犬Ⅰ型腺病毒DNA的酶切分析及分子克隆

犬Ⅰ型腺病毒(CAV-1)弱毒用限制性内切酶EcoR Ⅰ,BamH Ⅰ,Pst Ⅰ,Sph Ⅰ和Hind Ⅲ消化分析后其图谱与强毒株相比没有差异。将弱毒DNA用Pst Ⅰ完全消化后以鸟枪法克隆到载体质粒pBluescrip'SK中,经用光生物素标记的CAV-1 DNA杂交筛选以及Pst Ⅰ分析重组质粒证明已将分子量为5.5,3.5,2.85,1.2,0.32和0.28Kb的CAV-1DNA片段克隆到质粒中。克隆到的这些片段将可考虑进一步研究作为探针检测犬及狐狸等野生动物的腺病毒感染。     

抗传染性犬肝炎病毒单克隆抗体的制备及鉴定

目的制备传染性犬肝炎病毒单克隆抗体。方法将用纯化的犬腺病毒1型（CAV-1）免疫的BALB／c小鼠脾细胞与SP2／0细胞在聚乙二醇作用下融合,通过酶联免疫吸附试验（ELISA）和免疫酶试验（1EA）筛选,以有限稀释法克隆3次,制备单克隆抗体,并对制备完成的单克隆抗体进行生物学鉴定。结果成功得到2株能稳定分泌抗CAV-1的单克隆抗体杂交瘤细胞,命名为1B、2H3,经鉴定其亚型分别为IgG2a和IgG2a,2株均为kappa链。腹水的ELISA效价可达10^7-10^8,IEA效价可达1：2560—1：5120。该单克隆抗体与CPV、CDV、FPV、CCV病毒无交叉反应。结论成功制备了抗CAV-1单克隆抗体,为进一步建立相关诊断方法奠定了基础。     

犬冠状病毒S糖蛋白基因重组犬2型腺病毒的构建及其免疫原性研究

首次构建了能表达犬冠状病毒纤突糖蛋白(CCVS1)的重组犬2型腺病毒(CAV-2)。用RT-PCR方法从CCVDXMV株细胞培养物中扩增出编码S糖蛋白A、B、C和D4个抗原位点的基因片段S1,将其克隆到pVAX1中,然后将含有CCVS1基因的完整表达盒(CMV-S1-PolyA)进一步定向克隆到含有CAV-2E3区的穿梭质粒pVAXE3中,构建出pVAX△E3S1。通过SalⅠ NruⅠ双酶切pVAX△E3S1回收含有目的基因的表达盒,将其克隆入含有CAV-2全基因组的骨架质粒pPoly2-CAV-2中,获得重组质粒pCAV-2-CCV-S1。ClaⅠ AscⅠ酶切pCAV-2-CCV-S1释放重组基因组,转染MDCK细胞,获得了重组病毒CAV-2-S1。该重组病毒在MDCK细胞上能产生典型的腺病毒细胞病变。通过mRNA水平和Westernblot检测,证实重组病毒能表达CCVS1蛋白。动物免疫试验表明,该重组病毒可以有效地诱导免疫犬产生抗CCV和CAV-2抗体。     

犬2型腺病毒通用载体的构建及鉴定

为了获得能够携带较大外源基因的犬2型腺病毒E3区缺失性载体,以犬2型腺病毒全基因组质粒pPolyⅡ-CAV-2及E3区重组质粒pVAX-E3为基础,缺失1381bp的E3区片段(92.6%的E3区全序列),插入Linker-NF(内含NotⅠ、ClaⅠ、FseⅠ多克隆位点),获得重组载体质粒pPolyⅡ-CAV-2-ΔE3（NF）(31.9kb)。以AscⅠ和PmeⅠ双酶切,游离重组基因组,在脂质体Lipofectamine^TM 2000介导下,转染MDCK细胞系,获得了E3区缺失的重组病毒CAV-2-ΔE3（NF）。通过病毒的形态学观察,血凝性、生长特性、感染性实验证明,该重组病毒与母源病毒没有差异。重组病毒CAV-2-ΔE3（NF）可以作为载体表达外源基因,其外源基因插入片段不小于3.3kb。     

