马传染性贫血病毒基因组部分转录图谱

以马传贫驴白细胞弱毒和驴强毒分别接种培养细胞和试验动物,分别在体外和体内条件,对病毒的各种转录产物进行克隆和序列分析。通过与病毒基因组的序列进行比较,用实验的方法绘制出了两株病毒在相应试验条件件下的转录图谱,确定了各拼接产物的外显子构成以及拼接供体和拼接受体位点的具体位置。发现两种病毒在外显子－3的上游拼接受体位点（SA2）的位置与已报道的EIAV毒株均不相同,且二者的拼接信号不一致。     

马传染性贫血病毒驴白细胞弱毒疫苗株及其亲本驴强毒株长末端重复序列(LTR)的启动子活性比较

将马传染性贫血病毒驴强毒(donkey-adapted equine infectious anemia virus,D-A EIAV)、马传染性贫血病毒驴白细胞弱毒(donkey leukocyte attenuated EIAV,DLA EIAV)及EIAV Wyoming株的全长长末端重复序列(LTR)分别克隆到报告基因载体pCAT-Basic vector中,获得重组质粒p-D-A-LTR-CAT、p-DLA-LTR-CAT及p-Wyo-LTR-CAT.将这3个重组质粒分别体外转染EIAV阴性健康驴的白细胞,比较这三者LTR启动报告基因CAT表达的基础活性和在tat-pcDNA3共转染条件下激活活性的差异.结果表明:在驴白细胞中,DLA EIAV LTR启动CAT表达的活性略高于D-A EIAV LTR;而与EIAV Wyoming株LTR比较,DLA EIAV与D-A EIAV二者LTR启动CAT表达的活性都较低.在有共转染重组表达质粒tat-pcDNA3条件下,D-A EIAV、DLA EIAV及EIAV Wyoming株LTR起始CAT表达的活性都得到提高,分别提高了4.8倍、6.0倍和3.2倍.上述结果提示,LTR可能是体现DLA EIAV驴白细胞适应性的因素,不一定是影响其毒力减弱的根本原因.     

中国株EIAV S2基因逆向突变感染性克隆的构建及体外感染性评价

以中国株EIAV的驴强毒株EIAVDV115与疫苗株EIAVFDDV15的S2基因变化规律为依据,利用反向遗传技术对EIAV弱毒疫苗株全基因组感染性克隆pFDDV3-8的S2基因区进行逆向突变,构建了含有强毒株EIAVDV115S2基因区内4个稳定点突变的克隆质粒pFDDVS2r1-3-4-5,将该质粒转染FDD后进行体外继代盲传,经RT-PCR、逆转录酶活性、间接免疫荧光等检测后,显示经EIAV克隆质粒pFDDVS2r1-3-4-5转染的FDD盲传3代后,可在转染的FDD细胞培养物的上清液中检测到EIAV逆转录酶活性;该细胞培养物经RT-PCR和间接免疫荧光检测均呈EIAV阳性;在电镜下可观察到典型EIAV粒子。证明已成功拯救经EIAVS2基因逆向突变后的衍生病毒vpFDDVS2r1-3-4-5。比较vpFDDVS2r1-3-4-5衍生病毒与亲本克隆衍生病毒的复制动力学,表明前者的复制比后者略滞后。以上结果提示,对疫苗株S2基因的突变未明显影响EIAV的体外复制。     

马传染性贫血强/弱毒嵌合病毒的体外构建

马传染性贫血病毒(equine infectious anemia virus,EIAV)引起马传染性贫血(简称马传贫),导致马持续性感染和反复病毒血症[1].EIAV与人免疫缺陷病毒Ⅰ型(HIV-1)同属反转录病毒科慢病毒属,二者有很多相似的特性[2].在反转录病毒前病毒基因组两端含有长末端重复序列(long terminal repeat,LTR).LTR含有真核启动子,其中含有病毒转录调控顺式作用位点,病毒编码的反式作用因子与其结合后可以反式激活基因的表达,对病毒基因的表达和其它生命活动起重要调控作用[3,4].因此,LTR序列的变异可能会引起病毒转录和复制方式的改变,进而引起其细胞嗜性和致病性的改变[5,6].为了探讨LTR在EIAV病毒复制和转录过程中的作用,并进一步研究EIAV的致病和免疫机制,用EIAV强毒L株LTR置换了以前构建的EIAV DLA(弱毒)感染性分子克隆中的LTR,构建了马传贫强/弱毒嵌合分子克隆,并获得了具有感染性的强/弱毒嵌合病毒.     

