幽门螺杆菌尿素酶B单位DNA疫苗的构建及鉴定

报告了利用淋巴细胞杂交瘤技术制备抗呼吸道合胞病毒蛋白的鼠单克隆抗体。获得 7株分泌抗呼吸道合胞病毒单克隆抗体的杂交瘤细胞株 :IF12 ,4H10 ,1D8,2B2 ,1G8,4G6 ,2D2。其中IF12 ,4H10 ,1D8,2B2 ,4G6分泌的抗体类别为IgG1,1G8为IgG2a ,2D2为IgG2b。经免疫印迹分析证实单抗 1F12 ,2B2识别病毒 4 4ku的蛋白 ,单抗1G8识别 37ku蛋白 ,2D2识别 2 1ku的病毒蛋白 ,单抗4G6识别病毒 90ku蛋白。对单抗的生物学活性进行了分析 ,单抗 4G6对呼吸道合胞病毒有明显的中和作用 ,小鼠腹水的中和滴度为 1∶32 ,其余各单抗中和滴度均小于1∶4。…     

蚕豆萎蔫病毒单克隆抗体制备及检测应用

:用蚕豆萎蔫病毒(BBWV)免疫的BALB/C鼠脾细胞与SP2/0鼠骨髓瘤细胞融合,经筛选克隆,获得6株能稳定传代并分泌抗BBWV单克隆抗体(Mab)的杂交瘤细胞株,单抗腹水ELISA滴度为1:320000～1:640000,各单抗抗体类型均为IgG1。6株单抗与BBWV不同分离物均有反应,而与其它植物病毒无交叉反应。经Westernblot印迹分析表明,此6株单克隆抗体均是针对BBWV447kD的外壳蛋白大亚基的特异性抗体。这是国内外首次报道获得BBWV单克隆抗体     

抗H9亚型禽流感病毒血凝素单克隆抗体的制备和鉴定

目的:获得分泌抗H9亚型禽流感病毒(AIV)血凝素单克隆抗体的杂交瘤细胞。方法:以H9N2亚型AIV为免疫原,免疫6～8周龄雌性BALB/c小鼠,取其脾细胞与骨髓瘤细胞Sp2/0-Ag-14,在PEG4000的作用下进行细胞融合,通过血凝抑制(HI)试验筛选分泌抗H9亚型AIV血凝素单克隆抗体的杂交瘤细胞。结果:经过连续3～4次克隆化,获得能稳定分泌抗H9亚型AIV血凝素的单克隆抗体细胞系6株,分别命名为1B2、1C10、1G2、2B7、2E3和5E11。6株细胞培养上清HI效价为24～28,腹水HI效价为210～213。除1G2为IgM外,其余5株均为IgG1。Western blotting结果显示,1B2、1C10、2B7和2E3能与AIVH9蛋白在Mr为75000处反应,表明其是针对AIVH9亚型血凝素蛋白的单抗。特异性试验表明该6株单抗均只与H9亚型AIV发生特异性HI反应,而不与其他14个HA亚型的AIV及新城疫病毒、传染性支气管炎病毒发生交叉反应,显示出良好的特异性。结论:制备了针对H9亚型禽流感病毒血凝素的单克隆抗体,为禽流感的快速诊断和病毒的抗原性分析等奠定了基础。     

禽网状内皮组织增殖病病毒gp90蛋白单克隆抗体的制备及其识别区分析

为了制备禽网状内皮组织增殖病病毒(REV)gp90蛋白的单克隆抗体,应用His-gp90融合蛋白免疫BALB/c小鼠,取免疫鼠的脾细胞与骨髓瘤细胞(SP2/0)进行融合,经过筛选、3次亚克隆后获得3株稳定分泌抗REV-gp90蛋白的单克隆抗体杂交瘤细胞株,分别命名为3G5-B8、3G5-A10和1G12。经间接ELISA(Enzyme-linked immunosorbent assay)方法检测,单克隆抗体的亲和力解离常数(Kd)分别为6.483×10–10、4.844×10–10和9.330×10–10,3株单抗的亚型分别为Ig G1、Ig G1和Ig G2b。经Western blotting和间接免疫荧光实验检测,3株单抗均能识别REV感染DF-1细胞后产生的gp90蛋白。以Western blotting方法利用单抗检测不同截短的gp90蛋白,初步确定3G5-B8和3G5-A10 2株单抗抗原识别区均位于gp90蛋白第200-245位氨基酸,而1G12株单抗识别区包含第230-235位氨基酸。这些单抗为REV的诊断和致病机理研究奠定了基础。     