犬腺病毒、犬细小病毒联合PCR方法的建立与应用

根据GenBank报道的犬腺病毒(CAV)和犬细小病毒(CPV)序列,设计两对联合PCR引物,其中一对为CAV-1和CAV-2通用引物,另一对为CPV引物。在建立单项PCR基础上,通过优化Mg^2 离子浓度和循环参数等反应条件建立联合PCR,确定联合PCR条件为：96℃180s,96℃230s,56℃30s,72℃280s,30个循环。联合PCR结果显示：CAV—l扩增片段大小为497bp,CAV-2为l019hp,CPV为719hp;细胞和其它相关病毒对照均无扩增带。上述PCR产物经用限制性内切酶酶切和克隆测序,结果均与相应病毒的应有条带和序列相同。敏感性比较试验结果表明。联合PCR比用细胞培养分离病毒敏感。将联合PCR应用于15份CAV和CPV细胞培养物,5份CAV-1、1份CAV-2和3份CPV人工感染犬病料以及30份临床病料检测,并与电镜负染、HA／HI及病毒分离等方法的结果进行比较,结果显示,联合PCR的检出率和病毒分离结果一致,高于电镜负染和HA／HI试验。以上结果说明：CAV-1／12AV-2和CPV联合PCR不仅具有很好的特异性和敏感性,而且可以在短时间内(2．5h～3h)同时鉴定出上述三种病毒。因此具有良好的实验室诊断和临床应用价值。     

表达猫瘟热病毒VP2蛋白重组腺病毒的构建及其免疫原性研究

为构建能表达FPV VP2蛋白的重组犬2型腺病毒(CAV-2)载体。首先用PCR方法从FPV GT-2株细胞培 养物中扩增出了VP2蛋白基因,将其克隆到真核表达质粒pVAX1中构建了含有FPV vp2基因的表达盒(CMV- VP2-PolyA),将该表达盒酶切后定向克隆到含有CAV-2 E3区的穿梭质粒pVAX△E3中,构建出pVAX △E3VP2。用Sal I Nru I双酶切pVAX△E3VP2,回收含有目的基因表达盒部分,将其定向克隆入含有CAV-2 全基因组的骨架质粒pPoly2-CAV-2中,构建了重组质粒pCAV-2-FPV-VP2。Cla I Asc I酶切pCAV-2-FPV- VP2释放出重组基因组,以此转染MDCK细胞,获得了重组病毒CAV-2-VP2。该重组病毒能使MDCK细胞产生 腺病毒样细胞病变。Western blot检测证实,该重组病毒能表达具有免疫学活性的VP2蛋白。该重组病毒可以有 效地诱导免疫猫产生抗FPV和CAV-2抗体。本实验表明该重组病毒有可能成为一个FPV的疫苗株。     

表达猫瘟热病毒VP2蛋白重组腺病毒的构建及其免疫原性研究

为构建能表达FPV VP2蛋白的重组犬2型腺病毒(CAV-2)载体.首先用PCR方法从FPV GT-2株细胞培养物中扩增出了VP2蛋白基因,将其克隆到真核表达质粒pVAX1中构建了含有FPV vp2基因的表达盒(CMV-VP2-PolyA),将该表达盒酶切后定向克隆到含有CAV-2 E3区的穿梭质粒pVAX△E3中,构建出pVAX△E3VP2.用Sal I+Nru I双酶切pVAX△E3VP2,回收含有目的基因表达盒部分,将其定向克隆入含有CAV-2全基因组的骨架质粒pPoly2-CAV-2中,构建了重组质粒pCAV-2-FPV-VP2.Cla I+Asc I酶切pCAV-2-FPV-VP2释放出重组基因组,以此转染MDCK细胞,获得了重组病毒CAV-2-VP2.该重组病毒能使MDCK细胞产生腺病毒样细胞病变.Western blot检测证实,该重组病毒能表达具有免疫学活性的VP2蛋白.该重组病毒可以有效地诱导免疫猫产生抗FPV和CAV-2抗体.本实验表明该重组病毒有可能成为一个FPV的疫苗株.     

