细小病毒非结构蛋白诱导细胞凋亡研究进展

迄今,据最新报道可感染哺乳动物和禽类的细小病毒有17余种。被感染细胞常出现不同程度的凋亡和坏死,呈现典型以细胞折光性增强、圆缩直至溶解脱落等为特征的细胞病变。NS1蛋白是细小病毒主要的非结构蛋白,其结构和功能保守,在病毒生命周期与感染宿主中扮演重要角色。它不仅影响病毒复制,还参与诱导宿主细胞凋亡。细小病毒NS1蛋白主要经由线粒体途径诱导被感染宿主细胞发生凋亡,本文全面归纳与总结细小病毒NS1蛋白诱导细胞凋亡的分子机制的最新研究进展。     

猪细小病毒NS1蛋白主要抗原表位区的原核表达

目的：用大肠杆菌表达猪细小病毒NS1基因的主要抗原表位区。方法：通过对GenBank发表的猪细小病毒（Porcine Par-vovirus,PPV）中国株非结构蛋白NS1的氨基酸序列分析,确定了其中抗原性较高的区域,针对此区域设计并合成了一对特异性引物,扩增出包含NS1主要抗原表位区的843bp的片段。酶切后连接到原核表达载体pET30a（＋）上,构建的原核表达载体pET30a-NS1s转化大肠杆菌BL21（DE3）感受态细胞,诱导表达。结果：重组蛋白大小约为43kD,与预期大小相符。Westernblot分析表明,该蛋白能与标准阳性血清发生特异性反应,证明该蛋白具有生物学活性。结论：NS1蛋白主要抗原表位区在大肠杆菌中成功表达,具有免疫原性。可作为鉴别诊断抗原用于PPV的临床检测。     

猪细小病毒NS1基因的原核表达及重组蛋白的复性

利用PCR技术扩增出PPVNS1基因抗原区。将目的基因与原核表达载体pGEX-4T-1进行连接并转化,重组质粒经鉴定并测序。测序结果表明,目的基因插入的位置、大小和读码框均正确,通过试验摸索并确定了表达NS1基因的最佳诱导条件:IPTG终浓度为1.0mmol/L,诱导时间为10h,温度为37℃,其表达量占全菌蛋白的29.8%。表达产物经SDS-PAGE分析,得到分子量约为52kDa的重组蛋白且以包涵体形式存在。重组蛋白经Westernblot检测,结果证明重组蛋白可被PPV阳性血清识别。用8mol/L尿素变性溶解包涵体,再用稀释方法和还原型、氧化型谷胱甘肽系统相结合的方法对重组蛋白进行复性。ELISA检测表明,复性后的重组蛋白有良好的生物活性。     

禽流感病毒NS1蛋白对细胞的影响

NS1蛋白为流感病毒非结构蛋白,只在病毒侵入宿主细胞后产生.目前NS1蛋白对细胞整体水平上的作用仍不清楚,为了解NS1蛋白在病毒感染细胞中的作用,构建了重组质粒pCMV-myc-NS1并将其转染A549细胞,利用双向电泳技术检测了受NS1蛋白调控的宿主蛋白,以期从蛋白质组水平上研究禽流感病毒与宿主细胞间的相互作用.同时,还检测了转染NS1对细胞增殖和细胞周期的影响.结果显示,NS1在细胞中的表达,能够明显引起宿主细胞代谢的变化,并通过阻滞细胞周期的正常进行而减缓细胞的增殖.     

一种可诱导细胞凋亡的鸡贫血病毒蛋白

鸡贫血病毒（ＣＡＶ）是一种全球性的禽传染病的病原。为环状单链ＤＮＡ,大小为２．３ｋｂ,是圆环病毒科的成员。ＣＡＶ基因组包含了３个部分或完全重叠的基因。ＣＡＶ可通过细胞凋亡使胸腺细胞及人工培养的转化型单核细胞产生致命的细胞病变（ＣＰＥ）。在转化的（鸡）细胞中,ＶＰ３基因的编码产物凋亡素可以造成凋亡,而这种效应不依赖于ｐ５３,且不受凋亡抑制蛋白Ｂｃｌ－２及ＣｒｍＡ的抑制。令人注目的是,凋亡素能使人肿瘤     

猪细小病毒SD-68株NS1基因的克隆与序列分析

对猪细小病毒(PPV)SD-68株NS1基因进行了克隆和序列测定,结果表明SD-68株NS1基因全长1989bp,编码662个氨基酸组成的多肽.该序列与PPV SY-99株、Kresse株、NADL-2(5075)和NADL-2(4973)株的NS1基因比较,核苷酸的同源性分别为99.9%、99.9%、99.7%、98.1%,氨基酸的同源性分别为99.7%、99.5%、99.5%、96.7%.PPV SD-68株与MVM(i)、MEV(Abashiri)、CPV、FPV、BPV3、GPV NS1的进化树分析表明PPV SD-68株NS1与MVM(i)NS1亲缘关系最近,与BPV3 NS1的亲缘关系最远;在Thr435和Ser473位点PPV SD-68株与MVM(i)完全一致,表明Thr435和Ser473是PPV SD-68株NS1潜在的磷酸化位点.     

