重组卵形疟原虫裂殖子表面蛋白1 N端的抗原性及免疫原性分析

doi:10.12140/j.issn.1000-7423.2021.06.004

中国寄生虫学与寄生虫病杂志 ›› 2021, Vol. 39 ›› Issue (6): 746-752.doi: 10.12140/j.issn.1000-7423.2021.06.004

重组卵形疟原虫裂殖子表面蛋白1 N端的抗原性及免疫原性分析

于嘉利¹(), 刘蕾², 杨博¹, 楚瑞林³, 孙毅凡¹, 刘耀宝⁴, 程洋¹^,^*()

1 江南大学无锡医学院病原感染与免疫研究室,无锡 214000
2 江阴市第三人民医院,无锡 214000
3 上海市疾病预防控制中心,上海 200336
4 江苏省血吸虫病防治研究所,无锡 214000

收稿日期:2021-03-15 修回日期:2021-05-06 出版日期:2021-12-30 发布日期:2021-12-15
通讯作者: 程洋
作者简介:于嘉利（1996-）,女,硕士研究生,从事病原感染与免疫研究。E-mail： 18328089416@163.com
基金资助:
国家自然科学基金(81871681)

Antigenicity and immunogenicity analysis of the recombinant merozoite surface protein 1 N-terminal of Plasmodium ovale

YU Jia-li¹(), LIU Lei², YANG Bo¹, CHU Rui-lin³, SUN Yi-fan¹, LIU Yao-bao⁴, CHENG Yang¹^,^*()

1 Laboratory of Pathogen Infection and Immunity, Wuxi School of Medicine, Jiangnan University, Wuxi 214000, China
2 The Third People’s Hospital of Jiangyin City,Wuxi 214000, China
3 Shanghai Center for Disease Control and Prevention,Shanghai 200336,China
4 Jiangsu Institute of Parasite Diseases, Wuxi 214000, China

Received:2021-03-15 Revised:2021-05-06 Online:2021-12-30 Published:2021-12-15
Contact: CHENG Yang
Supported by:
National Natural Science Foundation of China(81871681)

