鸡白细胞介素2增强传染性法氏囊病病毒多聚蛋白DNA疫苗免疫原性的研究

鸡白细胞介素 2(IL-2)基因是新近被确定的非哺乳类IL-2基因。将鸡白细胞介素2(IL-2)基因和传染性法氏囊病病毒 (IBDV)多聚蛋白基因 (VP2/VP4/VP3)分别插入真核表达载体pCI的CMV启动子下游 ,制备DNA疫苗 ,免疫 14日龄SPF鸡 ,14d后二免 ,二免后 3d攻击标准强毒株。结果表明共注射鸡IL 2质粒能明显增强DNA疫苗对强毒攻击 ,保护率达 80 % ;能增强DNA疫苗诱导的中和抗体效价 (P<0.05 ) ;能显著促进鸡胸腺、脾脏和外周血液T淋巴细胞及法氏囊B淋巴细胞增殖反应(P<0.05)。这些结果提示鸡IL 2能明显增强IBDV多聚蛋白DNA疫苗的免疫原性 ,是一种优良的禽类DNA疫苗佐剂。     

利用酵母双杂交技术筛选与生殖支原体黏附蛋白(MgPa)相互作用的宿主蛋白

从利用基于分离的泛素介导膜蛋白酵母双杂交系统构建的人尿道上皮细胞cDNA文库中筛选生殖支原体(Mg)黏附蛋白(MgPa)的互作蛋白。以pET30a-MgPa为模板,经PCR扩增MgPa基因,将其分别连接到pBT3STE和pBT3SUC载体以构建诱饵质粒pBT3STE-MgPa和pBT3SUC-MgPa;将诱饵质粒分别转化到酵母菌株NMY32内,检测其毒性和自激活活性;将人尿道上皮细胞cDNA文库质粒pPR3-N-207-Zeng转入到含pBT3SUC-MgPa诱饵质粒的酵母菌株中,筛选阳性克隆。检测阳性克隆LacZ报告基因的活性。提取阳性克隆质粒进行DNA测序与BLAST分析。结果显示,成功构建的诱饵质粒pBT3STE-MgPa和pBT3SUC-MgPa两者都没有自激活功能,且pBT3SUC-MgPa的活性强于pBT3STE-MgPa。用pBT3SUC-MgPa转化NMY32酵母作为受体酵母细胞。经DNA测序与BLAST分析结果表明筛选到的28个阳性克隆归属于23个不同的蛋白。从利用分离的泛素介导膜蛋白酵母双杂交系统构建的人尿道上皮细胞cDNA文库中筛选到23个与MgPa相互作用的蛋白,为阐明MgPa的功能及Mg可能的致病机制提供参考。     

鸡传染性法氏囊病病毒基因组B片段的克隆与序列分析

鸡传染性法氏囊病病毒(IBDV)属双链双节段RNA病毒科,禽双链RNA病毒属.IBDV基因组由A、B两个RNA片段组成.VP2是最主要的IBDV结构蛋白,由A片段编码,它的变异最有可能导致IBDV血清型变异.最近的研究表明:B片段对病毒的毒力也有一定的影响.而我国对B片段的研究还未见报道.为此,我们克隆了我国甘肃地区IBDV分离强毒株Ts毒株的B片段全序列,并与报道的序列进行了比较分析.     

鸡传染性法氏囊病病毒Gt株VP5基因缺失株感染性克隆的构建

传染性法氏囊病病毒 (IBDV)是双链,双节段RNA病毒,其基因组由A、B两个节段组成,编码结构蛋白VP1-VP4和非结构蛋白VP5。【目的】利用反向遗传操作构建拯救VP5基因缺失重组IBDV。【方法】利用体外定点突变技术,缺失IBDV Gt株VP5基因,通过多重PCR在基因组两端分别引入锤头状核酶序列(HamRz)和丁肝病毒核酶序列(HdvRz)。将带有核酶序列的IBDV基因组插入载体pCAGG的b肌动蛋白启动子下游,构建了IBDV感染性克隆pCAGGmGtA △VP5HRT,将该感染性克隆与pCAGGmGtBHRT共转染DFⅠ细胞。【结果】RT-PCR和间接免疫荧光均显示获得重组病毒,将其命名为rmGtA △VP5。IBDV VP5基因缺失感染性克隆的成功构建为从分子水平上深入研究vp5基因功能奠定了基础。     

