与猪流行性腹泻病毒M蛋白互作的宿主蛋白的鉴定

【背景】猪流行性腹泻病毒(Porcine epidemic diarrhea virus,PEDV)膜蛋白(M)在病毒粒子的组装、膜融合和病毒复制等方面具有重要的作用,但M蛋白与宿主细胞的互作机制尚不清楚。【目的】利用免疫沉淀技术和液质联用技术筛选细胞内与PEDVM蛋白相互作用的蛋白,为揭示M蛋白在病毒增殖过程中发挥的功能提供研究基础。【方法】将MOI=0.1的PEDV DR13疫苗株接种于长成单层的Vero细胞,感染36 h后,收集细胞并进行裂解。利用抗M的单克隆抗体沉淀与M相互作用蛋白复合物,通过液相色谱串联质谱(LC-MS/MS)进行鉴定并利用细胞功能富集分析(Gene ontology,GO)对感染组鉴定到的细胞蛋白进行分析,确定两个细胞内源性蛋白为候选蛋白,进行免疫共沉淀(Co-IP)验证和共定位分析。【结果】基于鉴定蛋白的肽段数的方法分析显示,感染组与对照组相比,鉴定了218个与M蛋白相互作用的细胞内源性蛋白,分别与蛋白质合成、代谢、细胞信号通路转导等密切相关,选择细胞分裂周期蛋白42 (Cell division cycle 42,CDC42)、真核翻译起始因子3亚基L蛋白(eIF3L)为候选蛋白进行Co-IP(Co-immunoprecipitation)验证和共定位分析,结果证实CDC42、eIF3L蛋白分别与M蛋白在细胞内存在相互作用。【结论】鉴定出PEDV M蛋白能够与宿主细胞CDC42和eIF3L蛋白相互作用,并鉴定出其他可能与M蛋白发生相互作用的宿主蛋白60个,为开展PEDV与宿主细胞蛋白相互作用研究提供了重要理论依据。     

PIAS1对PRRSV N蛋白SUMO化修饰及病毒复制的影响

【目的】猪繁殖与呼吸综合征病毒(PRRSV)是一种危害全球养猪业的重要病原。SUMO(Small ubiquitin-like modifier)化修饰作为一种可逆的翻译后修饰在调节病毒复制方面发挥着重要功能。PIAS1(Protein inhibitor of activated STAT1)是SUMO E3连接酶PIAS家族的一员,可以促进靶蛋白的SUMO化修饰,进而影响靶蛋白的功能,参与基因转录调控过程。探究PIAS1与PRRSV N蛋白相互作用的机制及其对N蛋白SUMO化修饰和病毒复制的影响,为进一步阐明PRRSV复制调控和致病的分子机制提供科学依据。【方法】利用酵母回复杂交、免疫共沉淀和激光共聚焦技术验证N蛋白与PIAS1的相互作用;以递增剂量外源性转染PIAS1观察其是否介导N蛋白SUMO化修饰;采用RNA干扰和慢病毒转导技术测定PIAS1对PRRSV复制的影响。【结果】PIAS1能与N蛋白相互作用,而且两者主要共定位于胞浆中;外源转染PIAS1并未增加N蛋白SUMO化修饰水平;在MARC-145细胞中,PIAS1的表达有利于PRRSV的复制。【结论】PIAS1可促进PRRSV的复制。     

风疹病毒衣壳蛋白与宿主细胞相互作用蛋白的初步筛选及分析

风疹病毒(Rubella virus,RV)的衣壳蛋白(Capsid protein,CP)不仅是病毒颗粒的重要组成部分,而且还可以通过与宿主蛋白之间的相互作用来调控病毒的转录和复制.为了系统研究衣壳蛋白与宿主蛋白之间的相互作用关系,我们从RV基因组中克隆获得衣壳蛋白基因序列,将该序列导入含有eXact-6His串联亲和纯化标签的慢病毒表达载体中,并构建了稳定表达eXact-6His-Capsid融合蛋白的293T细胞系.通过eXact和6His标签的两次亲和纯化获得衣壳蛋白相互作用蛋白复合物,质谱检测并筛选后发现22个可能与衣壳蛋白相互作用的宿主蛋白.随后构建衣壳蛋白的相互作用网络并进行功能学分析,发现其相互作用蛋白主要参与病毒感染、RNA剪切、细胞凋亡及酶相关通路等过程.     