抗羊口疮病毒ORFV118蛋白单克隆抗体的制备、鉴定及其应用

制备抗羊口疮病毒118(ORFV118)重组蛋白的单克隆抗体并鉴定其生物学特性。构建ORFV118原核表达重组质粒pET33b-ORFV118,将重组质粒转化大肠杆菌BL21,诱导表达出ORFV118重组蛋白;利用Ni-NTA亲和层析法纯化ORFV118重组蛋白;以纯化蛋白为抗原免疫小鼠,通过杂交瘤技术制备单克隆抗体;利用间接ELISA法、Western blot、免疫组化等方法分别对单抗特异性、效价、亚型以及ORFV118蛋白的功能进行研究。获得了3株稳定分泌单克隆抗体的细胞株,分别命名为1A2,3B5,5D10,它们诱生的小鼠腹水效价分别为110 000,16 400,18 000。其中效价最高的1A2抗体亚型为IgG1,能特异性结合其免疫原蛋白、真核表达产物以及病羊皮肤组织中的ORFV118蛋白。免疫组化结果显示单抗1A2染色局限于皮肤表皮层角化细胞及浸润至皮下组织的炎症细胞,与病毒侵染上皮组织层的特性相符。制备的单抗1A2能特异性识别ORFV118。深入研究单抗1A2将为了解ORFV118的生物学特性,为羊传染性脓疱病的诊断、预防与治疗提供可能和新思路。     

口蹄疫病毒单克隆抗体的制备及检测应用

用纯化的口蹄疫病毒(Footandmouthdiseasevirus,FMDV)免疫BALB/C小鼠,将免疫鼠的脾细胞与SP2/0骨髓瘤细胞融合,采用有限稀释法进行克隆,经筛选获得多株能稳定分泌抗FMDV单抗的杂交瘤细胞株。选择其中一株(2G12)用于下列实验,其细胞培养上清液的效价是1:256,腹水效价是1:1280;以自行制备的兔抗FMDV高免血清IgG为捕获抗体包被酶联免疫吸附试验微量反应板,以单抗2G12为第二抗体,建立了快速检测FMDV抗原的双抗体夹心ELISA,该方法能检出90ng病毒,而且只与FMDV发生特异性反应,与猪瘟病毒(HCV)、猪蓝耳病病毒(PRRSV)、伪狂犬病毒(PRV)、猪细小病毒(PPV)和乙脑病毒(JEV)均不发生反应。本研究为检测口蹄疫病毒抗原提供了灵敏和特异的方法。     

呼吸道合胞病毒G蛋白的相关研究

呼吸道合胞病毒G蛋白介导病毒附着在宿主细胞表面,且具有亚型间抗原结构变异大的特点,其抗原变异推测是呼吸道合胞病毒逃避已存在免疫监视,引起反复感染的原因,了解G蛋白与免疫反应的关系对研制呼吸道合胞病毒亚单位疫苗,有效地防治该病毒感染具有重要意义。     

