Abstract:Neonatal Fc receptor (FcRn) can specifically recognize and transport IgG across the mucosal barrier. In order to determine the interaction between porcine (Sus scrofa) FcRn and IgG Fc segment CH2 domain, the porcine IgG CH2 gene was cloned by the reverse transcription (RT-PCR) and further subcloned into prokaryotic expression vector PEGX-4T-1. The fusion protein was induced by isopropyl β-D-thiogalactoside (IPTG) and purified by glutathione S-transferase (GST) Affinity Column. In addition, IgG CH2 gene was subcloned to eukaryotic expression vector pEGFP-C1 and Co-transfection was carried out to determine whether the IgG CH2 and FcRn co-located in African green monkey (Chlorocebus sabaeus) kidney cells (COS-7). The interaction of IgG CH2 and FcRn was verified by coimmunoprecipitation. Furthermore, the binding ability of IgG CH2 and FcRn under different pH condition was detected by ELISA. The results showed the amplified porcine IgG CH2 gene was 330 bp, encoding 110 amino acids. The relative molecular weight of fusion protein GST-CH2 was 38.4 kD. The GST-CH2 in the induced bacteria existed in the form of soluble protein and inclusion body. The soluble GST-CH2 protein will possess the better ability of combining the FcRn. Laser confocal microscope observation showed that the IgG CH2 and FcRn were located in the cytoplasm and had an aggregation phenomenon. The coimmunoprecipitation showed that the corresponding target bands could be detected in all the coprecipitation strips through labeled protein GFP and Flag, which indicated IgG CH2 could bind FcRn. By ELISA, it was found that the IgG CH2 and FcRn had the binding ability when pH value was 6.0, but they were not combined at pH 7.4, suggesting that the combination of IgG CH2 and FcRn was dependent on pH. In conclusion, the results showed that FcRn and CH2 domain of IgG Fc segment had a co-localization and interaction, their combination was pH-dependent, which provides materials for the construction of Fc-based small-size antibody fusion protein.
[1] Bai Y, Ye L, Tesar D B, et al.2011. Intracellular neutralization of viral infection in polarized epithelial cells by neonatal Fc receptor (FcRn)-mediated IgG transport[J]. Proceedings of National Academy of Sciences of the USA, 108(45): 18406-18411. [2] Booth B J, Ramakrishnan B, Narayan K, et al.2018. Extending human IgG half-life using structure-guided design[J]. MAbs, 10(7): 1098-1110. [3] Burmistrova D A, Tillib S V, Shcheblyakov D V, et al.2016. Genetic passive immunization with adenoviral vector expressing chimeric nanobody-Fc molecules as therapy for genital infection caused by mycoplasma hominis[J]. PLOS ONE, 11(3): 1-21. [4] Cao G C, Gao X Y, Zhan Y C, et al.2020. An engineered human IgG1 CH2 domain with decreased aggregation and nonspecific binding[J]. MAbs, 12(1): e1689027-3. [5] Carter P J.2006. Potent antibody therapeutics by design[J]. nature reviews immunology, 6(5): 343-357. [6] Chu C F, Meador M G, Young C G, et al.2008. Antibody-mediated protection against genital herpes simplex virus type 2 disease in mice by Fc gamma receptor-dependent and -independent mechanisms[J]. Journal of Reproductive Immunology, 78(1): 58-67. [7] Deissler H L, Lang G K, Lang G E.2017. Neonatal Fc receptor FcRn is involved in intracellular transport of the Fc fusion protein aflibercept and its transition through retinal endothelial cells[J]. Experiment Eye Research, 154: 39-46. [8] Gong R, Wang Y, Feng Y, et al.2011. Shortened engineered human antibody?CH2?domains: Increased stability and binding to the human neonatal Fc receptor[J]. The Journal Biological Chemistry, 286(31): 27288-27293. [9] Gong R, Wang Y, Ying T, et al.2013. N-terminal truncation of an isolated human IgG1?CH2?domain significantly increases its stability and aggregation resistance[J]. Molecular Pharmaceutics, 10(7): 2642-2652. [10] Klaus T, Bereta J, 2018. CH2 domain of mouse IgG3 governs antibody oligomerization, increases functional affinity to multivalent antigens and enhances hemagglutination[J]. Frontiers in Immunology, 9: 1096-1110. [11] Knopp G W, Stadlmayr G, Ruker F.2016. IgG Fc fragment as a scaffold for development of targeted therapeutics[J]. Current Pharmaceutical Biotechnology, 17(15): 1315-1323. [12] Li Z, Palaniyandi S, Zeng R, et al.2011. Transfer of IgG in the female genital tract by MHC class I-related neonatal Fc receptor (FcRn) confers protective immunity to vaginal infection[J]. Proceedings of the National Academy of Sciences of the USA, 108(11): 4388-4393. [13] Liu Z, Liu Y, Zhang Y, et al.2017. Surface displaying of swine IgG1 Fc enhances baculovirus-vectored vaccine efficacy by facilitating viral complement escape and mammalian cell transduction[J]. Journal of Veterinary Research, 48(1): 29-40. [14] Lu L, Palaniyandi S, Zeng R, et al.2011. A neonatal Fc receptor-targeted mucosal vaccine strategy effectively induces HIV-1 antigen-specific immunity to genital infection[J]. Journal of Virology, 85(20): 10542-10553. [15] Neuber T, Frese K, Jaehrling J, et al.2014. Characterization and screening of IgG binding to the neonatal Fc receptor[J]. MAbs, 6(4): 928-942. [16] Nimmerjahn F.2015. A constant threat for HIV: Fc-engineering to enhance broadly neutralizing antibody activity for immunotherapy of the acquired immunodeficiency syndrome[J]. European of Journal Immunology, 45(8): 2183-2190. [17] Stapleton N M, Einarsdóttir H K, Stemerding A M, et al.2015. The multiple facets of FcRn in immunity[J]. Immunological Reviews, 268(1): 253-68. [18] Suzuki T, Ishii-Watabe A, Tada M, et al.2010. Importance of neonatal FcR in regulating the serum half-life of therapeutic proteins containing the Fc domain of human IgG1: A comparative study of the affinity of monoclonal antibodies and Fc-fusion proteins to human neonatal FcR[J]. Journal of Immunology, 184(4): 1968-1976. [19] Wang Y, Tian Z, Thirumalai D, et al.2014. Neonatal Fc receptor (FcRn): A novel target for therapeutic antibodies and antibody engineering[J]. Journal of Drug Targeting, 22(4): 269-278. [20] Yang C, Gao X, Gong R.2018. Engineering of Fc fragments with optimized physicochemical properties implying improvement of clinical potentials for Fc-Based therapeutics[J]. Frontiers in Immunology, 8: 1860-1874. [21] Yang WT, Yang GL, Wang Q, et al.2017. Protective efficacy of Fc targeting conserved influenza virus M2e antigen expressed by Lactobacillus plantarum[J]. Antiviral Research, 138: 9-21. [22] Ying T, Chen W, Feng Y, et al.2013. Engineered soluble monomeric IgG1 CH3 domain: Generation, mechanisms of function, and implications for design of biological therapeutics[J]. The Journal Biological Chemistry, 288(35):25154-2564. [23] Ying T, Ju T W, Wang Y, et al.2014. Interactions of IgG1 CH2 and CH3 domains with FcRn[J]. Frontiers in Immunology, 5: 146-153.