马传染性贫血病毒强、弱毒株dUTPase结构与酶活性比较

为研究尿嘧啶脱氧核糖核苷三磷酸酶(dUTPase)在马传染性贫血病毒(equine infectous anemia virus,EIAV)致弱过程中的作用,探索dUTPase结构与功能的关系,分别对EIAV强、弱毒株dUTPase的编码基因进行了结构分析,并在大肠杆菌中进行了表达.经镍-次氮基三乙酸(Ni-NTA)金属亲合层析方法对表达产物纯化后,用3H标记底物的方法测定了重组强、弱毒株dUTPase的活性.证明所表达的两种重组dUTPase均具有水解dUTP的功能,但重组弱毒株dUTPase的活性显著高于重组强毒株dUTPase的活性.结果提示,由于EIAV疫苗株在驴白细胞上连续传代培养,使病毒dUTPase的活性增强和复制能力提高,而决定酶活性改变的分子基础是dUTPase编码基因中的两个氨基酸发生了突变.此结果对其它慢病毒病的免疫预防具有重要参考价值.     

表达马传染性贫血病毒受体和荧光素酶报告基因的293细胞系的建立

为了在体外精确、简便地测定马传染性贫血病毒(EIAV)的中和抗体和研究不同毒株与受体的亲和性,克隆了马慢病毒受体1(ELR1)cDNA并插入真核表达载体pcDNA3.1( ),构建了表达载体pELR1。该载体瞬时转染293细胞后,经Western blot和间接免疫荧光(IFA)检测,确认了ELR1的表达。在pELR1质粒的基础上,插入EIAV疫苗株前病毒基因组转录调控区LTR以及萤火虫荧光素酶报告基因(Luc)构建了表达载体pELR1-LTR-Luc,并转染293细胞,建立了ELR1-LTR-Luc(293-E)细胞系。该细胞系能稳定表达ELR1基因,并且能在LTR的调控下表达萤火虫荧光素酶基因。用1000TCID50的EIAV驴胎皮肤细胞疫苗株D18V13接种该细胞,24h后检测其荧光素酶活性是未接毒对照的3.15倍。同时用IFA检测证明了病毒在细胞内的增殖。EIAV强毒株L21的接毒试验显示,ELR1-LTR(293-E)细胞的萤火虫荧光素酶活性与该毒株的接毒量在10-2~10-7稀释范围内呈正相关。该细胞系传35代后,外源基因的表达特征未发生改变。该细胞系的建立为进一步开展EIAV与细胞受体相互作用以及中和抗体评价等研究奠定了重要基础。     

EIAV env基因在痘苗病毒中的表达及其免疫效果的观察

将马传贫驴白细胞弱毒疫苗及其亲本株env基因克隆到痘苗病毒表达载体pSC65的pE/L启动子下游,通过同源重组插入到痘苗病毒天坛株基因组TK区,经蓝白斑筛选获得重组痘苗病毒rvv-DLVenv和rvv-LNenv,Western blot检测目的蛋白的表达,结果表明重组痘苗病毒能够有效表达完整的EIAV Env蛋白,其肌肉接种免疫小鼠后,表达的目的蛋白具有良好的免疫原性,能够诱导机体产生有效的体液和细胞免疫应答,其中以细胞免疫效果更为显著,CTL特异性裂解最高可达28%.本研究为EIAV基因工程疫苗的开发研制奠定了基础.     