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。     

西藏地区儿童急性呼吸道感染中呼吸道合胞病毒的初步研究

本研究为了解西藏地区儿童急性呼吸道感染中呼吸道合胞病毒(Respiratory syncytial virus,RSV)及基因型别。首先采用直接免疫荧光法检测2011年4～7月西藏自治区人民医院儿科病房因急性呼吸道感染住院患儿的鼻咽分泌物标本中7种常见的呼吸道病毒及人类偏肺病毒(Human metapneumovirus,hMPV)的抗原。然后对RSV抗原阳性的标本分别提取RNA,用逆转录-巢式聚合酶链反应法(Nest-PCR)确定RSV型别,同时用实时荧光PCR(Real-Time PCR)方法进行验证。再通过对G蛋白基因PCR扩增产物序列测定确定RSV的基因型。通过与GenBank中不同地区RSV分离株的G蛋白基因序列比对,了解西藏地区RSV G蛋白的结构特点及变异情况。结果表明,从167例标本中检测出呼吸道病毒抗原阳性的为65例,总阳性率为38.9%(65/167),其中RSV 45例,占阳性标本的69.2%(45/65),对其中42例RSV阳性标本进行了PCR分型,其中40例为A亚型,2例为B亚型。对7株A亚型RSV G蛋白基因PCR产物测序结果显示,全部为GA2基因型。西藏RSV与RSV原型株A2株核苷酸的同源性为90.7%～91.8%,氨基酸的同源性只有86.5%～87.2%。氨基酸的变异主要集中在胞外区一个高度保守序列的两端。7株西藏A亚型RSV G蛋白的核苷酸序列与GenBank中不同的RSV分离株相比同源性为90.7%～91.8%。西藏地区2011年春季小儿急性呼吸道感染的病毒病原主要为呼吸道合胞病毒,A亚型是2011年西藏地区的流行优势型别,其G蛋白胞外区基因具有较高的变异性。     

高致病性H5亚型禽流行性感冒病毒血凝素单克隆抗体的制备与初步应用

以禽流感病毒株Ck/HK/Yu22/02（H5N1）作为免疫原,利用常规杂交瘤技术和血凝抑制试验法成功地筛选出6株稳定分泌抗高致病性H5亚型禽流感病毒血凝素的单克隆抗体（单抗）,分别命名为2F2、3C8、3FC1、7C6、10HD4和13G4.经血凝抑制试验法分析,结果发现这6株单抗具有特异性高、反应性强、识别谱宽且互补等特点.基于单抗2F2,初步建立了三种H5N1病毒诊断方法,经评估证实均具有很好的特异性.由此说明,研究制备的抗H5亚型禽流感病毒血凝素单抗可适用于H5N1病毒的诊断.     

Functional Mapping of Bluetongue Virus Proteins and Their Interactions with Host Proteins During Virus Replication

Bluetongue virus (BTV) is a double-stranded RNA (dsRNA) virus which is transmitted by blood-feeding gnats to wild and domestic ruminants, causing high morbidity and often high mortality. Partly due to this BTV has been in the forefront of molecular studies for last three decades and now represents one of the best understood viruses at the molecular and structural levels. BTV, like the other members of the Reoviridae family is a complex non-enveloped virus with seven structural proteins and a RNA genome consisting of 10 dsRNA segments of different sizes. In virus infected cells, three other virus encoded nonstructural proteins are synthesized. Significant recent advances have been made in understanding the structure–function relationships of BTV proteins and their interactions during virus assembly. By combining structural and molecular data it has been possible to make progress on the fundamental mechanisms used by the virus to invade, replicate in, and escape from, susceptible host cells. Data obtained from studies over a number of years have defined the key players in BTV entry, replication, assembly and egress. Specifically, it has been possible to determine the complex nature of the virion through three dimensional structure reconstructions; atomic structure of proteins and the internal capsid; the definition of the virus encoded enzymes required for RNA replication; the ordered assembly of the capsid shell and the protein sequestration required for it; and the role of three NS proteins in virus replication, assembly and release. Overall, this review demonstrates that the integration of structural, biochemical and molecular data is necessary to fully understand the assembly and replication of this complex RNA virus.     

Virus Excretion from Foot-And-Mouth Disease Virus Carrier Cattle and Their Potential Role in Causing New Outbreaks

The role of foot-and-mouth disease virus (FMDV) carrier cattle in causing new outbreaks is still a matter of debate and it is important to find out these carrier animals by post-outbreak serosurveillance to declare freedom from FMDV infection. In this study we explore the differences in viral shedding between carrier and non-carrier animals, quantify the transmission rate of FMDV infection from carriers to susceptible animals and identify potential viral determinants of viral persistence. We collected nasal and saliva samples from 32 vaccinated and 7 unvaccinated FMDV carrier cattle and 48 vaccinated and 13 unvaccinated non-carrier cattle (total n=100) during the acute phase of infection (up to 28 days post-challenge) and then from limited number of animals up to a maximum 168 days post-challenge. We demonstrate that unvaccinated cattle excrete significantly higher levels of virus for longer periods compared with vaccinated cattle and this is independent of whether or not they subsequently become carriers. By introducing naïve cattle in to the FMDV carrier population we show the risk of new outbreaks is clearly very low in controlled conditions, although there could still be a potential threat of these carrier animals causing new outbreaks in the field situation. Finally, we compared the complete genome sequences of viruses from carrier cattle with the challenge virus and found no evidence for viral determinants of the carrier state.     