禽传染性支气管炎病毒Nsp2蛋白与宿主蛋白eIF2α的互作鉴定

Nsp2蛋白是冠状病毒的非结构蛋白,在病毒早期感染中具有重要作用。【目的】为初步筛选可能与禽传染性支气管炎病毒(avian infectious bronchitis virus,IBV) Nsp2蛋白互作的宿主蛋白,鉴定Nsp2蛋白与真核翻译起始因子2α亚基(eIF2α)的相互作用。【方法】以pCAGGs-Flag-Nsp2和pCAGGs-Flag载体转染后的鸡胚肾(CEK)细胞为研究对象,利用免疫共沉淀(Co-IP)和液相色谱-串联质谱(LC⁃MS/MS)技术筛选出可能与IBV Nsp2蛋白发生互作的宿主蛋白eIF2α,通过免疫共沉淀和间接免疫荧光试验进一步验证二者相互作用。【结果】经免疫共沉淀与质谱分析后筛选到97个可能与Nsp2蛋白互作的宿主蛋白,其中宿主抗病毒反应的关键蛋白eIF2α与Nsp2蛋白的相互作用通过免疫共沉淀和间接免疫荧光试验,表明二者存在直接互作关系,并共定位于细胞质中;此外,Nsp2蛋白表达和IBV感染都能显著提高宿主内源性eIF2α的转录水平。【结论】利用免疫共沉淀联合质谱技术筛选到CEK细胞中存在的97种可能与IBV Nsp2互作的候选蛋白,利用免疫共沉淀与间接免疫荧光证明候选蛋白eIF2α与Nsp2蛋白在细胞质中存在直接互作,同时发现Nsp2蛋白过表达和IBV感染会导致CEK细胞内eIF2α的转录水平显著增强。本研究为进一步探索冠状病毒非结构蛋白Nsp2的生物学功能奠定了基础,并提供了IBV入侵宿主时Nsp2蛋白的作用机制研究的新线索。     

猪δ冠状病毒核衣壳蛋白互作的蛋白鉴定及分析

初步筛选与鉴定PDCoV N蛋白的宿主互作蛋白.利用免疫共沉淀(Co-immunoprecipitation,CO-IP)和LC-MS/MS质谱技术筛选出PDCoVN蛋白的宿主互作蛋白,并进行生物信息学分析,再利用免疫共沉淀进行鉴定.通过免疫共沉淀产物的SDS-PAGE分析发现在40 kD和100 kD左右有明显的差异蛋白条带,通过质谱筛选到了68个与PDCoVN蛋白互作的宿主蛋白,并做了GO、COG和KEGG注释,挑选出2个候选互作蛋白,经过免疫共沉淀验证,PDCoVN蛋白与TUBB2B存在互作关系.该研究为进一步探索PDCoV N蛋白在病毒感染细胞时的作用提供了新方向.     