EIAV env基因在痘苗病毒中的表达及其免疫效果的观察

将马传贫驴白细胞弱毒疫苗及其亲本株env基因克隆到痘苗病毒表达载体pSC65的pE／L启动子下游,通过同源重组插入到痘苗病毒天坛株基因组TK区,经蓝白斑筛选获得重组痘苗病毒rvv—DINenv和rvv—LNenv,Westem blot检测目的蛋白的表达,结果表明重组痘苗病毒能够有效表达完整的EIAV Env蛋白,其肌肉接种免疫小鼠后,表达的目的蛋白具有良好的免疫原性,能够诱导机体产生有效的体液和细胞免疫应答,其中以细胞免疫效果更为显著,CTL特异性裂解最高可达28％。本研究为EIAV基因工程疫苗的开发研制奠定了基础。     

马传染性贫血病毒驴白细胞弱毒疫苗株及其亲本强毒株前病毒核苷酸序列比较分析

以马传染性贫血病毒驴白细胞弱毒疫苗株(DLA-EIAV)感染细胞总DNA及其亲本强毒L株感染马外周血液白细胞中DNA为模板, 应用PCR方法分段扩增出DLA-EIAV和L株前病毒, 并将各段扩增产物克隆后进行测序. 根据国外发表的马传染性贫血病毒核苷酸序列, 推导出DLA-EIAV和L株全基因组核苷酸序列, 经比较分析, DLA-EIAV株前病毒基因组全长8266个碱基, EIAV L株前病毒基因组共有8235个碱基. DLA-EIAV株与其亲本L株和DA株核苷酸序列相比, 同源率分别为97.0%和 97.5%. DLA-EIAV株和L株相比, 长末端重复序列(LTR, 由U3, R, U5组成)、编码囊膜糖蛋白的基因env及ORF S2变异率很高, U3, R, U5, env及ORF S2核苷酸序列差异率分别达13.2%, 7.5%, 5.1%, 2.7%和3.9%, env基因及ORF S2推导的氨基酸序列差异率分别为4.4%和8.8%. 从EIAV高度变异的env各个毒株中鉴定出6个氨基酸序列保守区, 并发现中国的EIAV强、弱毒增强子区有转录因子GATA结合一致序列. 序列比较发现EIAV L比DLA株多2个N连接糖化位点. DLA-EIAV, L和DA株在ENH的主要差别是, DLA-EIAV株含有转录因子bHLH作用一致序列. 另外, DLA-EIAV株TAR茎的起始部位发生了改变, 形成一个尿嘧啶小泡. 这些变异对EIAV毒力的影响有待进一步研究.     

马传染性贫血病毒N-连接糖基化回复突变的感染性克隆构建

根据马传贫强毒株EIAV-L和疫苗株EIAV-FDD表面蛋白gp90的N-连接糖基化的变化规律,采用PCR定点突变的方法,对全长感染性克隆pLGFD3-8上的N-连接糖基化的差异区域进行改造后,构建成含有3个N-连接糖基化位点突变的感染性克隆pLGNl91N236N246.将其转染驴胎皮肤细胞(FDD),通过用逆转录酶活性、间接免疫荧光和RT-PCR方法检测而确定其感染性.结果表明,在FDD细胞中盲传三代后,在细胞培养物中可检测到逆转录酶活性,RT-PCR和间接免疫荧光检测均呈阳性,电镜下见到典型的EIAV颗粒.这一结果可能对N-连接糖基化在我国马传贫弱毒疫苗致弱机理的作用研究而奠定良好的基础.     

马传染性贫血病毒驴白细胞弱毒疫苗gag基因的序列测定及分析

以马传染性贫血病毒（ＥＬＡＶ）驴白细胞弱毒疫苗株（ＤＬＡ）病毒基因组ＲＮＡ为材料,用ＲＴ－ＰＣＲ方法扩增出ＥＩＡＶ ｇａｇ基因,以平端针其克隆到质粒载体ｐＵＣ１９中,由于疫苗不是克隆株,因此通过５次单独克隆与测序,推导出ＥＩＡＶ－ＤＬＡ ｇａｇ基因的优势序列。ｇａｇ基因全长１４５８个碱基,编码一４８６个氨基酸残基的前体蛋白。与美国ＥＩＡＶ Ｗｙｏｍｉｎｇ１３６９株比较,核苷酸同源性为８０％,氨基酸     

Biological Characterization of Rev Variation in Equine Infectious Anemia Virus

Sequence analysis identified significant variation in the second exon of equine infectious anemia virus (EIAV) rev. Functional analysis indicated that limited amino acid variation in Rev significantly altered the export activity of the protein but did not affect Rev-dependent alternative splicing. EIAV Rev can mediate export through two independent cis-acting Rev-responsive elements (RREs), and differences among Rev variants were more pronounced when both RREs were present. Variation in Rev may be an important mechanism for regulation of virus replication in vivo and may contribute to changes in clinical disease.     

