autophagy and EGFR degradation that are critically dependent upon the activity of class III PtdIns 3-kinase. Our studies provide fundamental new mechanistic insights into the innate immunity response implemented by type I IFNs.     

The SARS coronavirus papain like protease can inhibit IRF3 at a post activation step that requires deubiquitination activity

Background

The outcome of a viral infection is regulated by complex interactions of viral and host factors. SARS coronavirus (SARS-CoV) engages and regulates several innate immune response pathways during infection. We have previously shown that the SARS-CoV Papain-like Protease (PLpro) inhibits type I interferon (IFN) by inhibiting IRF3 phosphorylation thereby blocking downstream Interferon induction. This finding prompted us to identify other potential mechanisms of inhibition of PLpro on IFN induction.

Methods

We have used plasmids expressing PLpro and IRF3 including an IRF3 mutant that is constitutively active, called IRF3(5D). In these experiments we utilize transfections, chromatin immunoprecipitation, Electro-mobility Shift Assays (EMSA) and protein localization to identify where IRF3 and IRF3(5D) are inhibited by PLpro.

Results

Here we show that PLpro also inhibits IRF3 activation at a step after phosphorylation and that this inhibition is dependent on the de-ubiquitination (DUB) activity of PLpro. We found that PLpro is able to block the type I IFN induction of a constitutively active IRF3, but does not inhibit IRF3 dimerization, nuclear localization or DNA binding. However, inhibition of PLpro’s DUB activity by mutagenesis blocked the IRF3 inhibition activity of PLpro, suggesting a role for IRF3 ubiquitination in induction of a type I IFN innate immune response.

Conclusion

These results demonstrate an additional mechanism that PLpro is able to inhibit IRF3 signaling. These data suggest novel innate immune antagonism activities of PLpro that may contribute to SARS-CoV pathogenesis.

     

SARS coronavirus papain-like protease inhibits the type I interferon signaling pathway through interaction with the STING-TRAF3-TBK1 complex

SARS coronavirus (SARS-CoV) develops an antagonistic mechanism by which to evade the antiviral activities of interferon (IFN). Previous studies suggested that SARS-CoV papain-like protease (PLpro) inhibits activation of the IRF3 pathway, which would normally elicit a robust IFN response, but the mechanism(s) used by SARS PLpro to inhibit activation of the IRF3 pathway is not fully known. In this study, we uncovered a novel mechanism that may explain how SARS PLpro efficiently inhibits activation of the IRF3 pathway. We found that expression of the membrane-anchored Plpro domain (PLpro-TM) from SARS-CoV inhibits STING/TBK1/IKK?-mediated activation of type I IFNs and disrupts the phosphorylation and dimerization of IRF3, which are activated by STING and TBK1. Meanwhile, we showed that PLpro-TM physically interacts with TRAF3, TBK1, IKK?, STING, and IRF3, the key components that assemble the STING-TRAF3-TBK1 complex for activation of IFN expression. However, the interaction between the components in STING-TRAF3-TBK1 complex is disrupted by PLpro-TM. Furthermore, SARS PLpro-TM reduces the levels of ubiquitinated forms of RIG-I, STING, TRAF3, TBK1, and IRF3 in the STING-TRAF3- TBK1 complex. These results collectively point to a new mechanism used by SARS-CoV through which Plpro negatively regulates IRF3 activation by interaction with STING-TRAF3-TBK1 complex, yielding a SARS-CoV countermeasure against host innate immunity.     

The papain-like protease from the severe acute respiratory syndrome coronavirus is a deubiquitinating enzyme

The severe acute respiratory syndrome coronavirus papain-like protease (SARS-CoV PLpro) is involved in the processing of the viral polyprotein and, thereby, contributes to the biogenesis of the virus replication complex. Structural bioinformatics has revealed a relationship for the SARS-CoV PLpro to herpesvirus-associated ubiquitin-specific protease (HAUSP), a ubiquitin-specific protease, indicating potential deubiquitinating activity in addition to its function in polyprotein processing (T. Sulea, H. A. Lindner, E. O. Purisima, and R. Menard, J. Virol. 79:4550-4551, 2005). In order to confirm this prediction, we overexpressed and purified SARS-CoV PLpro (amino acids [aa]1507 to 1858) from Escherichia coli. The purified enzyme hydrolyzed ubiquitin-7-amino-4-methylcoumarin (Ub-AMC), a general deubiquitinating enzyme substrate, with a catalytic efficiency of 13,100 M(-1)s(-1), 220-fold more efficiently than the small synthetic peptide substrate Z-LRGG-AMC, which incorporates the C-terminal four residues of ubiquitin. In addition, SARS-CoV PLpro was inhibited by the specific deubiquitinating enzyme inhibitor ubiquitin aldehyde, with an inhibition constant of 210 nM. The purified SARS-CoV PLpro disassembles branched polyubiquitin chains with lengths of two to seven (Ub2-7) or four (Ub4) units, which involves isopeptide bond cleavage. SARS-CoV PLpro processing activity was also detected against a protein fused to the C terminus of the ubiquitin-like modifier ISG15, both in vitro using the purified enzyme and in HeLa cells by coexpression with SARS-CoV PLpro (aa 1198 to 2009). These results clearly establish that SARS-CoV PLpro is a deubiquitinating enzyme, thereby confirming our earlier prediction. This unexpected activity for a coronavirus papain-like protease suggests a novel viral strategy to modulate the host cell ubiquitination machinery to its advantage.     

ISG15 and immune diseases

ISG15, the product of interferon (IFN)-stimulated gene 15, is the first identified ubiquitin-like protein, consisting of two ubiquitin-like domains. ISG15 is synthesized as a precursor in certain mammals and, therefore, needs to be processed to expose the C-terminal glycine residue before conjugation to target proteins. A set of three-step cascade enzymes, an E1 enzyme (UBE1L), an E2 enzyme (UbcH8), and one of several E3 ligases (e.g., EFP and HERC5), catalyzes ISG15 conjugation (ISGylation) of a specific protein. These enzymes are unique among the cascade enzymes for ubiquitin and other ubiquitin-like proteins in that all of them are induced by type I IFNs or other stimuli, such as exposure to viruses and lipopolysaccharide. Mass spectrometric analysis has led to the identification of several hundreds of candidate proteins that can be conjugated by ISG15. Some of them are type I IFN-induced proteins, such as PKR and RIG-I, and some are the key regulators that are involved in IFN signaling, such as JAK1 and STAT1, implicating the role of ISG15 and its conjugates in type I IFN-mediated innate immune responses. However, relatively little is known about the functional significance of ISG15 induction due to the lack of information on the consequences of its conjugation to target proteins. Here, we describe the recent progress made in exploring the biological function of ISG15 and its reversible modification of target proteins and thus in their implication in immune diseases.