利用酵母双杂交系统从人胚胎肝脏cDNA文库中筛选与JNKK2相互作用的蛋白

目的:利用酵母双杂交系统,以149位赖氨酸突变成甲硫氨酸的c-Jun N端激酶激酶2(JNKK2)失活突变体(JNKK2KM)为诱饵,从人胎肝文库中筛选能与JNKK2作用的蛋白。方法:构建诱饵质粒p GBKT7-JNKK2KM,将其转化到AH109感受态酵母菌中进行扩增,而后检测融合蛋白表达、自激活活性以及对宿主的毒性;将诱饵酵母菌与含有人胎肝c DNA文库质粒的Y187交配进行酵母双杂交筛选,经缺陷型培养基筛选排除假阳性克隆;取阳性菌落抽提质粒进行酶切鉴定,对鉴定后的阳性克隆进行测序及生物信息学分析,明确筛选出的蛋白信息,通过免疫共沉淀实验验证筛选出的蛋白与JNKK2的相互作用。结果:构建了诱饵质粒,检测到融合蛋白的表达,且无自激活作用,未发现对宿主存在毒性;初步筛选到120个阳性克隆,经多轮重复验证得到阳性克隆11个,经生物信息学分析最后确定3个可以与JNKK2相互作用的新蛋白质分子为鸟嘌呤核苷酸结合蛋白β多肽2样蛋白1(GNB2L1)、开放读框60(ORF60)与泛素样修饰物激活酶3(UBA3),免疫共沉淀实验表明它们均能与JNKK2发生相互作用。结论:筛选到3个新的JNKK2相互作用蛋白,为深入探究JNKK2在肝脏中的作用奠定了基础。     

传染性法氏囊病病毒VP4蛋白单克隆抗体的制备及鉴定

传染性法氏囊病病毒(IBDV)蛋白VP4在抑制宿主免疫应答中起重要作用,为制备IBDV VP4的单克隆抗体,以实验室保存的融合蛋白His-VP4免疫BALB/c小鼠,经过细胞融合、筛选、亚克隆后获得4株能稳定分泌抗VP4的单抗杂交瘤细胞株,分别命名为3B3、3H11、4C8和4G6,经间接ELISA测定4株单抗的亲和力解离常数分别为4.61×10–11、1.71×10–10、4.26×10–11和5.02×10–11,均为高亲和力抗体。4株单抗的重链类型分别为Ig G1、Ig G1、Ig G2b和Ig G1。进一步以Western blotting鉴定,该4株单抗均能特异地识别IBDV的VP4蛋白,间接免疫荧光和Western blotting试验表明4株单抗均能识别IBDV感染DF-1细胞后产生的VP4蛋白。该单抗为检测IBDV以及研究IBDV VP4的生物学作用奠定了基础。     

鸡传染性法氏囊病病毒研究进展

传染性法氏囊病(Infection bursal disease, IBD)是由鸡传染性法氏囊病毒(Infectious bursal disease virus, IBDV)引起的鸡和火鸡的一种高度接触性传染病,给世界各国的禽养殖业带来了巨大损失。自IBDV发现至今新的变异株不断出现,分子结构的改变导致病毒致病力的改变及宿主对疫苗应答的改变,使得传统的疫苗已不能控制其流行,因此各国学者对其基因组结构和功能进行了广泛深入的研究,并积极研制新型有效的疫苗以达到防治的目的。 1 基因组结构和功能 IBDV基因组由A(3.2kb)、B(2.8kb)两个双链RNA节段构成。A编码形成VP2蛋白(37-40k…     

转录因子X-box结合蛋白1相互作用蛋白的筛选和鉴定

X-box 结合蛋白 1 是一种重要的转录因子,参与体内多项信号转导过程. 为进一步研究 XBP1 的生物学功能,运用酵母双杂交技术在肝细胞文库中筛选 XBP1 的结合蛋白. 首先运用 PCR 技术扩增获得 XBP1 的编码序列,克隆至 pGEM-T 载体,经测序鉴定后,亚克隆至诱饵载体 pGBKT7 中,转化酵母 AH109(a type). 免疫印迹检测诱饵质粒 pGBKT7-XBP1 在AH109 酵母中的表达之后,含有诱饵质粒的酵母 AH109 与含有肝细胞 cDNA 文库质粒 pACT2 的酵母 Y187(αtype)配合,配合后的二倍体酵母生长在含有 X-α-gal 的营养缺陷型培养基上 (SD/-Trp-Leu-His-Ade) 进行选择和筛选,经测序和序列比对确定阳性克隆的开放读码框 ORF,得到 7 种不同的蛋白质. 为了进一步验证这些筛选蛋白质与 XBP1 的相互作用,克隆其中一种蛋白质 MT1E,并运用 GST pulldown 和免疫共沉淀技术成功检测了 MT1E 和 XBP1 的相互作用(体外 / 体内),结果提示,MT1E 可能是 XBP1 的一个新的调节蛋白. 通过酵母双杂交技术筛选得到的 7 种蛋白质分别与肝细胞基础代谢、蛋白质的合成与运输、细胞的增殖与凋亡密切相关. 上述结果有助于揭示 XBP1 的生物学功能,为进一步探讨 XBP1 的表达和调控机制提供新线索.     