细小病毒非结构蛋白转基因小鼠模型建立

将小鼠乳腺癌病毒启动子控制的细小病毒非结构蛋白基因(长5.7kb)氯化铯超速离心,纯化透析后用显微注射法导入C57BL/SJL F_1小鼠受精卵雄核,植入假孕母鼠输卵管,得成活小鼠15只。抽取鼠尾DNA,对其中10只小鼠作PCR和southern blot鉴定,其中4只(40％)整合有目的基因。对首建者B_6()的8只子代小鼠鉴定,3只(37.5％)整合有目的基因。说明导入的目的基因能传代。     

H5N1亚型禽流感病毒NS1基因的克隆及其诱导肺腺癌细胞A549凋亡的研究

通过RT-PCR的方法克隆H5N1亚型禽流感病毒NS1基因,并构建了真核表达载体pCMV-Myc/NS1。将此真核表达质粒转染肺腺癌细胞A549,48 h后,经Western印迹检测,NS1基因能在细胞中正确表达。经荧光显微镜、透射电镜观察和流式细胞仪检测,发现该株流感病毒的NS1蛋白可诱导肺腺癌细胞A549凋亡。     

犬细小病毒诊断与防制研究进展

犬细小病毒是严重危害野生动物驯养繁殖产业的重要病毒性传染病之一,具有感染高、发病急、病程短和死亡率高等特点,且随着病毒的不断变异,其宿主范围不断扩大,除感染狐狸、犬、狼等犬科动物外,还能感染猫、豹、熊、虎和果子狸等其它多种动物,对我国的野生动物保护、驯养繁殖和疫源疫病监测工作的影响越来越大。本文对犬细小病毒的诊断及其防制进行了概述,以期为野生动物感染犬细小病毒的防控提供科学依据。     

犬CTLA-4胞外区的分子克隆、表达和对犬细小病毒VP2的免疫佐剂作用

[目的]探索犬细胞毒性T细胞相关抗原-4(cytotoxic T lymphocyte-associated antigen-4,CTLA-4)胞外区作为免疫佐剂的可行性.[方法]根据已发表序列设计引物,用RT-PCR扩增CTLA-4胞外区编码序列,用PCR扩增犬细小病毒(canine parvovirus,CPV)VP2蛋白主要抗原表位基因片段VP2S,将VP2S克隆入含和不含CTLA-4胞外区基因片段的原核表达质粒pQE-31;用获得的重组质粒pQE-CTLA-4-VP2S和pQE-VP2S转化大肠杆菌,并进行诱导表达;用相同剂量的重组蛋白VP2S和CTLA-4-VP2S免疫小鼠.用间接ELISA和血凝抑制试验比较两个免疫组的抗体水平.[结果]经过30次循环PCR扩增后,琼脂糖凝胶电泳显示预期大小的扩增产物;序列测定结果显示,克隆的毕格犬CTLA-4胞外区与已发表序列的核苷酸同源性为99.2%,氨基酸序列同源性为98.4%,结合B7分子的六肽基序(MYPPPY)无变化:VP2S与已发表CPV VP2的核苷酸序列同源性为99%,氨基酸序列同源性为98.6%:经IPTG诱导后,两种重组大肠杆菌表达预期的29kDa VP2S和42kDaCTLA-4-VP2S重组蛋白,两者均能被CPV抗血清识别;间接ELISA和血凝抑制试验结果显示,CTLA-4-VP2S免疫组的抗体产生时间为初免后第2周,抗体高峰期为初免后第4周,而VP2S免疫组的抗体产生时间为初免后第4周,抗体高峰期为初免后第5周,两个试验组高峰期ELISA抗体效价和血凝抑制抗体效价分别相差100倍和10倍.[结论]犬CTLA-4胞外区可作为分子佐剂促进CPV VP2蛋白抗体的产生.     

