携带人NFBD1基因shRNA重组逆转录病毒载体的构建及鉴定

建立逆转录病毒介导的NFBD1基因RNA干扰表达体系,并观察其在宫颈癌SiHa细胞中对NFBD1表达的影响.将人NFBD1基因RNA干扰双链DNA片段重组到pSUPER Retro质粒中,构建携带人NFBD1基因RNA干扰的逆转录病毒载体pSUPER-shRNA-NFBD1,经PT67细胞包装后,产生的重组逆转录病毒感染宫颈癌细胞株SiHa细胞,并用嘌呤霉素筛选产生稳定的细胞克隆,用实时荧光定量PCR和Westernblotting检测细胞中NFBD1 mRNA和蛋白表达的变化.重组逆转录病毒质粒经测序鉴定正确;逆转录病毒感染SiHa细胞后用嘌呤霉素筛选出稳定的细胞克隆;实时荧光定量PCR和Westernblotting检测人NFBD1 mRNA和蛋白表达水平明显低于阴性对照组和未干扰组.携带人NFBD1基因RNA干扰双链DNA片段的逆转录病毒感染SiHa细胞后能明显抑制NFBD1 mRNA和蛋白表达,为进一步研究NFBD1在宫颈癌中的作用奠定了基础.     

Mx基因稀有密码子和mRNA结构及大肠杆菌表达 优化

通过对稀有密码子和mRNA翻译起始区二级结构的分析, 构建了4种重组表达菌株BL21(DE3)/pET-Mx, Rosseta(DE3)/pET-Mx, BL21(DE3)/pGEX-Mx和Rosseta(DE3)/pGEX-Mx, 在大肠杆菌中进行Mx基因的表达, Rosseta(DE3)/pET-Mx和Rosseta(DE3)/pGEX-Mx重组表达菌中都获得了表达, Western blotting检测到了特异的75 kDa表达产物。实验结果证明稀有密码子和mRNA翻译起始区二级结构对Mx 蛋白表达都有影响, 选择适用于稀有密码子表达的菌株Rosetta(DE3)有利于Mx蛋白的表达, 同时翻译起始区二级结构能值较低的表达载体pGEX-Mx获得的表达量明显增高。实验中首次获得了重组表达鸡全长Mx蛋白的大肠杆菌重组菌。     

用pLNCX2携带人MCPH1基因shRNA重组逆转录病毒载体的构建及鉴定

目的建立逆转录病毒介导的MCPH1基因RNA干扰表达体系并观察其在宫颈癌Caski细胞中对MCPH1表达的影响。方法将人MCPH1基因RNA干扰双链DNA片段重组到逆转录病毒质粒pLNCX2中,构建携带人MCPHI基因RNA干扰的逆转录病毒载体pLNCX2-shRNA—MCPH1,经PT67细胞包装后,产生的重组逆转录病毒感染宫颈癌细胞株Caski细胞,并用G418筛选产生稳定的细胞克隆,用RT—PCR和Western印迹检测细胞中MCPH1mRNA和蛋白表达的变化。结果重组逆转录病毒质粒经测序鉴定正确,逆转录病毒感染Caski细胞后用G418筛选出稳定的细胞克隆,RT—PCR和Western印迹检测人MCPH1mRNA和蛋白表达水平明显低于阴性对照组和未干扰组。结论携带人MCPHI基因RNA干扰双链DNA片段的逆转录病毒感染Caski细胞后能明显抑制MCPHImRNA和蛋白表达,为进一步研究MCPH1在宫颈癌中的作用奠定了基础。     

鸡Mx蛋白基因诱变修饰及抗病活性

[目的]进一步研究鸡Mx蛋白第631位氨基酸的变异与鸡群抗病性的相关性.[方法]本实验利用PCR突变技术将鸡Mx蛋白基因的全长cDNA第2032位的碱基由G突变为A(既631位氨基酸的改变),并将突变的Mx基因插入真核表达载体pcDNA3.0,重组表达载体转染COS-Ⅰ细胞后,进行RT-PCR与间接免疫荧光(IFA)鉴定.[结果]对鸡Mx蛋白基因的cDNA进行PCR诱变修饰正确,构建了能够正确表达鸡Mx蛋白的重组真核表达载体;诱变修饰重组Mx蛋白对抗新城疫病毒(NDV)感染分析结果显示,重组Mx蛋白具有较强的抗新城疫病毒生物活性.[结论]为下一步研究鸡Mx蛋白的抗病机理与制备抗病转基因鸡奠定了坚实的基础.     

