非洲猪瘟病毒Georgia 2007/1株CD2v蛋白的原核表达及多克隆抗体制备

本研究旨在通过原核表达系统表达非洲猪瘟病毒(African swine fever virus,ASFV)Georgia 2007/1株EP402R基因,获得其编码的CD2v重组蛋白,并针对纯化的CD2v重组蛋白制备多克隆抗体。将ASFV EP402R全长基因进行密码子优化后连入pET-28a(+)表达载体,构建原核重组表达质粒,经1 mmol/L IPTG于16℃诱导12 h后,利用SDS-PAGE和Western blotting对重组蛋白进行表达鉴定和反应原性分析。以纯化的CD2v重组蛋白为免疫原制备鼠源抗CD2v多克隆抗体,随后以间接ELISA方法、间接免疫荧光试验及Western blotting分别检测多克隆抗体的效价和特异性。结果显示,ASFV EP402R基因克隆至pET-28a(+)获得pET-28a-EP402R重组质粒,转化大肠杆菌BL21(DE3)感受态细胞后经诱导表达获得CD2v重组蛋白,其大小约为47 ku,重组蛋白主要以包涵体形式存在,部分也可以融合表达蛋白形式存在。Western blotting结果显示,其可溶性上清经镍柱纯化后能被ASFV阳性血清识别,具有良好的反应原性。间接ELISA检测该多克隆抗体效价可达1∶512 000,间接免疫荧光试验和Western blotting表明该多克隆抗体可特异性识别真核表达的CD2v蛋白。以上结果表明,通过原核表达的ASFV CD2v重组蛋白具有较好的免疫原性,利用重组蛋白制备的多克隆抗体具有较高的抗体效价和特异性,为进一步研究ASFV EP402R生物学功能及基因缺失毒株的鉴别诊断和疫苗开发提供技术储备。     

猪繁殖与呼吸综合征病毒N蛋白基因的克隆及原核表达

通过RT-PCR技术从细胞毒液中扩增N蛋白cDNA,克隆至原核表达载体pET-28a(+)中,所获得的重组质粒pET-28a-N经酶切鉴定正确后,将其转化入表达菌E.coliBL21plysS诱导表达,用SDS-PAGE与Western blotting对表达产物进行鉴定。结果表明,通过RT-PCR扩增获得长度为372 bp的N蛋白基因,诱导表达重组质粒pET-28a-N,经SDS-PAGE检测,IPTG终浓度为1 mmol/L时,诱导4 h蛋白表达量最高,出现分子质量约为18 ku的目的蛋白带,与N蛋白的理论值相符。经Western blotting检测,该表达产物可与PRRSV阳性血清发生特异性反应。获得的PRRSV N蛋白为建立针对该病毒抗体的间接ELISA检测方法,以及为进一步研发PRRS抗体检测试剂盒奠定了基础。     

非洲猪瘟病毒p30基因的原核表达及间接ELISA抗体检测方法的建立

为建立检测血清中非洲猪瘟病毒(African swine fever virus,ASFV)抗体的间接ELISA方法,本试验将ASFVp30基因进行原核表达,采用SDS-PAGE和Western blotting方法对重组蛋白进行表达鉴定和免疫原性分析,随后以纯化的重组蛋白为包被抗原,经条件优化、特异性试验、敏感性试验和重复性试验,建立一种血清中ASFV抗体的检测方法。结果显示,ASFVp30基因成功克隆到原核表达载体pET-32a(+)中,获得pET-32a-p30重组质粒;转化大肠杆菌BL21(DE3)感受态细胞进行诱导表达,得到P30重组蛋白,重组蛋白大小约为42ku,主要以包涵体形式存在;Western blotting结果显示,纯化后的蛋白具有良好的免疫原性;以纯化的P30重组蛋白为包被抗原,建立了检测ASFV抗体的间接ELISA方法,通过方阵试验对间接ELISA方法进行优化,最终确定了抗原最佳包被浓度为1.2μg/mL,待检血清最佳稀释倍数为1∶100,最佳封闭液为1%BSA,酶标抗体最佳稀释度为1∶4 000,以此建立的ASFV间接ELISA方法临界值为0.322。本方法仅与ASFV阳性血清发生特异性反应,与猪瘟病毒、猪繁殖与呼吸综合征病毒、口蹄疫病毒、伪狂犬病病毒、猪圆环病毒2型及猪流行性腹泻病毒阳性血清均无交叉反应,具有较强的特异性。该方法检测ASFV阳性血清灵敏度可达到1∶1 600;批内重复性和批间重复性变异系数均10%。本试验建立的间接ELISA方法具有良好的特异性、灵敏度和重复性,可初步应用于ASFV抗体的检测。     