Some Surface-Active Agents and Their Virucidal Effect on Foot-and-Mouth Disease Virus

Selected cationic and anionic surface-active compounds were tested to determine their virucidal effect on the foot-and-mouth disease virus, type O, strain M11, propagated in primary calf kidney cells. The chemical inactivation of the virus was tested with 0.5, 1.0, 2.0, and 5.0% concentrations of the selected compounds. Virus controls with pH adjusted to cover the expected range of the mixtures of the chemicals and virus were also tested. The absence of virus from the mixtures of chemical and virus after reaction at 28 C for 2 hr was assayed by inoculating suckling mice with the mixtures. One cationic compound, alkyl methyl isoquinilinium chloride, showed considerable antiviral activity due largely to pH effect. The use of the surface-active agents investigated in this study, in the presence of organic material, would not be recommended as virucides.     

柑橘衰退病毒多克隆和单克隆抗体的制备及检测效果分析

通过改进提纯方法获得了柑橘衰退病毒(Citrustristezavirus,CTV)的提纯液,其产量为1mg/100g植物组织。用CTV免疫大耳白兔,获得多克隆抗体,间接ELISA效价为1∶25600。用CTV免疫小鼠,经细胞融合、ELISA筛选和克隆化培养,获得18株能稳定分泌抗CTV单克隆抗体的杂交瘤单细胞株。对其中4株单克隆腹水抗体进行分析的结果表明,这些抗体的ELISA效价为1∶51200~1∶204800,其中2G和3H的抗体类型及亚类为IgG2a,1E和4H为IgG2b。用所制备抗体对不同来源柑橘样品的CTV检测结果显示,单克隆和多克隆抗体结合使用,采用三抗体夹心ELISA(TAS-ELISA)可以获得理想的检测效果,其特异性强、灵敏度高。同时发现所分析4株单克隆抗体对不同的CTV分离物鉴别能力存在差异,但有关这些CTV分离物的特性及其血清学关系还需进一步研究。     

Live Chimeric and Inactivated Japanese Encephalitis Virus Vaccines Differ in Their Cross-Protective Values against Murray Valley Encephalitis Virus