鳜鱼Mx蛋白全长cDNA的克隆和序列分析

Mx蛋白是一类由I型干扰素诱导表达的抗病毒蛋白。本研究以感染了鳜传染性脾肾坏死病毒(Infectious spleen and kidney necrosis virus,ISKNV)的鳜鱼为材料,提取肝脏总RNA,通过逆转录一聚合酶链式反应(RT-PCR)扩增出Mx蛋白基因的核心片段序列,再应用3’和5’快速扩增cDNA末端(RACE)方法PCR扩增Mx蛋白cDNA末端,最终获得鳜鱼Mx蛋白cDNA序列(GenBank登陆号：AY392097)。序列分析表明：鳜鱼Mx蛋白cDNA含有2391bp,其中编码区长1881bp,编码627个氨基酸残基,推测蛋白质分子量大小为7．15kDa。鳜鱼Mx蛋白具有脊椎动物Mx蛋白共有的结构特征：一个三联体GTP结合区域(GXXXSGKS/T、DXXG、T／NKXD)一个发动蛋白家族的典型结构特征序列(LPRGS／KGIVTR);以及C端高度保守的Leu拉链结构域。鳜鱼Mx蛋白全基因的获得为下一步研究鱼类Mx蛋白的抗病毒活性、作用机制,以及干扰素的检测奠定了基础。     

赤眼鳟Mx1基因的cDNA克隆及表达特性

为探究赤眼鳟(Squaliobarbus curriculus)是否存在Mx1 (Myxovirus resistance)基因及参与抗病毒免疫反应, 研究利用RACE技术获得了赤眼鳟Mx1基因(ScMx1)的cDNA全长序列, 并对其进行了生物信息学分析; 采用荧光定量PCR技术, 检测了ScMx1在赤眼鳟健康组织中的表达情况以及感染GCRV后ScMx1和ScIFN-Ⅰ的表达特征。结果表明, ScMx1的cDNA全长为3000 bp, 包含5′非编码区124 bp, 开放阅读框1893 bp, 3′非编码区983 bp, 共编码630个氨基酸。预测的ScMx1蛋白包含GTP酶结合区域、中央核心结构域和GTP酶效应结构域。ScMx1与青鱼Mx1的相似性最高(97%), 与ScMx的相似性仅为50%。ScMx1在所检测的10种组织中均有表达, 其中在脾脏中表达量最高。经GCRV感染开始至168h, ScMx1和ScIFN-Ⅰ在肝脏和体肾中的表达量持续上调; 在脾脏和头肾中于感染后72h达到峰值。相关性分析显示脾脏中ScMx1和ScIFN-Ⅰ的表达水平呈显著相关(r=0.94, P=0.018)。研究发现赤眼鳟存在Mx1基因, 且可能参与了抗GCRV免疫应答反应。     

IL-2与猪细小病毒VP2基因双表达载体的构建及免疫原性的研究

将白细胞介素-2基因和猪细小病毒VP2基因主要抗原区克隆至pCI-neo真核表达载体中,构建了pCIneo-IL2-VP2重组质粒,用脂质体将其转染到PK-15细胞中,利用免疫荧光方法检测在体外表达情况。并以小鼠为动物模型,将pCIneo-IL2-VP2重组质粒、对照组pCI-neo和猪细小病毒活疫苗通过肌肉注射进行免疫,检测免疫小鼠的淋巴细胞转化功能,特异性CTL杀伤活性和血清抗体滴度。结果显示,pCIneo-IL2-VP2在体外能够诱导PK-15细胞表达VP2蛋白,小鼠注射pCIneo-IL2-VP2质粒1周后能够诱导机体产生抗体,4周时达到峰值,与活疫苗对照组产生的抗体滴度、诱导T淋巴细胞增殖和诱导强的细胞毒性基本一致。试验表明,构建的pCIneo-IL2-VP2能够有效诱导机体产生体液免疫和细胞免疫。     

人天然免疫基因BCL10的猪同源物的识别、克隆与初步表达分析

采用电子克隆方法克隆到大小为925 bp的人天然免疫蛋白BCL10的猪同源基因完整cDNA序列(GenBank登录号：EU088132), 并利用RT-PCR方法从猪的全血中扩增出包含702 bp的完整开放读码框架(ORF)的cDNA片段。经核酸测序, 证明与电子克隆结果相符。利用NCBI BLAST分析该cDNA包含3个大小为57 bp、289 bp和356 bp的外显子, 并且定位于猪的4号染色体上。采用半定量PCR技术检测基础水平猪各组织BCL10基因mRNA表达丰度, 并将该基因构建到带有绿色标签的真核表达载体pEGFP-C1中, 采用脂质体转染法将该基因转入PK-15细胞, 通过绿色荧光标记和RT-PCR方法检测实验组的BCL10蛋白表达。研究结果表明, BCL10基因mRNA在脾脏中表达最高; 胸腺、大脑和淋巴结表达次之, 而肝脏只有微量表达, 肾脏没有检测到表达; 同时BCL10基因在PK-15细胞中得到了有效表达。     