鲤春病毒(SVCV)糖蛋白基因的原核表达

通过将鲤春病毒血症病毒(Spring Viremia of Carp Virus,SVCV)糖蛋白(Glycoprotein,G)基因截短后构建重组表达载体,实现体外高效表达G蛋白,为有关原核诱导蛋白提供参考。以质粒pEGFP-G为模板设计引物,分别扩增G基因的不同片段,与密码子优化后的G基因分别插入pET-32a表达载体,构建重组表达载体pET-32a-GX和pET-32a-OG。经过鉴定后,将重组质粒分别转入大肠杆菌BL21(DE3),通过适宜条件的诱导表达,获得诱导产物并进行SDS-PAGE和Western blotting检测。构建了重组表达载体pET-32a-GX与含密码子优化后G基因的重组表达载体pET-32a-OG;经适宜条件诱导表达了G蛋白后的SDS-PAGE和Western Blotting检测,表明G蛋白成功表达,且含截短片段的重组载体pET-32a-G2的蛋白表达量最高,与原G序列有相同的免疫原性。成功构建截短后的原核表达载体pET-32aGX与密码子优化后的重组表达载体pET-32a-GX,并实现体外大量诱导SVCV的G蛋白。     

新型鹅星状病毒ORF2基因的原核表达及多克隆抗体的制备

以新型鹅星状病毒(goose astrovirus, GAstV)ORF2基因为序列设计1对特异性引物,利用PCR方法进行扩增,将其克隆到原核表达载体pET-30a中,转化DH5α感受态细胞,经酶切鉴定及测序后,获得重组质粒pET30a-ORF2。随后转化BL21(DE3)感受态细胞,经IPTG诱导后进行SDS-PAGE和Western blot检测重组蛋白。将鉴定正确的重组蛋白纯化后免疫家兔,制备抗鹅星状病毒衣壳蛋白的多克隆抗体。结果:成功获得ORF2基因,构建的原核表达重组质粒成功表达预期的重组蛋白,大小约84 kDa,且均能与His单抗和鹅阳性血清特异反应。制备的多克隆抗体,Western blot检测能与重组蛋白发生特异性反应,间接免疫荧光试验(IFA)检测也能与新型鹅星状病毒发生特异性反应。本试验结果表明,原核表达的新型鹅星状病毒结构蛋白ORF2及制备的多抗均具有良好的免疫原性和反应原性,为新型鹅星状病毒检测方法的建立及ORF2基因功能研究奠定了基础。     

H9N2亚型禽流感病毒NP蛋白原核表达及多克隆抗体制备

【目的】对华南地区分离到的1株H9N2亚型禽流感病毒(Avian influenza virus,AIV)流行株NP蛋白进行原核表达,制备H9N2亚型AIV NP蛋白多克隆抗体。【方法】将1株H9N2亚型AIV的NP基因克隆至pET-32a(+)原核表达载体,构建NP蛋白原核表达质粒。将重组质粒同时转化大肠杆菌BL21(DE3)和Rosetta(DE3)感受态细胞,经IPTG诱导表达重组蛋白。通过考马斯亮蓝染色和Western blotting分析并比较NP蛋白在两种表达菌中的表达量,进一步优化诱导剂浓度、诱导时间及诱导温度等条件,提高蛋白的表达效率。采用镍柱亲和层析法对NP蛋白进行纯化,用BCA法测定蛋白浓度。以纯化的NP蛋白免疫新西兰大白兔获得多克隆抗体,通过Western blotting和间接免疫荧光对所制备的多克隆抗体进行鉴定,通过间接ELISA测定抗体效价。【结果】试验成功构建pET-32a-H9N2-NP原核表达质粒并表达重组NP蛋白。考马斯亮蓝染色和Western blotting结果均表明,重组NP蛋白在大肠杆菌Rosetta(DE3)感受态细胞中表达水平远高于大肠杆菌BL21(DE3)感受态细胞,其大小约73 ku。诱导条件优化结果显示,重组NP蛋白在37 ℃、IPTG终浓度为1 mmol/L诱导7 h时的表达量最大,且通过镍柱纯化后得到纯度较高的重组蛋白。Western blotting和间接免疫荧光结果均表明,所制备的多克隆抗体能高效地与H9N2亚型AIV发生特异性结合。间接ELISA测得多克隆抗体的效价为1∶409 600。【结论】本研究制备的兔抗NP蛋白多克隆抗体效价较高,表明NP蛋白具有良好的免疫原性,为今后NP蛋白单克隆抗体的制备和ELISA检测方法的建立奠定了基础。     

