猪CD1d蛋白多克隆抗体的制备及应用

doi:10.3864/j.issn.0578-1752.2024.08.015

摘要/Abstract

摘要：

【目的】制备猪源CD1d的多克隆抗体，为探究猪CD1d蛋白在非洲猪瘟病毒（African swine fever virus，ASFV）感染过程中的功能奠定基础。【方法】利用PCR方法扩增了猪CD1d基因，并将其同源重组至pGEX-6p1载体中，构建了原核重组表达质粒pGEX-6p1-CD1d。将重组质粒转化E.coli BL21（DE3）并用IPTG进行诱导表达，表达的GST-CD1d重组蛋白经SDS-PAGE和Western blot（WB）方法鉴定，SDS-PAGE结果显示约50 ku处有一条明显的条带，该蛋白以包涵体形式表达。然后利用谷胱甘肽琼脂糖亲和层析方法进行蛋白纯化，将纯化的GST-CD1d蛋白与等体积的弗氏完全佐剂混合乳化后，将纯化的蛋白免疫新西兰大白兔，采用颈背部多点皮下注射，免疫剂量为200 μg/只，首免后第3周和第5周分别进行二免和三免，均采用弗氏不完全佐剂乳化，方法和剂量与首免相同。三免后第7天，通过耳缘静脉采血分离血清。首免后第7周进行第四次免疫，一周后心脏采血。该抗体经Protein G亲和层析纯化后冻存于-80 ℃冰箱。通过WB和间接免疫荧光（IFA）鉴定瞬时转染表达的外源CD1d蛋白和猪原代巨噬细胞（PAMs）表达的内源CD1d蛋白的表达与细胞定位情况。同样，制备的CD1d抗体可以将外源瞬时转染表达的CD1d通过IP拉下。为了探究CD1d在ASFV感染早期的情况，将ASFV接种于PAMs，制备ASFV感染0、15、30、60 min的样品，以CD1d为一抗，通过WB检测了CD1d蛋白的表达情况。在HEK293T细胞共转pCAGGS-HA-CD1d和pCAGGS-Flag-CD2v质粒，24 h后收取细胞裂解，加入Flag beads过夜结合蛋白，通过WB检测互作情况染，同时，质粒共转染于共聚焦小皿中的HEK293T细胞，用标签抗体对其进行孵育，选择相应的荧光二抗，通过激光共聚焦显微镜观察CD1d与CD2v在细胞中共定位情况。采用Co-IP验证CD1d与ASFV外囊膜蛋白CD2v的相互作用。【结果】原核表达的GST-CD1d蛋白以包涵体形式表达在感受态细胞中，分子质量约为35 ku；实验兔4次免疫CD1d重组蛋白后采血并分离血清，纯化的抗体经SDS-PAGE检测在45和25 ku处各出现一条特异性条带，分别为CD1d抗体的重链与轻链。以纯化的CD1d蛋白作为免疫原制备的兔抗CD1d抗体包含重链和轻链，且具有较好纯度；该抗体能够通过WB和IFA鉴定瞬时转染的外源以及PAMs内源CD1d蛋白的表达和细胞定位。进一步检测结果显示，ASFV感染PAMs后，CD1d蛋白表达水平明显增加，并且WB和IFA结果显示CD1d与ASFV编码的外囊膜蛋白CD2v存在相互作用和共定位。【结论】通过原核表达技术制备了CD1d的抗体，为进一步探究CD1d蛋白在ASFV感染过程中的生物学功能打下了基础。

关键词: CD1d蛋白, 原核表达, 多克隆抗体, 非洲猪瘟病毒, CD2v蛋白

Abstract:

【Objective】 The aim of this study was to prepare polyclonal antibodies against porcine CD1d protein, so as to lay the foundation for exploring the function of porcine CD1d protein in the process of African swine fever virus (ASFV) infection. 【Method】 In this study, the pig CD1d gene was amplified using PCR and homologously recombined into the pGEX-6p1 vector, constructing a prokaryotic recombinant expression plasmid pGEX-6p1-CD1d. The recombinant plasmid E. coli BL21 (DE3) was transformed and induced for expression using IPTG. The expressed GST CD1d recombinant protein was identified by SDS-PAGE and Western blot (WB) methods. The SDS-PAGE results showed a clear band at approximately 50 ku, which was expressed in the form of an inclusion body. Then, protein purification was performed using glutathione agarose affinity chromatography. The purified GST-CD1d protein was mixed and emulsified with an equal volume of Freund's complete adjuvant. The purified protein was immunized in New Zealand white rabbits and administered subcutaneously at multiple points on the neck and back, with an immune dose of 200 μG/piece, and then second and third immunizations were performed at the 3rd and 5th weeks after the first immunization, respectively, using Freund's incomplete adjuvant emulsification, with the same method and dosage as the first immunization. On the 7th day after the third immunization, the blood was collected from the ear vein to isolate the serum. The fourth immunization was conducted at the 7 weeks after the first immunization, and the blood was collected from the heart one week later. The antibody was purified by Protein G affinity chromatography and frozen at -80 ℃. The expression and cellular localization of endogenous CD1d protein expressed by transient transfection of exogenous and porcine primary macrophages (PAMs) were indentified by using WB and indirect immunofluorescence (IFA). Similarly, the prepared CD1d antibody could pull down CD1d expressed by transient exogenous transfection through IP. In order to investigate the early stage of ASFV infection, ASFV was inoculated into PAMs and samples of ASFV infection for 0, 15, 30, and 60 minutes were prepared, respectively. CD1d was used as the primary antibody and the expression of CD1d protein was detected by WB. Plasmids pCAGGS-HA-CD1d and pCAGGS-Flag-CD2v were co transfected into HEK293T cells. After 24 hours, the cells were collected for lysis, and Flag beads overnight binding protein was added. The interaction was detected by WB staining. At the same time, the plasmids were cotransfected into HEK293T cells in a confocal dish, incubated with labeled antibodies, and corresponding fluorescent secondary antibodies were selected. The co localization of CD1d and CD2v was observed under a laser confocal microscope. Verification of Co-IP interaction between CD1d and ASFV outer capsule protein CD2v was verified. 【Result】 The GST-CD1d protein expressed in prokaryotic cells was expressed in the form of inclusion bodies, with a molecular weight of approximately 35 ku; After four rounds of immunization with CD1d recombinant protein in experimental rabbits, blood was collected and serum was separated. The purified antibody was detected by SDS-PAGE and showed a specific band at 45 and 25 ku, respectively, representing the heavy and light chains of the CD1d antibody. The rabbit anti CD1d antibody prepared using purified CD1d protein as immunogen contained both heavy and light chains, and had good purity; This antibody could identify the expression and cellular localization of transient transfected exogenous and PAMs endogenous CD1d proteins through WB and IFA. Further testing results showed that after ASFV infection with PAMs, the expression level of CD1d protein significantly increased, and WB and IFA results showed that CD1d interacted and co localized with the outer capsule protein CD2v encoded by ASFV. 【Conclusion】 This study prepared antibodies against CD1d through prokaryotic expression technology, laying the foundation for further exploration of the biological function of CD1d protein in ASFV infection process.

Key words: CD1d protein, prokaryotic expression, polyclonal antibody, African swine fever virus, CD2v protein

刘传霞, 陈欣, 王晓, 李雪雯, 李婷婷, 翁长江, 郑君. 猪CD1d蛋白多克隆抗体的制备及应用[J]. 中国农业科学, 2024, 57(8): 1620-1628.

LIU ChuanXia, CHEN Xin, WANG Xiao, LI XueWen, LI TingTing, WENG ChangJiang, ZHENG Jun. Preparation and Application of Polyclonal Antibodies Against Pig CD1d Protein[J]. Scientia Agricultura Sinica, 2024, 57(8): 1620-1628.

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