干扰素诱导的鱼类Mx蛋白

Mx蛋白是干扰素诱导表达的蛋白家族中的成员,当机体和细胞受病毒感染或诱生剂处理时产生。Mx蛋白和其它干扰素诱导蛋白一起构成宿主细胞的抗病毒状态,以达到抗病毒的目的。研究表明,Mx蛋白具有抗病毒活性,还可能与其它基本生命活动如发育或分化,蛋白质分送和生长有关。在鱼类也发现多种Mx蛋白,具有Mx蛋白家族的共有特征;在肽链末端有一个三联ATP／GTP结合区和发动蛋白家族的结构特征序列;在蛋白C端存在使Mx蛋白形成三聚体的Leu拉链结构以及定位信号。但是迄今没有发现鱼类Mx蛋白的抗病毒活性。文章最后对目前鱼类病毒病的防治及利用抗病毒基因进行鱼类基因工程抗病毒育种进行了探讨。     

2A肽介导猪PID1与CuZnSOD双基因真核共表达载体的构建与细胞表达

构建PID1基因与CuZnSOD基因的真核共表达载体,在PK15细胞中鉴定基因的表达。PCR扩增的PID1与CuZnSOD两基因分别经双酶切后定向插入pIRES2-AcGFP1空载体,构建pIRES2-CuZnSOD-PID1真核双表达载体并进行测序与酶切鉴定。采用脂质体转染法将重组质粒转染至PK15细胞,细胞内荧光显微镜下观察其荧光的表达,RT-PCR、Westernblot技术分别检测PID1基因与CuZnSOD基因mRNA和蛋白表达情况。重组克隆载体插入目的片段序列与PID1基因与CuZnSOD基因序列完全一致。PIRES2-CuZnSOD-PID1真核双表达载体测序、酶切鉴定结果与预期结果一致。荧光显微镜下观察转染后的PK15细胞出现绿色荧光。RT-PCR检测结果显示,转染细胞中PID1基因与CuZnSOD基因表达量明显高于对照组（P〈0.05）。Westernblot检测结果表明pIRES2-CuZnSODPID1真核双表达载体稳定有效表达。成功构建pIRES2-CuZnSOD-PID1真核共表达载体,且双基因在真核细胞独立稳定表达,为转基因猪等育种新材料的制备奠定基础。     

Molecular Characterization of Mx1 Gene in Native Indian Breeds of Chicken

The genetic polymorphism of Mx1 gene was explored in Indian chicken breeds. PCR-RFLP analysis in 102?bp fragment of partial intron 13 and partial exon 14 of Mx1 gene revealed two genotypes viz. RS and SS with two alleles viz. R and S both in Naked Neck and Tellicherry breeds of chicken. The homozygous genotype RR was not identified. When deduced amino acid sequences were compared, the asparagine amino acid was found to be substituted in “R” allele for serine in “S” allele. PCR-SSCP analysis of 284?bp fragment in 5′-UTR and partial promoter region revealed three genotypes viz. CC, CG, and CH with three different alleles viz. C, G, and H in Naked Neck breed of chicken and five genotypes viz. DI, JK, KK, KL, and KM with six different alleles viz. D, I, J, K, L, and M in Tellicherry breed of chicken. The homozygous genotypes viz. GG and HH in Naked Neck and DD, II, JJ, LL, and MM in Tellicherry chicken was not identified. The nucleotide substitution rate estimated to be in the range of 0.004–0.011. The identified genetic variation can be helpful for better insight to disease resistance property of the Mx1 gene.     