非洲猪瘟病毒p30基因的原核表达及间接ELISA抗体检测方法的建立

为建立检测血清中非洲猪瘟病毒（African swine fever virus,ASFV）抗体的间接ELISA方法,本试验将ASFV p30基因进行原核表达,采用SDS-PAGE和Western blotting方法对重组蛋白进行表达鉴定和免疫原性分析,随后以纯化的重组蛋白为包被抗原,经条件优化、特异性试验、敏感性试验和重复性试验,建立一种血清中ASFV抗体的检测方法。结果显示,ASFV p30基因成功克隆到原核表达载体pET-32a （+）中,获得pET-32a-p30重组质粒;转化大肠杆菌BL21（DE3）感受态细胞进行诱导表达,得到P30重组蛋白,重组蛋白大小约为42 ku,主要以包涵体形式存在;Western blotting结果显示,纯化后的蛋白具有良好的免疫原性;以纯化的P30重组蛋白为包被抗原,建立了检测ASFV抗体的间接ELISA方法,通过方阵试验对间接ELISA方法进行优化,最终确定了抗原最佳包被浓度为1.2 μg/mL,待检血清最佳稀释倍数为1：100,最佳封闭液为1% BSA,酶标抗体最佳稀释度为1：4 000,以此建立的ASFV间接ELISA方法临界值为0.322。本方法仅与ASFV阳性血清发生特异性反应,与猪瘟病毒、猪繁殖与呼吸综合征病毒、口蹄疫病毒、伪狂犬病病毒、猪圆环病毒2型及猪流行性腹泻病毒阳性血清均无交叉反应,具有较强的特异性。该方法检测ASFV阳性血清灵敏度可达到1：1 600;批内重复性和批间重复性变异系数均<10%。本试验建立的间接ELISA方法具有良好的特异性、灵敏度和重复性,可初步应用于ASFV抗体的检测。     

猪繁殖与呼吸综合征病毒糖基化囊膜蛋白5原核表达载体的构建及免疫原性分析

为分析猪繁殖与呼吸综合征病毒(PRRSV)糖基化囊膜蛋白5（GP5）的免疫原性,本研究通过提取PRRSV分离株（GenBank登录号：HQ701732.1）RNA和RT-PCR扩增得到开放阅读框5（ORF5）基因。根据ORF5的基因序列,设计2对引物,经PCR扩增分别获得不含信号肽和跨膜功能区的2段基因片段。利用酶切位点,将2段基因连接到原核表达载体pET-28a（+）上,获得重组表达质粒pET28a-GP5。将重组质粒导入BL21（DE3）感受态细胞,经IPTG诱导获得表达。经Western blotting鉴定,重组蛋白可被PRRSV阳性血清识别。将纯化的重组蛋白免疫BALB/c小鼠,ELISA方法检测,小鼠能产生针对蛋白的血清抗体。因此,该重组PRRSV GP5蛋白具有良好的生物学活性,为进一步研究GP5蛋白的结构和功能奠定基础。     

扩展莫尼茨绦虫vasa基因的原核表达及多克隆抗体的制备

试验旨在表达、纯化扩展莫尼茨绦虫VASA蛋白,并制备兔抗VASA多克隆抗体。根据扩展莫尼茨绦虫全基因核苷酸序列设计特异性引物,利用PCR方法扩增vasa基因片段;将扩增产物与原核表达载体pET-22b(+)连接,获得重组质粒pET-22b-VASA;经Amp抗性筛选阳性菌,双酶切、PCR测序鉴定后,将其转化大肠杆菌(DE3)感受态细胞中,并进行IPTG诱导表达;重组融合蛋白经镍柱纯化后,进行Western blot鉴定;将融合蛋白免疫兔,制备多克隆抗体。结果显示,重组质粒pET-22b-VASA构建正确,通过IPTG诱导获得大小约32 200的VASA重组融合蛋白;Western blot分析表明其与鼠抗His单克隆抗体呈阳性反应。纯化的VASA蛋白免疫兔获得了多克隆抗体,ELISA检测其效价为1∶128 000。本试验成功制备了具有免疫原性的VASA蛋白及其兔源多克隆抗体,为VASA蛋白生物学功能及该蛋白在绦虫体内的分布等研究奠定基础。     