表达狂犬病病毒糖蛋白的重组犬2型腺病毒的构建

本试验以犬2型腺病毒全基因组重组质粒pPolyⅡ-CAV-2及其E3区重组质粒pVAX-E3为基础,通过DraⅢ和SspⅠ双酶切,缺失第25097bp-26141bp共1044bp的E3区片段,按与编码链相同转录方向插入由CMV启动子、狂犬病病毒SRV\-9株糖蛋白基因、SV40 polyA基因构成的总长2424bp的表达盒,获得重组基因组质粒pPolyⅡ-CAV-2-CGS(34.7kb).以AscⅠ和ClaⅠ双酶切,游离重组基因组(32.7kb),在脂质体Lipofectamine TM 2000介导下,转染MDCK细胞系,获得了E3缺失区携带狂犬病病毒糖蛋白表达盒的重组犬2型腺病毒CAV-2-CGS.Western印迹试验表明,CAV-2-CGS表达了狂犬病病毒糖蛋白.初步接种试验显示,重组病毒可以诱导犬产生狂犬病病毒特异性抗体.     

犬2型腺病毒通用载体的构建及鉴定

为了获得能够携带较大外源基因的犬2型腺病毒E3区缺失性载体,以犬2型腺病毒全基因组质粒pPolyⅡ-CAV-2及E3区重组质粒pVAX-E3为基础,缺失1381bp的E3区片段(92.6%的E3区全序列),插入Linker-NF(内含NotⅠ、ClaⅠ、FseⅠ多克隆位点),获得重组载体质粒pPolyⅡ-CAV-2-ΔE3(NF)(31.9kb)。以AscⅠ和PmeⅠ双酶切,游离重组基因组,在脂质体LipofectamineTM2000介导下,转染MDCK细胞系,获得了E3区缺失的重组病毒CAV-2-ΔE3(NF)。通过病毒的形态学观察,血凝性、生长特性、感染性实验证明,该重组病毒与母源病毒没有差异。重组病毒CAV-2-ΔE3(NF)可以作为载体表达外源基因,其外源基因插入片段不小于3.3kb。     

A serologic survey for antibodies to three canine viruses in wolverines (Gulo gulo) from the Brooks Range, Alaska

Canine distemper virus (CDV), canine parvovirus type 2 (CPV-2), and canine adenovirus type 1 (CAV-1) are pathogens that are typically associated with canids but may cause serious disease in a wide range of other carnivores. From 1998 to 2002, serum samples from 64 wolverines (Gulo gulo) from the Brooks Range, Alaska, were tested for antibodies to CDV, CPV-2, and canine adenovirus (CAV). Four animals tested positive for antibodies to CDV (7%), one for antibodies to CPV-2 (2%), and none for antibodies to CAV. These are similar to antibody prevalence estimates for other large and medium carnivores in North America.     

重组虎源H5N1流感病毒HA基因犬2型腺病毒的构建与实验免疫研究

H5N1流感病毒可以对虎和猫产生致死性感染,为研制可用于预防猫科动物流感的新型疫苗,构建了重组虎源H5N1流感病毒HA基因的犬2型腺病毒。将A/Tiger/Harbin/01/2003(H5N1)的HA基因克隆入pVAX1载体中,然后将含有HA基因的表达盒(CMV HA PolyA)克隆入pVAXΔE3的SSPⅠ酶切缺失处,获得含有HA表达盒的穿梭载体pΔEHA。用SalⅠ NruⅠ分别对pΔEHA和pPoly-2-CAV2进行双酶切,将含有HA表达盒的SalⅠ NruⅠ片段克隆入pPoly2-CAV2,获得了在E3区缺失处插入HA表达盒的重组质粒pCAV-2/HA。释放CAV-2/HA重组基因组转染MDCK细胞,获得了重组活病毒CAV2/HA,经Western blot分析表明重组表达产物可被流感病毒HA单克隆抗体3A13所识别。使用该重组病毒免疫猫可以产生效价为1∶8~1∶16的抗H5亚型流感病毒血凝抑制抗体。     