非洲猪瘟病毒D1133L蛋白增加宿主波形蛋白磷酸化而促进病毒在猪巨噬细胞中的复制

非洲猪瘟(African swine fever, ASF)是由非洲猪瘟病毒(African swine fever virus, ASFV)感染引起家猪和野猪的一种高死亡率的传染性疾病。ASFV具有庞大的基因组,其中非结构蛋白pD1133L被预测为其编码的6个解旋酶之一。本实验室应用免疫沉淀-质谱联用(immunoprecipitation-mass spectrometry, IP-MASS)技术筛选与pD1133L互作的宿主细胞蛋白,发现细胞波形蛋白(vimentin, VIM)为pD1133L互作的宿主蛋白之一,但尚不清楚宿主蛋白VIM对ASFV复制的影响。【目的】探究ASFV与VIM的相互调控作用,揭示VIM促进ASFV复制的机制。【方法】通过免疫共沉淀(co-immunoprecipitation, Co-IP)试验验证pD1133L与VIM存在互作关系;外源过表达VIM蛋白以及设计并合成VIM的siRNA探究VIM对ASFV复制的影响;利用Western blotting以及荧光定量PCR (quantitative real-time PCR, qPCR)方法检测ASFV对VIM蛋白水平以及转录水平的影响;通过Western blotting、间接免疫荧光试验(immunofluorescence assay, IFA)探究巨噬细胞感染ASFV后VIM磷酸化水平变化以及亚细胞定位变化情况;CCK-8试剂盒检测VIM磷酸化抑制剂KN-93处理的最佳浓度,并利用Western blotting以及IFA检测KN-93对VIM磷酸化、亚细胞定位以及对ASFV复制影响。【结果】VIM过表达促进ASFV复制,敲低VIM的表达则抑制ASFV复制;ASFV感染抑制VIM蛋白水平以及转录水平表达,且呈时间依赖性;ASFV感染后VIM发生磷酸化修饰且发生亚细胞定位改变,从而促进ASFV复制。【结论】证实了ASFV与宿主蛋白VIM之间的相互调控作用;初步确定ASFV感染后VIM受到ASFV pD1133L调控,亚细胞定位发生重排向核周聚集从而促进ASFV复制的机制。     

免疫共沉淀筛选细胞内与A型流感病毒M2蛋白相互作用的蛋白

摘要：【目的】筛选细胞内与A型流感病毒M2蛋白（A/M2）相互作用的蛋白质。【方法】将A/M2编码序列插入真核表达载体pCAGGS-CFlag,重组质粒pCAGGS-CFlag-A/M2转染HEK-293T细胞,裂解细胞,以Flag单抗偶联的琼脂糖球珠免疫沉淀A/M2-Flag蛋白,清洗去除非特异性结合的杂蛋白后,SDS-PAGE银染法显示与A/M2共沉淀的蛋白,从胶上切下此蛋白条带进行质谱分析。【结果】成功构建了A/M2的表达质粒,免疫印迹证实了A/M2蛋白在293T细胞中能够表达,免疫共沉淀筛选到与A/M2结合的多种蛋白,分析质谱结果,确定ataxin 10和3个真核翻译起始因子(eIF)为候选蛋白。【结论】ataxin 10与A/M2相互作用为流感病毒感染或接种流感疫苗引发小脑性共济失调提供了解释,eIF与A/M2相互作用表明A/M2可能在调控病毒蛋白合成方面起重要作用。     

miR-34b调控肠道病毒71型在人横纹肌肉瘤细胞中的复制及机制

【背景】研究发现microRNAs(miRNAs)可以参与调控病毒在宿主细胞内感染和复制的过程。【目的】研究miR-34b对肠道病毒71型(Enterovirus71,EV71)在宿主细胞内的复制及其可能机制。【方法】在人横纹肌肉瘤(Rhabdomyosarcoma,RD)细胞中转染miR-34b mimics和Inhibitor,通过Western blot和Real-time PCR实验检验EV71病毒的复制和表达情况。随后利用双荧光素酶报告系统验证miR-34b与潜在靶点eIF4E的相互作用,并检测miR-34b对RD细胞中eIF4E mRNA表达水平的影响。【结果】miR-34b可以促进病毒在RD细胞中的复制和表达,而miR-34b抑制剂有抑制病毒复制的作用,细胞内miR-34b可以通过作用于靶基因eIF4E调控EV71在宿主细胞中的复制过程。【结论】揭示了miR-34b在EV71病毒复制过程中的调控作用及机制,研究EV71病毒与宿主miRNAs的相互作用机制为进一步阐明EV71病毒感染与复制机理奠定了基础。     