鸡源CD40L基因克隆、蛋白表达及生物活性检测

为获得鸡源CD40L (chCD40L) 蛋白,以鸡脾细胞制备cDNA并以之为模板扩增chCD40L基因,构建pFastBac-chCD40L供体重组质粒,转化感受态细胞DH10Bac,通过筛选及鉴定获得Bacmid-chCD40L重组质粒,转入真核表达系统sf9昆虫细胞进行蛋白表达与纯化,获得His-chCD40L蛋白。此外,构建pQM01-chCD40L质粒,转染HEK 293T细胞进行蛋白表达与纯化,获得Strep-chCD40L蛋白。亲和层析纯化的chCD40L蛋白浓度为0.01 mg/mL。为检测chCD40L蛋白的生物活性,分离和培养3周龄SPF雏鸡的法氏囊组织原代细胞,将chCD40L加入细胞培养液刺激细胞增殖,通过Western blotting试验、间接免疫荧光试验、流式细胞术检测,发现该蛋白能够与法氏囊B淋巴细胞表面的CD40结合,说明chCD40L具有生物活性。成功获得chCD40L蛋白,为原代B淋巴细胞体外培养及IBDV野毒分离与诊断奠定了基础。     

VSV糖蛋白酵母双杂交诱饵载体的构建及其自激活作用的检测

构建水泡性口炎病毒糖蛋白(VSV-G)酵母双杂交诱饵载体,检测其在酵母细胞中的表达和自激活作用,为进一步研究酵母双杂交系统筛选与VSV-G相互作用蛋白奠定基础。通过RT-PCR方法从水泡性口炎病毒(VSV)克隆糖蛋白(G)基因,BamH I和Sal I双酶切后连接诱饵载体pSos,获得诱饵质粒pSos-VSV-G,经测序鉴定后pSos-VSV-G转化到酵母菌株cdcH25(α),在营养缺陷培养基中观察pSos-VSV-G的自激活作用和毒性作用,同时利用蛋白印迹法分析诱饵蛋白的表达。成功扩增VSV-G基因,并准确克隆入pSos中,诱饵载体pSos-VSV-G成功转化到酵母菌株cdcH25(α)中,经表型筛选检测无自激活作用和毒性作用,蛋白印迹法检测证实pSos-VSV-G在酵母细胞中表达诱饵蛋白。可以利用酵母双杂交系统筛选与VSV-G相互作的蛋白质。     

Molecular determinants of virulence, cell tropism, and pathogenic phenotype of infectious bursal disease virus.

Infectious bursal disease viruses (IBDVs), belonging to the family Birnaviridae, exhibit a wide range of immunosuppressive potential, pathogenicity, and virulence for chickens. The genomic segment A encodes all the structural (VP2, VP4, and VP3) and nonstructural proteins, whereas segment B encodes the viral RNA-dependent RNA polymerase (VP1). To identify the molecular determinants for the virulence, pathogenic phenotype, and cell tropism of IBDV, we prepared full-length cDNA clones of a virulent strain, Irwin Moulthrop (IM), and constructed several chimeric cDNA clones of segments A and B between the attenuated vaccine strain (D78) and the virulent IM or GLS variant strain. Using the cRNA-based reverse-genetics system developed for IBDV, we generated five chimeric viruses after transfection by electroporation procedures in Vero or chicken embryo fibroblast (CEF) cells, one of which was recovered after propagation in embryonated eggs. To evaluate the characteristics of the recovered viruses in vivo, we inoculated 3-week-old chickens with D78, IM, GLS, or chimeric viruses and analyzed their bursae for pathological lesions 3 days postinfection. Viruses in which VP4, VP4-VP3, and VP1 coding sequences of the virulent strain IM were substituted for the corresponding region in the vaccine strain failed to induce hemorrhagic lesions in the bursa. In contrast, viruses in which the VP2 coding region of the vaccine strain was replaced with the variant GLS or virulent IM strain caused rapid bursal atrophy or hemorrhagic lesions in the bursa, as seen with the variant or classical virulent strain, respectively. These results show that the virulence and pathogenic-phenotype markers of IBDV reside in VP2. Moreover, one of the chimeric viruses containing VP2 sequences of the virulent strain could not be recovered in Vero or CEF cells but was recovered in embryonated eggs, suggesting that VP2 contains the determinants for cell tropism. Similarly, one of the chimeric viruses containing the VP1 segment of the virulent strain could not be recovered in Vero cells but was recovered in CEF cells, suggesting that VP1 contains the determinants for cell-specific replication in Vero cells. By comparing the deduced amino acid sequences of the D78 and IM strains and their reactivities with monoclonal antibody 21, which binds specifically to virulent IBDV, the putative amino acids involved in virulence and cell tropism were identified. Our results indicate that residues Gln at position 253 (Gln253), Asp279, and Ala284 of VP2 are involved in the virulence, cell tropism, and pathogenic phenotype of virulent IBDV.     

