eISSN: 1644-4124
ISSN: 1426-3912
Central European Journal of Immunology
Current issue Archive Manuscripts accepted About the journal Special Issues Editorial board Abstracting and indexing Subscription Contact Instructions for authors Publication charge Ethical standards and procedures
Editorial System
Submit your Manuscript
SCImago Journal & Country Rank
1/2014
vol. 39
 
Share:
Share:

Genetic and antigenic analysis of mink’s immunoglobulin G Fc region

Lei Jiang
,
Li Li
,
Cui Zhao
,
Xiao-ru Pang
,
Qiang Shen
,
Wei-Shan Chang
,
Jing Zhai

(Centr Eur J Immunol 2014; 39 (1): 36-39
Online publish date: 2014/04/17
Article file
- Genetic Lei Jiang.pdf  [0.21 MB]
Get citation
 
PlumX metrics:
 

Introduction

In recent years, the scale of special animal breeding in China has continued to expand, the quantity of mink breeding has reached a certain scale, but currently the epidemic diseases among the groups of minks are viral diseases, such as canine distemper, canine parvovirus disease [1]. At present, a virus detection kit and colloidal gold test strip for the minks are not yet popular, and as a result, rapid detection of diseases of the minks cannot be carried out conveniently. Several viral diseases in dogs also occur in minks, and canine disease diagnostic market has become perfect, so that the possibility of using dogs’ detection reagents to detect corresponding viral diseases in minks has an important significance.
Fc is a significant domain of immunoglobulins [2, 3]. It is related to the species specific to the antibody. Immunoglobulin G Fc fragment not only has the ability to activate the complement system, but also the ability to induce the binding of the antigen-antibody complex and the antigen-presenting cell through the Fc receptor (FcR) [4]. It can also promote the phagocytosis of antigen-presenting cells to foreign antigens in the receptor-induced ones, and thus stimulate the cellular immune response of the body to specific antigens [5, 6]. In this study we extracted RNA from mink spleen, then mink IgG Fc gene was cloned, and the genetic evolution of this sequence was analyzed. Mink, canine, mice and chicken IgG cross-reactivity was detected based on western blot. It provides a theoretical basis for guiding clinical mink disease immune detection and serology treatment.

Material and methods

Sample collection and tissue preparation

The minks were purchased from a mink farm, Zhu-cheng, China. Spleen was harvested and frozen in the fridge (–20°C).

Total RNA isolation and synthesis of cDNA

Total RNA samples were extracted from spleens using Trizol (TransGen) and the cDNA pool was obtained using the PrimScript RT reagent Kit (TaKaRa).

RT-PCR and sequencing

A pair of homologous primers (Table 1) was designed by DNASTAR 5.0 software with respect to the minks (GenBank: L07789.1). With the primers, a cDNA fragment was amplified through RT-PCR using the first strand cDNAs as templates. The PCR reaction was performed under the following conditions in a thermal cycle: initial denaturation at 94°C for 5 min; 30 cycles of denaturation at 94°C for 30 s; annealing at 55°C for 30 s and extension at 72°C for 10 min. Polymerase chain reaction (PCR) products were analyzed by electrophoresis in 1% agarose, and purified by Agarose Gel DNA Extraction Kit (Shanghai Sangon Biotech Co., Ltd.). The products were cloned by Peasy-T1(TransGen) and sent to Shanghai Sangon Biotec Co., Ltd. for sequencing.

Multiple alignment and phylogenetic sequence analysis

The nucleotide sequence of mink IgG-Fc fragment, along with that of American minks, canines, mice and chicken from GenBank, were aligned by DNAstar software. Phylogenetic analysis was carried out utilizing DNAMAN5.2 software.

SDS-PAGE and Western-blot

Different animal IgG (Y) (Beijing solarbio Co., Ltd.) was quantitatively diluted, then the samples and the Loading Buffer were added to boiling water at a ratio of 1 : 1 and boiled for 10 min. Concentration of the stacking gel was 5%, concentration of the separating gel was 15%, wet transfer was carried out overnight. The cellulose membrane was closed by 5% skim overnight, and rinsed 2 times, 5 min each time. Rabbit anti-dog IgG was diluted 200-fold, 10 ml of diluent was added, slowly incubated at room temperature for 3 h, rinsed for 10 min by TBST for a total of 5 times. At last it was developed in a darkroom by HRP-DAB and was observed after 3 min.

Results

Molecular cloning and analysis of mink IgG-Fc

A cDNA fragment of mink IgG-Fc fragment of 606bp (Fig. 1) was obtained from single RT-PCR which was identified from the spleen cDNA library of mink. It encoded a protein 202 amino acids in length.