猪流行性腹泻病毒nsp1蛋白对Ⅰ型干扰素应答的影响

猪流行性腹泻病毒 (PEDV) 能抑制宿主Ⅰ型干扰素及其诱导的细胞抗病毒免疫应答,但是PEDV抑制Ⅰ型干扰素应答的分子机制尚不明了,尤其是PEDV非结构蛋白 (Nonstructural proteins,nsps) 在Ⅰ型干扰素应答中的调控作用研究不多。为研究PEDV非结构蛋白1 (nsp1) 对细胞Ⅰ型干扰素应答的影响,构建了真核表达载体pCAGGS-nsp1,采用Western blotting和间接免疫荧光试验确定nsp1在细胞中的表达。通过报告基因法、ELISA以及病毒复制抑制试验评估nsp1对Ⅰ型IFN的影响。结果显示,nsp1在转染细胞和病毒感染细胞中均高效表达;双荧光报告基因试验结果表明,nsp1能显著抑制IFN-β启动子活性,且具有剂量依赖性。ELISA结果显示,nsp1能显著抑制IFN-β蛋白的表达。水泡性口炎病毒 (VSV) 复制抑制试验结果显示,nsp1明显抑制poly(I:C)介导的Ⅰ型IFN的抗病毒作用。结果提示,nsp1作为PEDV的保守蛋白,具有拮抗Ⅰ型干扰素启动子活性和应答的功能,为揭示PEDV逃逸宿主天然免疫应答的机制和研发新型高效抗PEDV疫苗奠定基础。     

SARS冠状病毒中的核衣壳蛋白

严重急性呼吸综合征(SARS)的元凶是一种新冠状病毒,研究病毒结构蛋白的功能有助于了解病毒的感染、复制和包装等生理过程。其中核衣壳蛋白是SARS冠状病毒中含量最丰富和最保守的结构蛋白,自身聚合后包被病毒RNA基因组形成螺旋状核壳体是SARS冠状病毒成熟的关键步骤;核衣壳蛋白能与病毒或宿主细胞中多种蛋白质相互作用,还能影响宿主细胞的多个通路。因此核衣壳蛋白是一个重要的多功能蛋白质,参与了病毒感染、复制和病毒包装等过程。     

Highly Divergent Strains of Porcine Reproductive and Respiratory Syndrome Virus Incorporate Multiple Isoforms of Nonstructural Protein 2 into Virions

Viral structural proteins form the critical intermediary between viral infection cycles within and between hosts, function to initiate entry, participate in immediate early viral replication steps, and are major targets for the host adaptive immune response. We report the identification of nonstructural protein 2 (nsp2) as a novel structural component of the porcine reproductive and respiratory syndrome virus (PRRSV) particle. A set of custom α-nsp2 antibodies targeting conserved epitopes within four distinct regions of nsp2 (the PLP2 protease domain [OTU], the hypervariable domain [HV], the putative transmembrane domain [TM], and the C-terminal region [C]) were obtained commercially and validated in PRRSV-infected cells. Highly purified cell-free virions of several PRRSV strains were isolated through multiple rounds of differential density gradient centrifugation and analyzed by immunoelectron microscopy (IEM) and Western blot assays using the α-nsp2 antibodies. Purified viral preparations were found to contain pleomorphic, predominantly spherical virions of uniform size (57.9 nm ± 8.1 nm diameter; n = 50), consistent with the expected size of PRRSV particles. Analysis by IEM indicated the presence of nsp2 associated with the viral particle of diverse strains of PRRSV. Western blot analysis confirmed the presence of nsp2 in purified viral samples and revealed that multiple nsp2 isoforms were associated with the virion. Finally, a recombinant PRRSV genome containing a myc-tagged nsp2 was used to generate purified virus, and these particles were also shown to harbor myc-tagged nsp2 isoforms. Together, these data identify nsp2 as a virion-associated structural PRRSV protein and reveal that nsp2 exists in or on viral particles as multiple isoforms.     