蓝舌病病毒血清8型NS3蛋白在昆虫杆状病毒系统中的表达与鉴定

为表达蓝舌病病毒NS3蛋白,将蓝舌病病毒血清8型NS3序列克隆至pFastBac-HTA载体上,经转座、转染后获得重组杆状病毒rBac-NS3;用间接免疫荧光(IFA)检测NS3蛋白的表达情况,并采用亲和层析进行纯化;以Western Blot和间接ELISA方法鉴定NS3蛋白的反应原性。IFA结果显示,重组杆状病毒rBac-NS3感染的Sf9细胞可以大量表达NS3蛋白。Western Blot结果显示,纯化后的NS3蛋白与抗His单抗和绵羊蓝舌病阳性血清能够发生特异性反应;以纯化的NS3蛋白为包被抗原建立的间接ELISA方法可以区分蓝舌病阳性血清和阴性血清,进一步验证本试验利用杆状病毒表达系统成功表达并纯化出蓝舌病病毒NS3蛋白,表明纯化后的NS3蛋白具有良好的反应原性,可作为开发鉴别诊断试剂盒的备选蛋白及NS3蛋白的结构和生物学功能研究。     

Prokaryotic Expression and Immunogenicity Identification of Bluetongue Virus VP7 Protein

To obtain VP7 protein of bluetongue virus (25 type), VP7 gene was amplified and cloned in pET-24b(+) expression vector.The pET-24b-BTV-VP7 recombinant plasmid was transformed into BL21 (DE3), then the VP7 protein of bluetongue virus was expressed using IPTG and purified by nickel affinity chromatography in vitro.Immunogenicity of VP7 protein was determined by Western blotting and ELISA.The results showed that the molecular weight of VP7 protein was about 40 ku and it could react with goat positive serum specifically.This study laid the foundation for establishing protein chip detection methods in the future.     

蓝舌病病毒衣壳蛋白VP2、VP5、VP7酵母双杂交诱饵质粒的构建及鉴定

蓝舌病病毒(bluetongue virus,BTV)的结构主要由3层衣壳蛋白组成,其中VP2、VP5蛋白构成了BTV的外层衣壳,VP7蛋白构成了BTV的中间衣壳,最内层衣壳则由VP3蛋白构成。VP2、VP5及VP7蛋白在BTV侵染宿主细胞的过程中起着非常重要的作用。为了研究BTV与宿主细胞相互作用的分子机制,本研究将BTV的VP 2、VP 5、VP 7基因分别克隆到pGBKT7载体中,成功构建了pGBKT7-VP2、pGBKT7-VP5与pGBKT7-VP73个诱饵质粒,且通过自激活和毒性验证,证明所构建的3个质粒均无自激活作用,对酵母细胞无毒性作用。本研究为今后利用酵母双杂交筛选VP2、VP5、VP7蛋白中与宿主细胞相互作用的蛋白做好了铺垫,为深入研究BTV与宿主细胞的相互作用奠定了基础。     

Construction and Identification of Yeast Two-hybrid Bait Plasmids of Capsid Proteins VP2, VP5 and VP7 of Bluetongue Virus

The structure of bluetongue virus(BTV) was consisted of three layers of capsid proteins, VP2 and VP5 proteins consisted the outer capsid of BTV, VP7 protein consisted the middle capsid of BTV, VP3 consisted the inner capsid of BTV.When BTV infected host cells, VP2, VP5 and VP7 proteins of BTV played important roles in the process of infecting host cells.In order to study the molecular mechanism of interaction between BTV and host cells, we cloned VP 2, VP 5 and VP 7 genes into pGBKT7 vector, three recombinant bait plasmids pGBKT7-VP2, pGBKT7-VP5 and pGBKT7-VP7 were successfully constructed, and then the self-activation and toxicity of the bait plasmids were tested.The results showed that three bait plasmids all had no self-activation and toxicity to yeast cells.This research made a steppingstone for the screening of host-cell protein interacting with VP2, VP5 and VP7 proteins using yeast two-hybrid system, and laid a foundation for investigating the interaction between BTV and its host cells.     

