应用Pull-down方法检测草鱼恒定链(Ii)与主要组织相容性复合体(MHC)分子的结合

摘要
图/表
参考文献
相关文章 (7)

全文: PDF (1210 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要恒定链(invariant chain, Ii)能结合主要组织相容性复合体(major histocompatibility complex, MHC)Ⅰ类和Ⅱ类分子，并在MHC递呈抗原中起重要辅助作用。为了探讨鱼类Ii和MHC分子体外结合关系，本研究采用Pull-down方法检测草鱼(Ctenopharyngodon idellus) Ii与MHCⅠ类或Ⅱ类分子的结合。克隆草鱼Ii (711 bp)、MhcⅠα (540 bp)和MhcⅡβ (549 bp)基因片段，再将其分别插入原核表达质粒PET-22b(无His标签)或PET-28a (含His标签)中，构建了3个重组质粒PET-22b-Ii、PET-28a-MhcⅠα和PET-28a-MhcⅡβ。然后分别转染工程菌大肠杆菌(Escherichia coli) Rosetta(DE3)，进行诱导表达、纯化和聚丙烯酰胺凝胶电泳(polyacrylamide gel electrophoresis, PAGE)鉴定。结果表明，含His标签的MHCⅠα和MHCⅡβ不仅表达，而且可高效纯化，其相对分子质量约为24 kD；Western blot结果表明，Ii可表达，相对分子质量约为30 kD。将PET-22b-Ii与PET-28a-MhcⅠα或PET-28a-MhcⅡβ分别共转染Rosetta (DE3)，构建了重组菌Rosetta(DE3) (PET-28a-MhcⅠα+PET-22b-Ii)和Rosetta(DE3) (PET-28a-MhcⅡβ+PET-22b-Ii)。经诱导表达和PAGE检测发现，MHCⅠα和MHCⅡβ分别结合Ii，形成相对分子质量为54 kD的复合物； SDS处理后，分别被解离形成单分子Ii(30 kD)以及MHCⅠα 或MHCⅡβ (24 kD)。在Western blot中，解离后的Ii可与特异性多克隆抗体结合并被电化学发光(electrogenerated chemiluminescence, ECL)显色。综上所述，草鱼Ii可以分别与MHCⅡβ和MHCⅠα结合，为进一步研究动物Ii与MHC分子的关系提供了基础资料。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	林海斌
	张娅菲
	杨聪莺
	罗兰芳
	杨磊
	余为一
	刘洪明
	陈芳芳

关键词 ：草鱼, 恒定链(Ii), 主要组织相容性复合体(MHC), 原核共转染

Abstract：Invariant chain (Ii) can bind to major histocompatibility complex (MHC) classⅠorⅡmolecules, and plays an important assistant role in antigen presentation by MHC molecules. In order to explore what about the binding of Ii with MHC molecules, a Pull-down method for detection of association of grass carp(Ctenopharyngodon idellus) Ii with MHC molecules was reported in the present study. DNA segments of Ii (711 bp), MhcⅠα (540 bp) and MhcⅡβ (549 bp) in grass carp were cloned, and then respectively inserted into prokaryotic expression plasmid PET-22b (no His-tag) or PET-28a (carry with His-tag) to construct 3 recombinant plasmids of PET-22b-Ii, PET-28a-MhcⅠα and PET-28a-MhcⅡβ. The above 3 recombinant plasmids then were transfected into engineering bacteria (Escherichia coli) Rosetta (DE3), respectively. After an induction to express and renature the interest proteins and purification by Ni+-NTA affinity chromatography column, the purified expressed protein products were detected by polyacrylamide gel electrophoresis (PAGE). The results indicated that MHCⅠα and MHCⅡβ labeled with His-tag could well express and be purified each with a molecular weight of 24 kD. The result of Western blot showed that Ii also well expressed and had a molecular weight of about 30 kD. Finally, the recombinant plasmid PET-22b-Ii was cotransfected with PET-28a-MhcⅠα or PET-28a-MhcⅡβ into Rosetta (DE3), respectively, to construct 2 recombinant strains of Rosetta(DE3)(PET-28a-MhcⅠα+PET-22b-Ii) and Rosetta(DE3)(PET-28a-MhcⅡβ+PET-22b-Ii). Induced expression and PAGE detection showed that MHCⅠα or MHCⅡβ could bind Ii to form a complex of 54 kD, respectively, which could be dissociated into simple molecule of Ii (30 kD), MHCⅠα or MHCⅡβ (24 kD) after SDS treatment, respectively. Western blot result showed that the dissociated Ii could bind specific antibody and be coloured by electrogenerated chemiluminescence (ECL). In conclusion, the prokaryotic expressed grass carp Ii and MHC molecules had activity, and its Ii could bind with MHCⅡβ as well as MHCⅠα. This research provides basic data for further research on relation between Ii and MHC molecules in animals.

Key words： Grass carp Invariant chain(Ii) Major histocompatibility complex(MHC) Prokaryotic cotransfection

收稿日期: 2014-12-01 出版日期: 2015-04-13

基金资助:国家自然科学基金;国家自然科学基金

通讯作者: 陈芳芳 E-mail: fang7828887@126.com

引用本文:

林海斌张娅菲杨聪莺罗兰芳杨磊余为一刘洪明陈芳芳. 应用Pull-down方法检测草鱼恒定链(Ii)与主要组织相容性复合体(MHC)分子的结合[J]. , 2015, 23(6): 772-778.