基于非结构蛋白1(NS1)的黄病毒感染诊断研究进展

蚊虫传播的黄病毒造成的传染病是人类健康的重要威胁,有效的早期精确诊断对预防与控制黄病毒感染并及时有效开展病患救治至关重要。然而由于黄病毒在血液中核酸可检测窗口短,核酸检测手段难以发挥优势,必须要通过血清学的诊断与病毒分离予以佐证,而血清学检测也要面对黄病毒之间存在的交叉反应问题。本文介绍了基于黄病毒非结构蛋白1(NS1)建立的检测手段。NS1蛋白在病人血清中含量很高是良好早期诊断靶标,基于NS1蛋白的黄病毒血清学诊断的检测窗口较长、灵敏度高、特异性强,具有独特的优势。尤其是2016年寨卡病毒暴发以来基于NS1的检测技术在灵敏度与特异性上得到快速与多元的发展,为黄病毒的精确检测带开启了新的局面。     

A型流感病毒NS1蛋白研究进展

NS1蛋白是A型流感病毒的唯一的非结构蛋白,是一种RNA结合蛋白,具有重要的调节活性。NS1蛋白仅存在于病毒感染的细胞内,且在感染的早期,大量存在于细胞核中,而在感染的晚期,也可出现于细胞浆中。NS1蛋白具有RNA结合区和效应区,在抑制宿主细胞蛋白质的合成、诱导细胞凋亡和拮抗干扰素α/β的产生等方面具有重要的作用。另外,NS1蛋白在野毒感染的鉴别诊断、外源基因的载体及抗病毒药物的设计等方面,均显示了良好的应用价值。     

犬细小病毒VP2蛋白在真核细胞中的分泌表达及特性

摘要:【目的】利用真核细胞分泌表达犬细小病毒VP2蛋白和研究其特性。【方法】为构建犬细小病毒（Canine parvovirus, CPV）VP2基因的真核分泌型表达载体,首先通过酶切从含有人CD5信号肽序列的质粒中将CD5信号肽基因片段切出,将其连接到真核表达载体pcDNA3.1A的多克隆位点上,构建成pcDNA3.1-CD5sp质粒。然后再通过PCR方法从含有犬细小病毒VP2基因的质粒中扩增VP2基因,并将其插入到pcDNA3.1- CD5sp载体中CD5信号肽的下游,构建成VP2基因的真核分泌型表达载体pcDNA-CD5sp-VP2。经磷酸钙介导转染293T细胞,使其在真核细胞中进行分泌表达,并通过ELISA检测表达的VP2蛋白与犬转铁蛋白受体（TfR）结合的活性。【结果】序列分析结果表明,本实验构建的犬细小病毒VP2基因真核分泌型表达载体结构正确,将该表达载体转染的293T细胞,在培养基中通过Western-blot检测到有VP2重组蛋白的存在。经ELISA检测表明表达的重组VP2蛋白具有与犬转铁蛋白受体结合的活性。【结论】 利用人的CD5信号肽实现了犬细小病毒VP2蛋白在真核细胞中的分泌表达,表达的VP2蛋白具有与犬转铁蛋白受体结合的活性。     

猪细小病毒NS1基因的克隆与序列分析

目的:扩增猪细小病毒(Porcine Parvovinls,PPV)LJL12株NS1基因的全长序列,并进行同源性分析.方法:参考GenBank上公布的PPV中国株NS1基因序列,设计一对特异性引物增LJL12株NS1基因,测定序列,使用分子生物学软件进行同源性分析.结果:LJL12 株 NS1 基因伍长 1989bp,编码 662个氨基酸.与其他 PPV 中国株 NS1 的核苷酸同源性在 98.6%～100%之间,氨基酸同源性在98.5%～100%之间.其中,与南京株的同源性最高.结论:PPV NS1 蛋白具有高度保守性,适合用作诊断抗原.LJL12 株PPV NS1 基因的克隆,为进一步研究 NS1 的功能和作用奠定了基础.     

NS1-binding protein abrogates the elevation of cell viability by the influenza A virus NS1 protein in association with CRKL

The influenza A virus non-structural protein 1 (NS1) is a multifunctional virulence factor consisting of an RNA binding domain and several Src-homology (SH) 2 and SH3 binding motifs, which promotes virus replication in the host cell and helps to evade antiviral immunity. NS1 modulates general host cell physiology in association with various cellular molecules including NS1-binding protein (NS1-BP) and signaling adapter protein CRK-like (CRKL), while the physiological role of NS1-BP during influenza A virus infection especially in association with NS1 remains unclear. In this study, we analyzed the intracellular association of NS1-BP, NS1 and CRKL to elucidate the physiological roles of these molecules in the host cell. In HEK293T cells, enforced expression of NS1 of A/Beijing (H1N1) and A/Indonesia (H5N1) significantly induced excessive phosphorylation of ERK and elevated cell viability, while the over-expression of NS1-BP and the abrogation of CRKL using siRNA abolished such survival effect of NS1. The pull-down assay using GST-fusion CRKL revealed the formation of intracellular complexes of NS1-BP, NS1 and CRKL. In addition, we identified that the N-terminus SH3 domain of CRKL was essential for binding to NS1-BP using GST-fusion CRKL-truncate mutants. This is the first report to elucidate the novel function of NS1-BP collaborating with viral protein NS1 in modulation of host cell physiology. In addition, an alternative role of adaptor protein CRKL in association with NS1 and NS1-BP during influenza A virus infection is demonstrated.     