表达狂犬病毒糖蛋白抗原的重组犬2型腺病毒的构建及鉴定

为研制一种预防犬科动物狂犬病的新型疫苗,将含有狂犬病毒ERA株糖蛋白基因(Rabies glycoprotein,Rgp)表达盒的穿梭质粒pVAXΔE3Rgp中的Rgp表达盒克隆入犬2型腺病毒(Canine adenovirus type2,CAV2)骨架质粒pPoly2-CAV2中,获得重组质粒pPoly2-CAV2-ΔE3-Rgp,释放其基因组,转染MDCK细胞系,获得E3缺失区(Deletion of early protein3,ΔE3)含有Rgp表达盒的重组病毒CAV2-ΔE3-Rgp。该重组病毒能在MDCK细胞上产生典型的腺病毒细胞病变。通过酶切、PCR、基因测序,表明该重组病毒含有完整的Rgp表达盒。通过RT-PCR、Western blot等检测,表明该重组病毒能够表达Rgp抗原。用该重组病毒免疫犬,3次免疫后,可以诱导犬产生特异的抗CAV2HI抗体,其效价超过1∶256和抗狂犬病病毒(Rabies virus,RV)中和抗体,其效价超过0.50IU/mL。试验结果表明,获得的重组病毒免疫犬后,能够产生抗狂犬病毒和腺病毒的高效价保护性抗体,是一种有潜力的犬科动物狂犬病毒腺病毒二联疫苗候选株。     

Patterns of Exposure of Iberian Wolves (<Emphasis Type="Italic">Canis lupus</Emphasis>) to Canine Viruses in Human-Dominated Landscapes

Wildlife inhabiting human-dominated landscapes is at risk of pathogen spill-over from domestic species. With the aim of gaining knowledge in the dynamics of viral infections in Iberian wolves (Canis lupus) living in anthropized landscapes of northern Spain, we analysed between 2010 and 2013 the samples of 54 wolves by serology and polymerase chain reaction (PCR) for exposure to four pathogenic canine viruses: canine distemper virus (CDV), canine parvovirus-2 (CPV), canine adenovirus 1 and 2 (CAV-1 and CAV-2) and canine herpesvirus. Overall, 76% of the studied wolves presented evidence of exposure to CPV (96% by HI, 66% by PCR) and 75% to CAV (75% by virus neutralization (VN), 76% by PCR, of which 70% CAV-1 and 6% CAV-2). This represents the first detection of CAV-2 infection in a wild carnivore. CPV/CAV-1 co-infection occurred in 51% of the wolves. The probability of wolf exposure to CPV was positively and significantly correlated with farm density in a buffer zone around the place where the wolf was found, indicating that rural dogs might be the origin of CPV infecting wolves. CPV and CAV-1 appear to be enzootic in the Iberian wolf population, which is supported by the absence of seasonal and inter-annual variations in the proportion of positive samples detected. However, while CPV may depend on periodical introductions by dogs, CAV-1 may be maintained within the wolf population. All wolves were negative for exposure to CDV (by VN and PCR) and CHV (by PCR). The absence of acquired immunity against CDV in this population may predispose it to an elevated rate of mortality in the event of a distemper spill-over via dogs.     

Canine Adenovirus Type 2 Vector Generation via I-Sce1-Mediated Intracellular Genome Release

When canine adenovirus type 2 (CAdV-2, or also commonly referred to as CAV-2) vectors are injected into the brain parenchyma they preferentially transduce neurons, are capable of efficient axonal transport to afferent regions, and allow transgene expression for at last >1 yr. Yet, translating these data into a user-friendly vector platform has been limited because CAV-2 vector generation is challenging. Generation of E1-deleted adenovirus vectors often requires transfection of linear DNA fragments of >30 kb containing the vector genome into an E1-transcomplementing cell line. In contrast to human adenovirus type 5 vector generation, CAV-2 vector generation is less efficient due, in part, to a reduced ability to initiate replication and poor transfectibility of canine cells with large, linear DNA fragments. To improve CAV-2 vector generation, we generated an E1-transcomplementing cell line expressing the estrogen receptor (ER) fused to I-SceI, a yeast meganuclease, and plasmids containing the I-SceI recognition sites flanking the CAV-2 vector genome. Using transfection of supercoiled plasmid and intracellular genome release via 4-OH-tamoxifen-induced nuclear translocation of I-SceI, we improved CAV-2 vector titers 1,000 fold, and in turn increased the efficacy of CAV-2 vector generation.     