Identification of nonessential regions of the nsp2 replicase protein of porcine reproductive and respiratory syndrome virus strain VR-2332 for replication in cell culture

The nonstructural protein 2 (nsp2) of porcine reproductive and respiratory syndrome virus (PRRSV) is a multidomain protein and has been shown to undergo remarkable genetic variation, primarily in its middle region, while exhibiting high conservation in the N-terminal putative protease domain and the C-terminal predicted transmembrane region. A reverse genetics system of PRRSV North American prototype VR-2332 was developed to explore the importance of different regions of nsp2 for viral replication. A series of mutants with in-frame deletions in the nsp2 coding region were engineered, and infectious viruses were subsequently recovered from transfected cells and further characterized. The results demonstrated that the cysteine protease domain (PL2), the PL2 downstream flanking sequence (amino acids [aa] 181 to 323), and the putative transmembrane domain were critical for replication. In contrast, the segment of nsp2 preceding the PL2 domain (aa 13 to 35) was dispensable for viral replication, and the nsp2 middle hypervariable region (aa 324 to 813) tolerated 100-aa or 200-aa deletions but could not be removed as a whole; the largest deletion was about 400 aa (nsp2Delta324-726). Characterization of the mutants demonstrated that those with small deletions possessed growth kinetics and RNA expression profiles similar to those of the parental virus, while the nsp2Delta324-726 mutant displayed decreased cytolytic activity on MARC-145 cells and did not develop visible plaques. Finally, the utilization of the genetic flexibility of nsp2 to express foreign genes was examined by inserting the gene encoding green fluorescent protein (GFP) in frame into one nsp2 deletion mutant construct. The recombinant virus was viable but impaired and unstable and gradually gained parental growth kinetics by the loss of most of the GFP gene.     

Severe Acute Respiratory Syndrome Coronavirus nsp1 Facilitates Efficient Propagation in Cells through a Specific Translational Shutoff of Host mRNA

Severe acute respiratory syndrome (SARS) coronavirus (SCoV) is an enveloped virus containing a single-stranded, positive-sense RNA genome. Nine mRNAs carrying a set of common 5' and 3' untranslated regions (UTR) are synthesized from the incoming viral genomic RNA in cells infected with SCoV. A nonstructural SCoV nsp1 protein causes a severe translational shutoff by binding to the 40S ribosomal subunits. The nsp1-40S ribosome complex further induces an endonucleolytic cleavage near the 5'UTR of host mRNA. However, the mechanism by which SCoV viral proteins are efficiently produced in infected cells in which host protein synthesis is impaired by nsp1 is unknown. In this study, we investigated the role of the viral UTRs in evasion of the nsp1-mediated shutoff. Luciferase activities were significantly suppressed in cells expressing nsp1 together with the mRNA carrying a luciferase gene, while nsp1 failed to suppress luciferase activities of the mRNA flanked by the 5'UTR of SCoV. An RNA-protein binding assay and RNA decay assay revealed that nsp1 bound to stem-loop 1 (SL1) in the 5'UTR of SCoV RNA and that the specific interaction with nsp1 stabilized the mRNA carrying SL1. Furthermore, experiments using an SCoV replicon system showed that the specific interaction enhanced the SCoV replication. The specific interaction of nsp1 with SL1 is an important strategy to facilitate efficient viral gene expression in infected cells, in which nsp1 suppresses host gene expression. Our data indicate a novel mechanism of viral gene expression control by nsp1 and give new insight into understanding the pathogenesis of SARS.     