链接本文:

http://journal05.magtech.org.cn/Jwk_ny/CN/ 或 http://journal05.magtech.org.cn/Jwk_ny/CN/Y2015/V23/I6/772

[1] Jasanoff A ,Wagner G,Wiley D C. 1998. Structure of a trimeric domain of the MHC class Ⅱ2associated chaperonin and targeting protein Ii [J ] . EMBO Journal,17 (23) :6812-6818.
[2] Strubin M, Berte C, Mach B. 1986. Alternative splicing and alternative initiation of translation explain the four forms of the Ia antigen-associated invariant chain[J]. EMBO Journal, 5:3483-3488.
79:3053-63.
[3] Warmerdam P A, Long E O, Roche P A. 1996. Isoforms of the invariant chain regulate transport of MHC class II molecules to antigen processing compartments[J]. Journal of Cell Biology, 133, 281-291.
[4] Sillé F C, Martin C, Jayaraman P, et al. 2011. Requirement for invariant chain in macrophages for Mycobacterium tuberculosis replication and CD1d antigen presentation[J]. Infection and Immunity, 2011.
[5] Karakikes I, Morrison I E, O'Toole P, et al. 2012. Interaction of HLA-DR and CD74 at the cell surface of antigen-presenting cells by single particle image analysis[J]. FASEB Journal, 26(12):4886-4896.
[6] Frauwirth K, Shastri N. 2001. Mutation of the invariant chain transmembrane region inhibits II degradation, prolongs association with MHC class II, and selectively disrupts antigen presentation[J]. Cellular Immunology, 209:97-108.
[7] Dixon A M, Stanley B J, Matthews E E, et al. 2006. Invariant chain transmembrane domain trimerization: a step in MHC class II assembly[J]. Biochemistry, 45:5228-5234.
[8] Roche P A, Cresswell P. 2011. Proteolysis of the class II-associated invariant chain generates a peptide binding site in intracellular HLA-DR molecules[J]. Journal of Immunology, 187:1076-1080.
[9] Arneson L S, Miller J. 1995. Efficient endosomal localization of major histocompatibility complex class II-invariant chain complexes requires multimerization of the invariant chain targeting sequence[J]. Journal of Cell Biology. 129, 1217-1228.
[10] Neumann J, Koch N. 2005. Assembly of major histocompatibility complex class II subunits with invariant chain[J]. FEBS Lett 579, 6055-6059.
[11] Germain R N. 2011. Uncovering the role of invariant chain in controlling MHC class II antigen capture[J]. Journal Immunology, 187, 1073-1075.
[12] Basha G, Omilusik K, Chavez-Steenbock, A, et al. 2012. A CD74-dependent MHC class I endolysosomal cross-presentation pathway[J]. Nature Immunology, 13, 237-245.
[13] Chen F F, Pan L, Zhang J G, et al. 2014. Allele-dependent association of chicken MHC class I molecules with the invariant chain[J]. Veterinary immunology and Immunnophathology, 160:273-280.
[14] van Lith M, McEwen-Smith RM, Benham AM. 2010. HLA-DP, HLA-DQ, and HLA-DR have different requirements for invariant chain and HLA-DM[J]. Journal of Biological Chemistry, 285(52):40800-8.
[15] Frayser M, Sato AK, Xu L, et al., 1999. Empty and peptide-loaded class II major histocompatibility complex proteins produced by expression in Escherichia coli and folding in vitro[J]. Protein Expression and Purification, 15(1):105-14.
[16] Dai Y, Chen F F, Liu X L, et al. 2010. cDNA cloning and antigen-binding sites of the MHC class I in Chinese native chicken (Qingyuan Partridge chicken)[J]. International Journal of Food, Agriculture & Environment (JFAE), 8(1):91-97.
[17] Chen F F, Pan L, Wu C, et al. 2012. Character of chicken polymorphic MHC class II alleles of three Chinese local breeds[J]. Poultry Science, 91:1097-1104.
[18] Tan S, Kern RC, Selleck W. 2005. The pST44 polycistronic expression system for producing protein complexes in Escherichia coli[J]. Protein Expression Purification, 40(2):385-95.
[19] K?hler A, Zimmerman E, Schneider M, et al., 2010. Structural basis for assembly and activation of the heterotetrameric SAGA histone H2B deubiquitinase module[J]. Cell, 141(4):606-17.
[20] Chou CL, Sadegh-Nasseri S. 2000. HLA-DM recognizes the flexible conformation of major histocompatibility complex class II[J]. Journal Experimental Medicine, 192(12):1697-706.
[21] Chen F F, Pan L, Dai Y, et al., 2011. Characteristic of expression of goose invariant chain gene and comparison of its structure among different species . Poultry Science, 90:1664-70.
[22] Chen F F, Wu C, Pan L, et al., 2013. Cross-species association of quail invariant chain with chicken and mouse MHC II molecules[J]. Developmental and Comparative Immunology, 40(1):20-27.