Envelope Proteins of White Spot Syndrome Virus (WSSV) Interact with Litopenaeus vannamei Peritrophin-Like Protein (LvPT)

White spot syndrome virus (WSSV) is a major pathogen in shrimp cultures. The interactions between viral proteins and their receptors on the surface of cells in a frontier target tissue are crucial for triggering an infection. In this study, a yeast two-hybrid (Y2H) library was constructed using cDNA obtained from the stomach and gut of Litopenaeus vannamei, to ascertain the role of envelope proteins in WSSV infection. For this purpose, VP37 was used as the bait in the Y2H library screening. Forty positive clones were detected after screening. The positive clones were analyzed and discriminated, and two clones belonging to the peritrophin family were subsequently confirmed as genuine positive clones. Sequence analysis revealed that both clones could be considered as the same gene, LV-peritrophin (LvPT). Co-immunoprecipitation confirmed the interaction between LvPT and VP37. Further studies in the Y2H system revealed that LvPT could also interact with other WSSV envelope proteins such as VP32, VP38A, VP39B, and VP41A. The distribution of LvPT in tissues revealed that LvPT was mainly expressed in the stomach than in other tissues. In addition, LvPT was found to be a secretory protein, and its chitin-binding ability was also confirmed.     

Conservation of the DNA sequences encoding the major structural viral proteins of WSSV

A cDNA library was constructed from white spot syndrome virus (WSSV)-infected penaeid shrimp tissue. cDNA clones with WSSV inserts were isolated and sequenced. By comparison with DNA sequences in GenBank, cDNA clones containing sequence identical to those of the WSSV envelope protein VP28 and nucleoprotein VP15 were identified. Poly(A) sites in the mRNAs of VP28 and VP15 were identified. Genes encoding the major viral structural proteins VP28, VP26, VP24, VP19 and VP15 of 5 WSSV isolates collected from different shrimp species and/or geographical areas were sequenced and compared with those of 4 other WSSV isolate sequences in GenBank. For each of the viral structural protein genes compared, the nucleotide sequences were 100 to 99% identical among the 9 isolates. Gene probes or PCR primers based on the gene sequences of the WSSV structural proteins can be used for diagnoses and/or detection of WSSV infection.     

Rescue of very virulent and mosaic infectious bursal disease virus from cloned cDNA: VP2 is not the sole determinant of the very virulent phenotype

Many recent outbreaks of infectious bursal disease in commercial chicken flocks worldwide are due to the spread of very virulent strains of infectious bursal disease virus (vvIBDV). The molecular determinants for the enhanced virulence of vvIBDV compared to classical IBDV are unknown. The lack of a reverse genetics system to rescue vvIBDV from its cloned cDNA hampers the identification and study of these determinants. In this report we describe, for the first time, the rescue of vvIBDV from its cloned cDNA. Two plasmids containing a T7 promoter and either the full-length A- or B-segment cDNA of vvIBDV (D6948) were cotransfected into QM5 cells expressing T7 polymerase. The presence of vvIBDV could be detected after passage of the transfection supernatant in either primary bursa cells (in vitro) or embryonated eggs (in vivo), but not QM5 cells. Rescued vvIBDV (rD6948) appeared to have the same virulence as the parental isolate, D6948. Segment-reassorted IBDV, in which one of the two genomic segments originated from cDNA of classical attenuated IBDV CEF94 and the other from D6948, could also be rescued by using this system. Segment-reassorted virus containing the A segment of the classical attenuated isolate (CEF94) and the B segment of the very virulent isolate (D6948) is not released until 15 h after an in vitro infection. This indicates a slightly retarded replication, as the first release of CEF94 is already found at 10 h after infection. Next to segment reassortants, we generated and analyzed mosaic IBDVs (mIBDVs). In these mIBDVs we replaced the region of CEF94 encoding one of the viral proteins (pVP2, VP3, or VP4) by the corresponding region of D6948. Analysis of these mIBDV isolates showed that tropism for non-B-lymphoid cells was exclusively determined by the viral capsid protein VP2. However, the very virulent phenotype was not solely determined by this protein, since mosaic virus containing VP2 of vvIBDV induced neither morbidity nor mortality in young chickens.     