Proteomics analysis unravels the functional repertoire of coronavirus nonstructural protein 3

Severe acute respiratory syndrome (SARS) coronavirus infection and growth are dependent on initiating signaling and enzyme actions upon viral entry into the host cell. Proteins packaged during virus assembly may subsequently form the first line of attack and host manipulation upon infection. A complete characterization of virion components is therefore important to understanding the dynamics of early stages of infection. Mass spectrometry and kinase profiling techniques identified nearly 200 incorporated host and viral proteins. We used published interaction data to identify hubs of connectivity with potential significance for virion formation. Surprisingly, the hub with the most potential connections was not the viral M protein but the nonstructural protein 3 (nsp3), which is one of the novel virion components identified by mass spectrometry. Based on new experimental data and a bioinformatics analysis across the Coronaviridae, we propose a higher-resolution functional domain architecture for nsp3 that determines the interaction capacity of this protein. Using recombinant protein domains expressed in Escherichia coli, we identified two additional RNA-binding domains of nsp3. One of these domains is located within the previously described SARS-unique domain, and there is a nucleic acid chaperone-like domain located immediately downstream of the papain-like proteinase domain. We also identified a novel cysteine-coordinated metal ion-binding domain. Analyses of interdomain interactions and provisional functional annotation of the remaining, so-far-uncharacterized domains are presented. Overall, the ensemble of data surveyed here paint a more complete picture of nsp3 as a conserved component of the viral protein processing machinery, which is intimately associated with viral RNA in its role as a virion component.     

Heat Shock Protein 72 Is Associated with the Hepatitis C Virus Replicase Complex and Enhances Viral RNA Replication

The NS5A protein of the hepatitis C virus (HCV) is an integral component of the viral replicase. It also modulates cellular signaling and perturbs host interferon responses. The multifunctional characteristics of NS5A are mostly attributed to its ability to interact with various cellular proteins. This study aimed to identify the novel cellular factors that interact with NS5A and decipher the significance of this interaction in viral replication. The NS5A-interacting proteins were purified by the tandem affinity purification (TAP) procedure from cells expressing NS5A and identified by mass spectrometry. The chaperone protein Hsp72 was identified herein. In vivo protein-protein interaction was verified by co-immunoprecipitation and an in situ proximity ligation assay. In addition to NS5A, Hsp72 was also associated with other members of the replicase complex, NS3 and NS5B, suggesting that it might be directly involved in the HCV replication complex. Hsp72 plays a positive regulatory role in HCV RNA replication by increasing levels of the replicase complex, which was attributed either to the increased stability of the viral proteins in the replicase complex or to the enhanced translational activity of the internal ribosome entry site of HCV. The fact that the host chaperone protein Hsp72 is involved in HCV RNA replication may represent a therapeutic target for controlling virus production.     

A swine arterivirus deubiquitinase stabilizes two major envelope proteins and promotes production of viral progeny

Arteriviruses are enveloped positive-strand RNA viruses that assemble and egress using the host cell’s exocytic pathway. In previous studies, we demonstrated that most arteriviruses use a unique -2 ribosomal frameshifting mechanism to produce a C-terminally modified variant of their nonstructural protein 2 (nsp2). Like full-length nsp2, the N-terminal domain of this frameshift product, nsp2TF, contains a papain-like protease (PLP2) that has deubiquitinating (DUB) activity, in addition to its role in proteolytic processing of replicase polyproteins. In cells infected with porcine reproductive and respiratory syndrome virus (PRRSV), nsp2TF localizes to compartments of the exocytic pathway, specifically endoplasmic reticulum-Golgi intermediate compartment (ERGIC) and Golgi complex. Here, we show that nsp2TF interacts with the two major viral envelope proteins, the GP5 glycoprotein and membrane (M) protein, which drive the key process of arterivirus assembly and budding. The PRRSV GP5 and M proteins were found to be poly-ubiquitinated, both in an expression system and in cells infected with an nsp2TF-deficient mutant virus. In contrast, ubiquitinated GP5 and M proteins did not accumulate in cells infected with the wild-type, nsp2TF-expressing virus. Further analysis implicated the DUB activity of the nsp2TF PLP2 domain in deconjugation of ubiquitin from GP5/M proteins, thus antagonizing proteasomal degradation of these key viral structural proteins. Our findings suggest that nsp2TF is targeted to the exocytic pathway to reduce proteasome-driven turnover of GP5/M proteins, thus promoting the formation of GP5-M dimers that are critical for arterivirus assembly.