Influenza A virus NS1 protein‐induced JNK activation and apoptosis are not functionally linked

Expression of the influenza A virus (IAV) nonstructural protein (NS1) results in the activation of c‐Jun N‐terminal kinase (JNK). Both NS1 and JNK are involved in apoptosis induction. To investigate their interrelationship, we stably expressed a tamoxifen inducible NS1 oestrogen receptor fusion‐protein (NS1ERT) in mammalian cells. Upon tamoxifen stimulation, NS1ERT‐expressing cells partially rescued the attenuated replication of NS1‐deficient IAVs and also inhibited interferon up‐regulation, confirming the functional competence of NS1ERT. Tamoxifen‐induced NS1ERT created a cytopathic phenotype and led to the activation of JNK and apoptosis. Induction of NS1F103SERT mutant failed to activate JNK, but induced apoptosis, whereas the induction of NS1M106IERT led to JNK phosphorylation, but not apoptosis, indicating that JNK activation and apoptosis induction are not functionally linked. Further mutational analysis highlighted that apoptosis induction is a function of the C‐terminal effector domain of NS1. Finally, IAVs encoding mutant NS1 revealed a modulating effect of NS1 on apoptosis induction in a genuine infection. With respect to apoptogenicity, an NS1 mutant virus that results in a super activation of JNK behaves similarly to the JNK nonactivating virus expressing NS1F103S, thus confirming that NS1‐mediated JNK activation and apoptosis induction are also functionally independent from each other in vivo.     

Expression and subcellular targeting of canine parvovirus capsid proteins in baculovirus-transduced NLFK cells

A mammalian baculovirus delivery system was developed to study targeting in Norden Laboratories feline kidney (NLFK) cells of the capsid proteins of canine parvovirus (CPV), VP1 and VP2, or corresponding counterparts fused to EGFP. VP1 and VP2, when expressed alone, both had equal nuclear and cytoplasmic distribution. However, assembled form of VP2 had a predominantly cytoplasmic localization. When VP1 and VP2 were simultaneously present in cells, their nuclear localization increased. Thus, confocal immunofluorescence analysis of cells transduced with the different baculovirus constructs or combinations thereof in the absence or presence of infecting CPV revealed that the VP1 protein is a prerequisite for efficient targeting of VP2 to the nucleus. The baculovirus vectors were functional and the genes of interest efficiently introduced to this CPV susceptible mammalian cell line. Thus, we show evidence that the system could be utilized to study targeting of the CPV capsid proteins.     

Hepatitis C virus NS5A protein interacts with lysine methyltransferase SET and MYND domain‐containing 3 and induces activator protein 1 activation

Hepatitis C virus (HCV) non‐structural protein 5A (NS5A) is a multifunctional protein that is involved in the HCV life cycle and pathogenesis. In this study, a host protein(s) interacting with NS5A by tandem affinity purification were searched for with the aim of elucidating the role of NS5A. An NS5A‐interacting protein, SET and MYND domain‐containing 3 (SMYD3), a lysine methyltransferase reportedly involved in the development of cancer, was identified. The interaction between NS5A and SMYD3 was confirmed in ectopically expressing, HCV RNA replicon‐harboring and HCV‐infected cells. The other HCV proteins did not bind to SMYD3. SMYD3 bound to NS5A of HCV genotypes 1b and 2a. Deletion mutational analysis revealed that domains II and III of NS5A (amino acids [aa] 250 to 447) and the MYND and N‐SET domains of SMYD3 (aa 1 to 87) are involved in the full extent of NS5A‐SMYD3 interaction. NS5A co‐localized with SMYD3 exclusively in the cytoplasm, thereby inhibiting nuclear localization of SMYD3. Moreover, NS5A formed a complex with SMYD3 and heat shock protein 90 (HSP90), which is a positive regulator of SMYD3. The intensity of binding between SMYD3 and HSP90 was enhanced by NS5A. Luciferase reporter assay demonstrated that NS5A significantly induces activator protein 1 (AP‐1) activity, this being potentiated by co‐expression of SMYD3 with NS5A. Taken together, the present results suggest that NS5A interacts with SMYD3 and induces AP‐1 activation, possibly by facilitating binding between HSP90 and SMYD3. This may be a novel mechanism of AP‐1 activation in HCV‐infected cells.