Purification and properties of the hexon antigen of canine adenovirus serotype CAV-1

The main antigen and immunogen of canine adenovirus type 1 (CAV-1) has been purified to near homogeneity from cultural fluid of a CAV-1-infected primary cell culture by hydrophobic and anion-exchange chromatography. The hexon native form (trimer) was shown to be resistant against denaturation by SDS under conditions of SDS-PAGE performed without heating the samples. The monomer chain of the CAV-1 hexon was apparently identical in terms of electrophoretic mobility with that of the previously sequenced BAV-3 hexon polypeptide (103 kDA). In blot enzyme immunoassay only native trimers of CAV-1 hexon were detected by cross-specific polyclonal and monoclonal anti-hexon antibodies.     

不同型犬腺病毒纤突蛋白基因序列的比较分析

根据已发表的ＣＡＶ纤突基因序列,用ＰＣＲ方法,对４个ＣＡＶ－２毒　株和４个ＣＡＶ－１毒株的纤突基因进行了扩增和测序,测定的核苷酸序列经推导得到分别编　码５４３和５４２个氨基酸的ＣＡＶ纤突蛋白全序列。测定的ＣＡＶ－２比较表明：我国流行的ＣＡＶ－２　ＳＹ　强毒株与国外标准强毒株Ｔｏｒｏｎｔｏ　Ａ２６／６１株相同,其驯化致弱的毒株与驯化前相比在１１３４位　发生碱基颠换。测定的ＣＡＶ－１比较表明：我国流行的ＣＡＶ－１株与标准强毒ＲＩ２６１株差异相对　较大,而国内ＣＡＶ－１毒株互相之间相对差别较小。ＣＡＶ－２与ＣＡＶ－１纤突基因的同源性为８０．４８％。     

Structural and mutational analysis of human Ad37 and canine adenovirus 2 fiber heads in complex with the D1 domain of coxsackie and adenovirus receptor

Adenovirus fibers from most serotypes bind the D1 domain of coxsackie and adenovirus receptor (CAR), although the binding residues are not strictly conserved. To understand this further, we determined the crystal structures of canine adenovirus serotype 2 (CAV-2) and the human adenovirus serotype 37 (HAd37) in complex with human CAR D1 at 2.3 and 1.5A resolution, respectively. Structure comparison with the HAd12 fiber head-CAR D1 complex showed that the overall topology of the interaction is conserved but that the interfaces differ in number and identity of interacting residues, shape complementarity, and degree of conformational adaptation. Using surface plasmon resonance, we characterized the binding affinity to CAR D1 of wild type and mutant CAV-2 and HAd37 fiber heads. We found that CAV-2 has the highest affinity but fewest direct interactions, with the reverse being true for HAd37. Moreover, we found that conserved interactions can have a minor contribution, whereas serotype-specific interactions can be essential. These results are discussed in the light of virus evolution and design of adenovirus vectors for gene transfer.     

Production and Purification of Non Replicative Canine Adenovirus Type 2 Derived Vectors

Adenovirus (Ad) derived vectors have been widely used for short or long-term gene transfer, both for gene therapy and vaccine applications. Because of the frequent pre-existing immunity against the classically used human adenovirus type 5, canine adenovirus type 2 (CAV2) has been proposed as an alternative vector for human gene transfer. The well-characterized biology of CAV2, together with its ease of genetic manipulation, offer major advantages, notably for gene transfer into the central nervous system, or for inducing a wide range of protective immune responses, from humoral to cellular immunity. Nowadays, CAV2 represents one of the most appealing nonhuman adenovirus for use as a vaccine vector. This protocol describes a simple method to construct, produce and titer recombinant CAV2 vectors. After cloning the expression cassette of the gene of interest into a shuttle plasmid, the recombinant genomic plasmid is obtained by homologous recombination in the E. coli BJ5183 bacterial strain. The resulting genomic plasmid is then transfected into canine kidney cells expressing the complementing CAV2-E1 genes (DK-E1). A viral amplification enables the production of a large viral stock, which is purified by ultracentrifugation through cesium chloride gradients and desalted by dialysis. The resulting viral suspension routinely has a titer of over 10¹⁰ infectious particles per ml and can be directly administrated in vivo.