猪Mx1基因第14外显子多态性分析及新突变位点的 发现

采用PCR-RFLP方法对国内外7个猪种Mx1基因第14外显子的多态性进行分析, 共检测到3个等位基因, 6种基因型。其中杜洛克中仅存在AA基因型, 苏太猪中存在全部基因型, 只有在梅山猪和具有梅山猪血统的苏太猪中出现基因型BB。所有猪种中, 只有在地方猪种和培育猪种中出现等位基因B, 所有猪种除松辽黑猪外均以A为优势等位基因。卡方检验结果表明, 不同猪种间基因型分布差异较大, 梅山猪和松辽黑猪与其他所有猪种的基因型频率差异极显著(P＜0.01) , 苏太猪与除皮特兰猪外的所有猪种的基因型频率差异也极显著(P＜0.01) , 淮猪与杜洛克和约克夏这两个国外猪种基因型频率差异不显著(P＞0.05), 而与皮特兰和其他地方猪种的基因型频率均存在极显著差异(P＜0.01) 。通过测序在扩增片段中新发现了3种类型的碱基突变, 前2个分别导致了Thr和Glu向Ala和Arg的替换, 最后一个突变不引起氨基酸的变化, 且后两个突变位点为BB基因型所特有。     

Interferon, Mx, and viral countermeasures

The interferon system provides a powerful and universal intracellular defense mechanism against viruses. Knockout mice defective in IFN signaling quickly succumb to all kinds of viral infections. Likewise, humans with genetic defects in interferon signaling die of viral disease at an early age. Among the known interferon-induced antiviral mechanisms, the Mx pathway is one of the most powerful. Mx proteins belong to the dynamin superfamily of large GTPases and have direct antiviral activity. They inhibit a wide range of viruses by blocking an early stage of the viral replication cycle. Likewise, the protein kinase R (PKR), and the 2–5 OAS/RNaseL system represent major antiviral pathways and have been extensively studied. Viruses, in turn, have evolved multiple strategies to escape the IFN system. They try to go undetected, suppress IFN synthesis, bind and neutralize secreted IFN molecules, block IFN signaling, or inhibit the action of IFN-induced antiviral proteins. Here, we summarize recent findings about the astonishing interplay of viruses with the IFN response pathway.     

Interferon-Induced Antiviral Mx1 GTPase Is Associated with Components of the SUMO-1 System and Promyelocytic Leukemia Protein Nuclear Bodies

Mx proteins are interferon-induced large GTPases, some of which have antiviral activity against a variety of viruses. The murine Mx1 protein accumulates in the nucleus of interferon-treated cells and is active against members of the Orthomyxoviridae family, such as the influenza viruses and Thogoto virus. The mechanism by which Mx1 exerts its antiviral action is still unclear, but an involvement of undefined nuclear factors has been postulated. Using the yeast two-hybrid system, we identified cellular proteins that interact with Mx1 protein. The Mx1 interactors were mainly nuclear proteins. They included Sp100, Daxx, and Bloom's syndrome protein (BLM), all of which are known to localize to specific subnuclear domains called promyelocytic leukemia protein nuclear bodies (PML NBs). In addition, components of the SUMO-1 protein modification system were identified as Mx1-interacting proteins, namely the small ubiquitin-like modifier SUMO-1 and SAE2, which represents subunit 2 of the SUMO-1 activating enzyme. Analysis of the subcellular localization of Mx1 and some of these interacting proteins by confocal microscopy revealed a close spatial association of Mx1 with PML NBs. This suggests a role of PML NBs and SUMO-1 in the antiviral action of Mx1 and may allow us to discover novel functions of this large GTPase.     

A Naturally Occurring Variant of Porcine Mx1 Associated with Increased Susceptibility to Influenza Virus In Vitro

Mx1 has been implicated in resistance to the influenza virus. We have now identified four alleles of the Mxl gene in domesticated breeds of pigs. Two of the alleles encode deletion variants (a 3-bp deletion in exon 13 and an 11-bp deletion in exon 14), which might be expected to interfere with Mx activity. The porcine Mxl genes corresponding to wild type, the 3-bp deletion mutant, and the 11-bp deletion mutant were cloned and expressed in NIH3T3 cells, and the antiviral activity for influenza virus was assayed. Virus yield was observed to be 10–100-fold greater with the 11-bp deletion allele than that for wild type and the 3-bp deletion alleles. The results suggest that the 11-bp deletion type is lacking antiviral activity able to contribute to the interference of influenza virus replication.     