Ability of Lactococcus lactis to export viral capsid antigens: a crucial step for development of live vaccines

The food grade bacterium Lactococcus lactis is a potential vehicle for protein delivery in the gastrointestinal tract. As a model, we constructed lactococcal strains producing antigens of infectious bursal disease virus (IBDV). IBDV infects chickens and causes depletion of B-lymphoid cells in the bursa of Fabricius and subsequent immunosuppression, morbidity, or acute mortality. The two major IBDV antigens, i.e., VP2 and VP3, that form the viral capsid were expressed and targeted to the cytoplasm, the cell wall, or the extracellular compartment of L. lactis. Whereas VP3 was successfully targeted to the three compartments by the use of relevant expression and export vectors, VP2 was recalcitrant to export, thus confirming the difficulty of translocating naturally nonsecreted proteins across the bacterial membrane. This defect could be partly overcome by fusing VP2 to a naturally secreted protein (the staphylococcal nuclease Nuc) that carried VP2 through the membrane. Lactococcal strains producing Nuc-VP2 and VP3 in various bacterial compartments were administered orally to chickens. The chickens did not develop any detectable immune response against VP2 and VP3 but did exhibit an immune response against Nuc when Nuc-VP2 was anchored to the cell wall of lactococci.     

传染性法氏囊病病毒VP2基因的真核表达载体的构建及表达

根据GenBank发表的传染性法氏囊病病毒 (IBDV) 5 2 70株VP2 基因序列 ,设计合成了 1对特异扩增IBDVVP₂ 基因的引物。以IBDV超强毒河南分离株HN0 1感染发病鸡法氏囊组织中提取病毒RNA来制模板 ,利用RT PCR扩增出了 1 .4kb的VP₂ 基因 ,将其克隆到pIREShyg载体上 ,构建了pIRES VP₂ 真核表达载体。然后通过磷酸钙共沉淀法转染CHO细胞 ,通过潮霉素筛选得到阳性克隆 ,间接免疫荧光实验 (IFA)鉴定VP₂ 在CHO细胞中的表达 ,并用RT PCR的方法从转录水平证实VP₂ 在CHO k1细胞中的表达 ,最终建立了CHO VP₂ 细胞株 株。     

Ability of Lactococcus lactis To Export Viral Capsid Antigens: a Crucial Step for Development of Live Vaccines

Thefood grade bacterium Lactococcus lactis is a potential vehicle for protein delivery in the gastrointestinal tract. As a model, we constructed lactococcal strains producing antigens of infectious bursal disease virus (IBDV). IBDV infects chickens and causes depletion of B-lymphoid cells in the bursa of Fabricius and subsequent immunosuppression, morbidity, or acute mortality. The two major IBDV antigens, i.e., VP2 and VP3, that form the viral capsid were expressed and targeted to the cytoplasm, the cell wall, or the extracellular compartment of L. lactis. Whereas VP3 was successfully targeted to the three compartments by the use of relevant expression and export vectors, VP2 was recalcitrant to export, thus confirming the difficulty of translocating naturally nonsecreted proteins across the bacterial membrane. This defect could be partly overcome by fusing VP2 to a naturally secreted protein (the staphylococcal nuclease Nuc) that carried VP2 through the membrane. Lactococcal strains producing Nuc-VP2 and VP3 in various bacterial compartments were administered orally to chickens. The chickens did not develop any detectable immune response against VP2 and VP3 but did exhibit an immune response against Nuc when Nuc-VP2 was anchored to the cell wall of lactococci.     

scFv antibodies against infectious bursal disease virus isolated from a combinatorial antibody library by flow cytometry

Infectious bursal disease is an economically important disease that affects chickens worldwide. Here, a recombinant single chain variable fragment (scFv) antibody library derived from chickens immunized with VP2 protein of infectious bursal disease virus (IBDV) was constructed. The library was subjected to three rounds of screening by flow cytometry against VP2 protein through a bacteria display technology, resulting in the enrichment of scFv. Three scFv clones with different fluorescence intensity were obtained by random colony pick up. The isolated scFv antibodies were expressed and purified. Relative affinity assay showed the three clones had different sensitivity to VP2, in accordance with fluorescence activity cell sorting analysis. The potential use of the selected IBDV-specific scFv antibodies was demonstrated by the successful application of the isolated antibodies in western blotting assay and ELISA.