Alignment and phylogenetic analysis

The deduced amino acid sequence of IgG-Fc was compared with those of American minks, canines, mice and chicken using DNAMAN (Fig. 2). The phylogenetic tree was constructed from the deduced mink IgG-Fc and the IgG(Y) sequences from several avians and mammalians using software DNAMAN 5.0. The result revealed that the highest homology of minks was with canines, and avian IgY-Fc which formed a monophyletic group distinct from mammalian IgG-Fc (Fig. 3).

The genetic variation analysis on gene and amino acids of IgG(Y)-Fc of different animals

The genetic variation analysis of minks (sequencing), American minks, canines, mice and chicken’s gene and amino acids of IgG(Y)-Fc was shown in Figure 1. The results showed that nucleotide sequence homologies between minks (sequencing) and American minks were 99%, and amino acid sequence homologies between minks and American minks were 97.5%. The highest nucleotide sequence homologies between minks and heterogeneous animals were 85% (canine), and the highest amino acid sequence homologies between minks and heterogeneous animals were 80.5%.

SDS-PAGEwestern blot

In Fig. 4, a heavy chain of IgG (Y) of different animals could be clearly seen. The heavy chain of minks, mice and canines was about 55 KD, the heavy chain of chicken was about 67 KD. It also showed that the anti-dog IgG-HRP could be reacted with dog IgG heavy chain and light chain. Anti-dog IgG-HRP and mink IgG had cross-reactivity to a certain extent, and the cross-reactivity response with chicken was very weak.

Discussion

The antigenicity of the antibody itself mainly depends on the Fc fragment of the antibody heavy chain. The constant region gene of the heavy chain is relatively conservative, so the analysis of the homology of different animal IgG heavy chain gene can reflect whether the antigenicity of the different animal antibody has intersectionality or not. In this study, we cloned the active mink’s IgG Fc gene, and we analysed the genetic evolution. We obtained the evolutionary tree and sequences’ comparison chart. The analysis of gene and amino acid showed that there was a certain extent of homology among IgG Fc of different animals. Mammals and birds could be seen that they belong to two branches of the evolutionary tree, and minks had the closest relationship with dogs. We firstly proved that mink IgG heavy chain can effectively combine to anti-dog IgG by western blot effectively. Therefore, we conclude that the diagnosing of mink diseases by dog diagnosis reagent is feasible. Through clinical practice we have also proved that the diagnostic SMZ-strip of dog’s canine distemper, parvovirus could be used on minks [7, 8]. From clinical practice, we got that we could treat mink’s distemper with serum of rehabilitated dogs’ distemper.
In this experiment, a variety of software analysis and western blot analysis demonstrated that dogs’ test kit can be applied to the body of the minks. And this study provided a theoretical basis for guiding the diagnosing of clinical disease of minks, it also laid the foundation for the research of antigenic gene and immunotherapy of antigenic protein.

Authors declare no conflict of interest. This work was supported by the project J08LF60 of the Shandong (China) Provincial Department of Education.

References

 1. Sidhu MS, Husar W, Cook SD, et al. (1993): Canine distemper terminal and intergenic non-protein coding nucleotide sequence: completion of the entire CDV genome sequence. Virology 193: 66-72.  
2. Jefferis R, Lund J, Pound JD (1998): IgG-Fc-mediated effector functions: molecular definition of interaction sites for effector ligands and the role of glycosylation. Immunol Rev 163: 59-76.  
3. Morgan EL, Thoman ML, Weigle WO (1981): Enhancement of T lymphocyte functions by Fc fragments of immunoglobulins. I. Augmentation of allogeneic mixed lymphocyte culture reactions requires I-A-or-I-B subregion differences between effector and stimulator cell populations. J Exp Med 153: 1161-1172.  
4. Teplyakov A, Zhao Y, Malia TJ (2013): IgG2 Fc structure and the dynamic features of the IgG CH2-CH3 interface. Mol Immunol 56: 131-139.
5. Ferrone CR, Perales MA, Goldberg SM (2006): Adjuvanticity of plasmid DNA encoding cytokines fused to immunoglobulin Fc domains. Clin Cancer Res 12: 5511-5519.
6. Regnault A, Lankar D, Lacabanne V (1999): Fc gamma receptor-mediated induct ion of dendritic cell maturation and major histocompatibility complex class I restricted antigen presentation after immune complex internalization. J Exp Med 189: 371-380.  
7. Chappuis G (1995): Control of canine distemper. Vet Microbiol 44: 351-358.  
8. Blixenkrone-Møller M, Pedersen IR, Appel MJ, Griot C (1991): Detection of IgM antibodies against canine distemper virus in dog and mink sera employing enzyme-linked immunosorbent assay (ELISA). J Vet Diagn Invest 3: 3-9.
Copyright: © 2014 Polish Society of Experimental and Clinical Immunology This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License (http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
Quick links
© 2024 Termedia Sp. z o.o.
Developed by Bentus.