Three types of polymorphisms in exon 14 in porcine Mx1 gene

Much is known about the antiviral activity of Mx proteins in species such as mouse and human. In the mouse, loss of resistibility to influenza virus has been shown to be due to specific polymorphisms in the Mx gene. This gene is therefore an interesting candidate gene for disease resistance in farm animals. The porcine Mx1 gene has already been identified and characterized based on its homology with mouse Mx1; however, until now no evidence of polymorphisms in the porcine gene has been reported. In this study, we have found two new polymorphisms in exon 14 of porcine Mx1 by DNA sequencing and confirmed their presence in different breeds, using polymerase chain reaction (PCR)–restriction fragment length polymorphisms (RFLP) with NarI and NaeI restriction enzymes. On the basis of the deduced amino acid sequence, one allele contains a deletion that may result in a frameshift to yield several amino acid substitutions and extension of the carboxyl terminal region of Mx1 protein. The deletion allele, Mx1 ^c, was found to be segregating in Landrace, Berkshire, Duroc, Hampshire, and Yucatan miniature pig. A second point mutation, Mx1 ^b, was detected in Meishan and two Vietnamese native pig breeds. All other breeds tested were fixed for the Mx1 ^a allele that is identical to the sequence reported previously. It will be interesting to determine if the Mx1 ^c deletion is associated with variation in resistance to the myxovirus family in the pig.     

The Large GTPase Mx1 Is Involved in Apical Transport in MDCK Cells

In epithelial cells apical proteins are transported by specific transport carriers to the correct membrane domain. The composition of these carriers is heterogeneous and comprises components such as motor proteins, annexins, lectins, Rab GTPases and cargo molecules. Here, we provide biochemical and fluorescence microscopic data to show that the dynamin‐related large GTPase Mx1 is a component of post‐Golgi vesicles carrying the neurotrophin receptor p75^NTR. Moreover, siRNA‐mediated depletion of Mx1 significantly decreased the transport efficiency of apical proteins in MDCK cells. In conclusion, Mx1 plays a crucial role in the delivery of cargo molecules to the apical membrane of epithelial cells.      

Co-immunoprecipitation of the Mouse Mx1 Protein with the Influenza A Virus Nucleoprotein

Studying the interaction between proteins is key in understanding their function(s). A very powerful method that is frequently used to study interactions of proteins with other macromolecules in a complex sample is called co-immunoprecipitation. The described co-immunoprecipitation protocol allows to demonstrate and further investigate the interaction between the antiviral myxovirus resistance protein 1 (Mx1) and one of its viral targets, the influenza A virus nucleoprotein (NP). The protocol starts with transfected mammalian cells, but it is also possible to use influenza A virus infected cells as starting material. After cell lysis, the viral NP protein is pulled-down with a specific antibody and the resulting immune-complexes are precipitated with protein G beads. The successful pull-down of NP and the co-immunoprecipitation of the antiviral Mx1 protein are subsequently revealed by western blotting. A prerequisite for successful co-immunoprecipitation of Mx1 with NP is the presence of N-ethylmaleimide (NEM) in the cell lysis buffer. NEM alkylates free thiol groups. Presumably this reaction stabilizes the weak and/or transient NP–Mx1 interaction by preserving a specific conformation of Mx1, its viral target or an unknown third component. An important limitation of co-immunoprecipitation experiments is the inadvertent pull-down of contaminating proteins, caused by nonspecific binding of proteins to the protein G beads or antibodies. Therefore, it is very important to include control settings to exclude false positive results. The described co-immunoprecipitation protocol can be used to study the interaction of Mx proteins from different vertebrate species with viral proteins, any pair of proteins, or of a protein with other macromolecules. The beneficial role of NEM to stabilize weak and/or transient interactions needs to be tested for each interaction pair individually.     

鳜鱼Mx蛋白全长cDNA的克隆和序列分析

Mx蛋白是一类由I型干扰素诱导表达的抗病毒蛋白.本研究以感染了鳜传染性脾肾坏死病毒(Infectious spleen and kidney necrosis virus,ISKNV)的鳜鱼为材料,提取肝脏总RNA,通过逆转录-聚合酶链式反应(RT-PCR)扩增出Mx蛋白基因的核心片段序列,再应用3'和5'快速扩增cDNA末端(RACE)方法PCR扩增Mx蛋白cDNA末端,最终获得鳜鱼Mx蛋白cDNA序列(GenBank登陆号AY392097).序列分析表明鳜鱼Mx蛋白cDNA含有2391bp,其中编码区长1881bp,编码627个氨基酸残基,推测蛋白质分子量大小为7.15kDa.鳜鱼Mx蛋白具有脊椎动物Mx蛋白共有的结构特征一个三联体GTP结合区域(GXXXSGKS/T、DXXG、T/NKXD);一个发动蛋白家族的典型结构特征序列(LPRGS/KGIVTR);以及C端高度保守的Leu拉链结构域.鳜鱼Mx蛋白全基因的获得为下一步研究鱼类Mx蛋白的抗病毒活性、作用机制,以及干扰素的检测奠定了基础.