The Japanese encephalitis virus (JEV) serocomplex, which also includes Murray Valley encephalitis virus (MVEV), is a group of antigenically closely related, mosquito-borne flaviviruses that are responsible for severe encephalitic disease in humans. While vaccines against the prominent members of this serocomplex are available or under development, it is unlikely that they will be produced specifically against those viruses which cause less-frequent disease, such as MVEV. Here we have evaluated the cross-protective values of an inactivated JEV vaccine (JE-VAX) and a live chimeric JEV vaccine (ChimeriVax-JE) against MVEV in two mouse models of flaviviral encephalitis. We show that (i) a three-dose vaccination schedule with JE-VAX provides cross-protective immunity, albeit only partial in the more severe challenge model; (ii) a single dose of ChimeriVax-JE gives complete protection in both challenge models; (iii) the cross-protective immunity elicited with ChimeriVax-JE is durable (≥5 months) and broad (also giving protection against West Nile virus); (iv) humoral and cellular immunities elicited with ChimeriVax-JE contribute to protection against lethal challenge with MVEV; (v) ChimeriVax-JE remains fully attenuated in immunodeficient mice lacking type I and type II interferon responses; and (vi) immunization with JE-VAX, but not ChimeriVax-JE, can prime heterologous infection enhancement in recipients of vaccination on a low-dose schedule, designed to mimic vaccine failure or waning of vaccine-induced immunity. Our results suggest that the live chimeric JEV vaccine will protect against other viruses belonging to the JEV serocomplex, consistent with the observation of cross-protection following live virus infections.Murray Valley encephalitis virus (MVEV) is a mosquito-borne flavivirus belonging to the Japanese encephalitis virus (JEV) serocomplex which can cause severe, sometimes fatal, disease in humans (reviewed in references 30, 31, 32, and 42). The virus is endemic in northern Australia and Papua New Guinea, where it causes a small number of human cases of encephalitis in most years. In symptomatic patients the case fatality rate is ∼20%, and among those who recover a large number (∼50%) will suffer from neuropsychiatric sequelae. Cases of Murray Valley encephalitis are more common in children or visitors in areas of endemic disease than in adult residents, who have preexisting immunity (7, 42, 46). Sporadically, MVEV spreads to central or southern regions of Australia (e.g., the Murray Valley of southeastern Australia) and causes epidemic viral encephalitis in humans (32). There are no vaccines or antiviral agents available against MVEV, and given the relatively small number of human cases, it is unlikely that a MVEV-specific vaccine for human use will be produced. However, it has been known for many years that at least in animal models, live viral infection with other members of the JEV serocomplex will give cross-protective immunity against heterologous viruses belonging to this group (10, 17, 33, 48, 52). MVEV is genetically and antigenically closely related to JEV (82% amino acid sequence identity in the envelope [E] protein), the most important encephalitic flavivirus in terms of human disease incidence and severity (reviewed in reference 4). A number of live and inactivated JEV vaccines have been licensed or are under development (reviewed in references 2, 16, and 34). If effective and long-lasting cross-protective immunity against MVEV was induced by one of the JEV vaccines, a strong case could be made for its prophylactic use in populations at risk of MVEV infection in Australia. A further reason for investigating the suitability of JEV vaccines in the Australian context is the recent emergence of JEV in northern Australia (18, 19, 41). This has raised the prospect that JEV may become established in enzootic cycles on the Australian mainland, necessitating the use of JEV vaccines in regions where MVEV is also endemic. The impact of MVEV infection in JEV vaccine recipients in terms of disease outcome remains unknown.In contrast to its protective value against heterologous flaviviruses, cross-reactive flavivirus immunity has also been associated with infection- and/or disease-enhancing consequences in natural and laboratory settings (1, 9, 20, 39). Antibody-dependent enhancement of infection is thought to account for the more severe forms of dengue sometimes associated with secondary, heterologous dengue virus infections by a mechanism putatively involving the increased uptake of virus bound with nonneutralizing antibody into Fc receptor-bearing cells (14, 15). For the MVEV/JEV pair, it has been reported that transfer of subneutralizing concentrations of JEV-immune serum or sera from mice suboptimally immunized with inactivated JEV vaccine (JE-VAX; Biken, Japan) can prime recipient mice for a more severe disease when challenged with MVEV (3, 50). We have demonstrated this potentially detrimental effect for the first time in the context of the full complement of the vaccine-primed immune response: the administration of an experimental UV-inactivated MVEV vaccine at a suboptimal dose greatly increased the susceptibility of mice (up to 75% mortality) to challenge with a dose of JEV, which was sublethal in unvaccinated animals (29). It is not clear if this phenomenon is an inherent property of inactivated vaccines, which provide relatively poor immunity in terms of quality, magnitude, and duration in comparison to live virus infections. Here we investigate the protective value and risk of disease potentiation of a recombinant, live JEV vaccine candidate (ChimeriVax-JE) and a licensed, inactivated JEV vaccine (JE-VAX) in mouse models of MVEV and West Nile virus (WNV) encephalitis. ChimeriVax-JE is constructed from yellow fever virus 17D vaccine cDNA by replacement of the viral structural prM and E proteins with those of an attenuated JEV strain; it has been shown to protect mice and monkeys from JEV challenge (12, 36) and has undergone phase 2 and phase 3 trials for safety and efficacy in humans (35, 37).     

Cell Fusion by Various Strains of Newcastle Disease Virus and Their Virulence

Some properties of eight strains of Newcastle disease virus (cell-fusing ability, hemolysin, heat stability of hemagglutinin or of hemolysin) do not correlate with virulence of these strains.