非洲马瘟病毒VP7基因拼接、表达及重组ELISA方法的建立与初步应用

采用人工拼接的方式拼接了非洲马瘟病毒（AHSV）含有绝大多数线性抗原表位的VP7编码基因片段,克隆于pET-30a构建重组质粒pET-30a-VP7,将pET-30a—VP7转化BL21（DE3）,经1．0mmol／LIPTG诱导,外源基因以包涵体的形式获得高效表达。通过Dot-EuSA以及ELISA试验证明表达产物具有良好的反应原性。以纯化后表达产物作为诊断抗原包被酶标板建立了检测AHSV抗体的间接ELISA方法。结果表明,抗原的最佳包被浓度为0．25μg／mL,血清的最佳稀释度为1：40,待检血清阳性临界值初步定为0．25。用此方法和商品化ELISA试剂盒检测了184份血清样品,结果完全符合。     

African horse sickness virus structure

African horse sickness virus (AHSV), of which there are nine serotypes (AHSV-1, -2, etc.), is a member of Orbivirus genus within the Reoviridae family. Both in morphology and molecular constituents AHSV particles are comparable to those of bluetongue virus (BTV), the prototype virus of the genus. The two viruses have seven structural proteins (VP1–7) organized in two layered capsid. The outer capsid is composed of VP2 and VP5. The inner capsid, or core, is composed of two major proteins, VP3 and VP7, and three minor proteins, VP1, VP4 and VP6. Within the core is the virus genome. This genome consists of 10 double-stranded (ds)RNA segments of different sizes, three large, designated L1–L3, three medium, M4–M6, and four small, S7–S10. In addition to the seven stuctural proteins that are coded by seven of the RNA species, four non-structural proteins, NS1, NS2, NS3 and NS3A, are coded by three RNA segments, M5, S8 and S10. The two smallest proteins (NS3 and NS3A) are synthesized by the S10 RNA segment, probably from different in-frame translation initiation codons. Nucleotide sequences of eight RNA segments (L2, L3, M4, M5, M6, S7, S8 and S10) and the predicted amino acid sequences of the encoded gene products are also available, mainly representing one serotype, AHSV-4. In this review the properties of the AHSV genes and gene products are discussed. The sequence and hybridization analyses of the different AHSV dsRNA segments indicate that the segments that code for the core proteins, as well as those that code for NS1 and NS2 proteins, are highly conserved between the different virus serotypes. However, the RNA encoding NS3 and NS3A, and the two segments encoding the outer capsid proteins, are more variable between the AHSV serotypes. A close phylogenetic relationship between AHSV, BTV and epizootic haemorrhagic disease virus (EHDV), three Culicoides-transmitted orbiviruses, has been revealed when the equivalent sequences of genes and gene products are compared. Recently, the four major AHSV capsid proteins have been expressed using recombinant baculoviruses. Biochemically and antigenically these proteins are similar to the authentic proteins. Since the AHSV VP7 protein is highly conserved among the different serotypes, it has been utilized as a diagnostic reagent. The expressed VP7 protein has also been purified to homogeneity and crystallized for three-dimensional X-ray analysis. The expressed outer capsid proteins, VP2 and VP5, have been purified and used to raise antisera in rabbits. The VP2 antisera neutralize virus infections in vitro indicating the importance of this protein for vaccine development.     

Prokaryotic Expression and Immunogenicity Analysis of Mink Parvovirus NS1 and VP2 Protein

In order to develop subunit vaccine of mink enteritis virus,the immunogenicity of mink parvovirus protein NS1 and VP2 had been evaluated.Two pairs of primers were designed,and the full-length NS1 and VP2 genes had been amplificated,and then prokaryotic expression vector pET-32a-NS1,PET-32a-VP2 were constructed.After the analysis of SDS-PAGE and Western blotting,target proteins had been purified by His-Bind affinity chromatography.The immunogenicity of purified protein NS1 and VP2 were evaluated by serum ELISA testing,after inoculated BALB/c mouse.The results showed that the molecular mass of NS1 and VP2 protein were 83 and 67 ku by SDS-PAGF and Western blotting;Although both target protein NS1 and VP2 had the ability to induce BALB/c mouse to produce anti-MEV specific antibodies,the level of antibodies induced by the protein VP2 was higher than protein NS1.Mink parvovirus protein VP2 was more suitable for the development of subunit vaccine.     