The surface envelope protein gene region of equine infectious anemia virus is not an important determinant of tropism in vitro.

Virulent, wild-type equine infectious anemia virus (EIAV) is restricted in one or more early steps in replication in equine skin fibroblast cells compared with cell culture-adapted virus, which is fully competent for replication in this cell type. We compared the sequences of wild-type EIAV and a full-length infectious proviral clone of the cell culture-adapted EIAV and found that the genomes were relatively well conserved with the exception of the envelope gene region, which showed extensive sequence differences. We therefore constructed several wild-type and cell culture-adapted virus chimeras to examine the role of the envelope gene in replication in different cell types in vitro. Unlike wild-type virus, which is restricted by an early event(s) for replication in equine dermis cells, the wild-type outer envelope gene chimeras are replication competent in this cell type. We conclude that even though there are extensive sequence differences between wild-type and cell culture-adapted viruses in the surface envelope gene region, this domain is not a determinant of the differing in vitro cell tropisms.     

Development of photoreceptor-specific promoters and their utility to investigate EIAV lentiviral vector mediated gene transfer to photoreceptors

BACKGROUND: We wanted to investigate the ability of recombinant equine infectious anemia virus (EIAV) vectors to transduce photoreceptor cells by developing a series of photoreceptor-specific promoters that drive strong gene expression in photoreceptor cells. METHODS: Promoter fragments derived from the rhodopsin (RHO), the beta phosphodiesterase (PDE) and the retinitis pigmentosa (RP1) genes were cloned in combination with an enhancer element, derived from the interphotoreceptor retinoid-binding protein gene (IRBP), into luciferase reporter plasmids. An in vitro transient reporter assay was carried out in the human Y-79 retinoblastoma cell line. The optimal promoters from this screen were then cloned into the recombinant EIAV vector for evaluation in vivo following subretinal delivery into mice. RESULTS: All promoters maintained a photoreceptor-specific expression profile in vitro and the gene expression was further enhanced in combination with the IRBP enhancer. The use of IRBP-combined RHO or PDE promoters showed modest but exclusive expression in photoreceptors following subretinal delivery to mice. By contrast an EIAV vector containing the cytomegalovirus (CMV) promoter drove reporter gene expression in both photoreceptors and retinal pigment epithelium. CONCLUSIONS: It may be possible to use recombinant EIAV vectors containing photoreceptor-specific promoters to drive therapeutic gene expression to treat a range of retinal degenerative diseases where the photoreceptor cell is the primary disease target.     

The open reading frame ORF S3 of equine infectious anemia virus is expressed during the viral life cycle.

The genome of equine infectious anemia virus (EIAV) contains several small open reading frames (ORFs), the importance of which in the development of the virus is not clear. We investigated the possibility that the largest of these ORFs (ORF S3) is expressed during the course of the viral infection. The ORF S3 information was expressed in Escherichia coli, and the antigen was used to raise monospecific antiserum. A 20-kDa protein expressed in cells producing EIAV was identified as the gene product of ORF S3. Furthermore, sera from EIAV-infected animals specifically recognized this protein, indicating that the ORF S3 antigen is expressed in vivo as well. A model for the expression of this new viral antigen is presented. The proposed splicing pattern is similar to that of the VEP-1 protein of maedi-visna-virus, which tempts us to speculate that ORF S3 defines the second exon of the EIAV Rev protein.     

Replication of Equine Infectious Anemia Virus in Engineered Mouse NIH 3T3 Cells

We employed the equine lentivirus equine infectious anemia virus (EIAV) to investigate the cellular restrictions for lentivirus replication in murine NIH 3T3 cells. The results of these studies demonstrate that NIH 3T3 cells expressing the EIAV receptor ELR1 and equine cyclin T1 supported productive replication of EIAV and produced infectious virions at levels similar to those found in a reference permissive equine cell line. The studies presented here demonstrate, for the first time, differential levels of restriction for EIAV and human immunodeficiency virus type 1 (HIV-1) replication in murine cells and suggest that these differences can be exploited to reveal critical virus-cell interactions required for HIV-1 assembly and budding of lentivirus particles.