水貂细小病毒NS1与VP2蛋白的原核表达及免疫原性分析

为了比较VP2和NS1两种蛋白的免疫原性,选择免疫原性较好的蛋白进行亚单位疫苗制备。本试验分别扩增了水貂细小病毒(mink enteritis virus,MEV)NS1与VP2基因,连接pET-32a表达载体并进行表达,对表达产物进行SDS-PAGE及Western blotting分析。以His-Bind亲和层析柱纯化目的蛋白,将纯化后的蛋白免疫小鼠,分析目的蛋白的免疫原性。经SDS-PAGE与Western blotting鉴定,表明NS1与VP2蛋白大小分别为83 和67 ku,且均具有生物学活性;免疫小鼠后,目的蛋白NS1和VP2均可诱导小鼠产生抗MEV特异性抗体,且VP2蛋白诱导小鼠产生的抗体滴度要高于NS1蛋白。与NS1蛋白比较,VP2蛋白更适合亚单位疫苗的制备。     

蓝舌病病毒VP7基因的原核表达

为获得蓝舌病病毒(BTV)VP7基因的原核表达蛋白,本实验采用RT-PCR方法扩增出了血清1型BTV的VP7基因,并克隆到原核表达载体pMAL-c2X中,构建了重组质粒pMAL-VP7.将重组质粒转化TBl感受态细胞,以0.5 mmol/L的IPTG进行诱导表达,SDS-PAGE电泳结果显示融合蛋白MBP-VP7以可溶形式存在,分子质量约为90 ku.以纯化的重组蛋白作为包被抗原,初步建立了检测BTV血清抗体的间接ELISA诊断方法,为今后进一步开展BTV诊断研究奠定了基础.     

Anti-idiotype technique: an alternative approach for immunodiagnosis of bluetongue

In development of a bluetongue alternative immunodiagnostic rest, the polyclonal anti-idiotypic antibodies were generated by the sequential immunization of rabbits with three monoclonal antibodies to VP7 of bluetongue virus. The anti-idiotypic antibodies recognize the idiotypes that are located within or near the antigen-combining sites and are associated with both heavy and light chains of the antibodies to VP7 of bluetongue virus. The anti-idiotypic antibodies mimic the VP7 antigen by recognizing the anti-VP7 antibodies from cattle and sheep that were infected with various serotypes of bluetongue viruses. The results indicate that the rabbit anti-idiotypic antibodies may be used as surrogate antigen in serological assays to detect the antibodies from different species of animals infected with various serotypes of bluetongue viruses.     

蓝舌病病毒重组VP7蛋白单克隆抗体制备及竞争ELISA检测方法的建立

为了建立蓝舌病(BT)的血清学诊断方法,本研究利用原核表达的蓝舌病病毒(BTV)血清型12型VP7纯化蛋白免疫BALB/c小鼠,制备2株单克隆抗体(MAb),分别命名为BTV-2D10和BTV-4H7。IFA试验表明,2株MAb均能与BTV 24个血清型发生特异性反应,而与茨城病病毒(IBAV)、中山病病毒(CV)、赤羽病病毒(AKAV)、牛病毒性腹泻病毒(BVDV)、牛传染性鼻气管炎病毒(IBRV)、牛轮状病毒(BRV)、牛肠道病毒(BEV)、牛呼肠孤病毒(RV)及口蹄疫病毒(FMDV)无交叉反应,表明2株MAb均为BTV群特异性抗体。采用重组表达的VP7蛋白作为包被抗原建立的竞争ELISA方法证明,BTV-4H7 MAb对不同血清型BTV阳性血清具有良好的阻断效果,而对AKAV、IBAV、BRV和FMDV阳性血清无阻断作用。本研究建立的竞争ELISA方法与IDEXX公司的试剂盒检测包括65份已知背景血清和322份采自广西省的山羊血清样品,检测结果符合率分别达100%和98%。该竞争ELISA方法的建立为BTV抗体的监测提供了安全、快速、准确的技术手段。