摘要/Abstract

摘要：

目的表达卵形疟原虫柯氏亚种（Plasmodium ovale curtisi）和沃氏亚种（P. ovale wallikeri）裂殖子表面蛋白1（merozoite surface protein 1,MSP1）N端重组蛋白,并进行抗原性及免疫原性分析,以探究其作为卵形疟候选疫苗的潜力。方法 PCR扩增卵形疟原虫基因组DNA Pomsp1 N端基因。将纯化后的Pocmsp1 N端、Powmsp1 N端分别与pET30a、pET32a载体连接,并转化至DH5α感受态细胞中,经BamHⅠ和XhoⅠ双酶切验证且测序无误后,转入大肠埃希菌BL21（DE3）pLysS中。0.1 mmol/L异丙基-β-D-硫代半乳糖苷（IPTG）诱导表达后纯化蛋白,采用十二烷基硫酸钠-聚丙烯酰胺凝胶电泳（SDS-PAGE）和蛋白质印迹（Western blotting）检测蛋白表达情况。15只BALB/c小鼠随机分为rPocMSP1 N端组、rPowMSP1 N端组和阴性对照组,每组5只,分别腹腔注射50 μg与弗氏完全佐剂混合的rPocMSP1和rPowMSP1 N端蛋白和等量的PBS,初次免疫后第21天和第42天使用弗氏不完全佐剂加强免疫,初次免疫后第0、7、28和49天采集小鼠尾静脉血,制备血清。ELISA、Western blotting检测小鼠血清中特异性IgG、分析抗体滴度及抗体亲和指数,评估纯化后的rPocMSP1和rPowMSP1 N端蛋白的免疫原性。Western blotting检测rPocMSP1和rPowMSP1 N端蛋白的交叉反应,并用蛋白芯片分析重组蛋白在卵形疟原虫感染者血清中的抗原反应性。采用GraphPad Prism 5.0软件和Microsoft Excel 2016软件进行统计学分析,组间差异比较采用成组t检验。结果 PCR扩增结果显示,Pocmsp1 N端和Powmsp1 N端片段大小均为1 068 bp,与预期大小一致。PCR产物经克隆、诱导并纯化后,所获rPocMSP1和rPowMSP1 N端蛋白浓度分别为0.5 mg/ml和1.0 mg/ml。SDS-PAGE结果显示,rPocMSP1和rPowMSP1 N端的相对分子质量（M_r）分别约为46 000和59 000,Western blotting结果证实蛋白成功表达。免疫组小鼠血清均可特异性识别相应抗原。ELISA结果显示,在免疫后第7天检测到特异性IgG抗体,纯化的rPocMSP1 N端蛋白和rPowMSP1 N端蛋白均与IgG发生特异性反应,与阴性对照组相比差异均有统计学意义（t = 5.824、25.98,P < 0.01）;初次免疫后第28天,rPocMSP1 N端和rPowMSP1 N端蛋白免疫组小鼠血清A₄₅₀值分别为1.043 ± 0.390和1.923 ± 1.373;IgG抗体水平持续上升至免疫后第49天,rPocMSP1 N端和rPowMSP1 N端蛋白免疫组小鼠血清A₄₅₀值分别为1.217 ± 0.365和2.463 ± 0.983。rPoMSP1 N端在小鼠体内中诱导了较高的抗体应答,抗体滴度为1 ∶ 640 000至1 ∶ 1 280 000。ELISA结果表明,用rPoMSP1 N端蛋白免疫的小鼠均诱导出高亲和力的IgG抗体,rPocMSP1 N端和rPowMSP1 N端免疫小鼠血清抗体亲和指数分别为97.11%和75.72%。Western blotting结果显示,rPocMSP1 N端免疫组小鼠血清中IgG抗体可以识别rPowMSP1 N端蛋白,rPowMSP1 N端免疫组小鼠血清中IgG抗体可以识别rPocMSP1 N端蛋白,两者存在交叉反应。蛋白芯片分析结果显示,rPocMSP1 N端蛋白识别卵形疟原虫感染者血清的敏感性为83.33%、特异性为57.14%,rPowMSP1 N端识别感染者血清的敏感性为97.62%、特异性为54.76%。rPocMSP1 N端、rPowMSP1 N端均与卵形疟原虫感染者血清有反应,与健康人血清相比,差异具有统计学意义（t = 5.896、10.42,P < 0.01）。结论 rPoMSP 1 N端蛋白具有良好的免疫原性,可诱导小鼠产生体液免疫应答,与卵形疟原虫感染者血清抗体反应上具有良好的抗原性。

关键词: 卵形疟原虫, 裂殖子表面蛋白1, 免疫原性, 抗原性

Abstract:

Objective This study aims to express the merozoite surface protein 1 N-terminal proteins of Plasmodium ovale curtisi and P. ovale wallikeri, and analyze their antigenicity and immunogenicity, revealing the potential for being as vaccine candidates of P. ovale. Methods The N-terminal of the Pomsp1 gene was amplified from the genomic DNA of P. ovale. The purified N-terminal sequences of Pocmsp1 and Powmsp1 were separately connected to the plasmid pET30a and pET32a and then transfected into DH5α competent cells. After verification with BamHⅠ and XhoⅠ enzyme digestion and DNA sequencing, the gene sequences were transferred into Escherichia coli BL21 (DE3) pLysS. After induction with 0.1 mmol/L IPTG, the expressed proteins were collected, purified, and verified with SDS-PAGE and Western blotting. Fifteen BALB/c mice were randomly assigned into three groups of 5 each: the rPocMSP1 N-terminal protein group, rPowMSP1 N-terminal protein group, and a negative control group. The mice of the three groups were injected intraperitoneally with the recombinant protein of rPocMSP1 N-terminal and rPowMSP1 N-terminal protein (50 μg of recombinant protein emulsified with Freund’s complete adjuvant) respectively, while the control group mice were injected with PBS. On 21d and 42d after primary immunization, the mice were boosted with the corresponding antigens emulsified with Freund’s incomplete adjuvant. Furthermore, on days 0, 7, 28, and 49 after immunization, tail vein blood samples were collected for serum preparation. ELISA and Western blotting were used to determine the serum specific IgG, analyze antibody titer and antibody affinity index, thereby to evaluate the immunogenicity of rPocMSP1 N-terminal and rPowMSP1 N-terminal proteins. Western blotting was used to determine the cross-reaction of the two recombinant proteins, and protein array was used to analyze their antigenicity in the serum of examinees infected with P. ovale. Results PCR demonstrated that the sequence length of PocMSP1 N-terminal and PowMSP1 N-terminal fragment was 1 068 bp, showing concordant with the expected size. Produced by PCR cloning, expression and purification, the concentration of rPocMSP1 N-terminal and rPowMSP1 N-terminal recombinant protein was 0.5 mg/ml and 1.0 mg/ml respectively. SDS-PAGE showed that the relative molecular mass of the purified rPocMSP1 N-terminal and rPowMSP1 N-terminal protein was 46 000 and 59 000, respectively, and Western blotting indicated the recombinant proteins were successfully expressed. The sera of immunized mice could recognize the corresponding antigens. ELISA detected specific IgG antibodies on 7 d after immunization, revealing specific reaction between the purified recombinant proteins and IgG, which was significantly different compared with that in the negative control group (rPocMSP1 N-terminal: t = 5.824, P < 0.01; rPowMSP1 N-terminal: t = 25.98, P < 0.01). On 28 d after immunization, the mean A₄₅₀ values for serum IgG in groups rPocMSP1 N-terminal and rPowMSP1 N-terminal were 1.043 ± 0.390, and 1.923 ± 1.373, and when the IgG levels continued to rise up to 49 d after immunization the mean A₄₅₀ values for serum IgG in rPocMSP1 N-terminal was 1.217 ± 0.365, and rPowMSP1 N-terminal was 2.463 ± 0.983. rPoMSP1 N-terminal protein induced considerable immune response in mice, with the antibody titer of 1 ∶ 640 000 and 1 ∶ 1 280 000, respectively.ELISA revealed that rPocMSP1 N-terminal and rPowMSP1 N-terminal proteins induced IgG antibody with high affinities in immunized mice, showing the affinity 97.11% by rPocMSP1 N-terminal protein, and 75.72% by rPowMSP1 N-terminal protein. Western blotting showed that the serum IgG antibody in mice immunized with rPocMSP1 N-terminal could recognize rPowMSP1 N-terminal antigen, and vice versa, the antibody in mice immunized with rPowMSP1 N-terminal antigen could recognize rPocMSP1 N-terminal antigen, demonstrating the two antigens have cross reaction property. Analysis with protein array showed that tested with rPocMSP1 N-terminal protein using P. ovale, the sensitivity and specificity was 83.33% and 57.14%, respectively; while rPowMSP1 N-terminal protein presented 97.62% of sensitivity and 54.76% of specificity; in comparison with the reaction using the sera from normal persons, the difference was statistically significant(t = 5.896, 10.42, P < 0.01). Conclusion rPoMSP1 N-terminal protein showed good immunogenicity, inducing humoral immune response in mice, and displaying significant antigenisity in reacting with the serum of people infected with P. ovale.

Key words: Plasmodium ovale, Merozoite surface protein 1, Immunogenicity, Antigenicity

中图分类号:

R382.31

于嘉利, 刘蕾, 杨博, 楚瑞林, 孙毅凡, 刘耀宝, 程洋. 重组卵形疟原虫裂殖子表面蛋白1 N端的抗原性及免疫原性分析[J]. 中国寄生虫学与寄生虫病杂志, 2021, 39(6): 746-752.

YU Jia-li, LIU Lei, YANG Bo, CHU Rui-lin, SUN Yi-fan, LIU Yao-bao, CHENG Yang. Antigenicity and immunogenicity analysis of the recombinant merozoite surface protein 1 N-terminal of Plasmodium ovale[J]. Chinese Journal of Parasitology and Parasitic Diseases, 2021, 39(6): 746-752.

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参考文献 23

[1]	World Health Organization. World Malaria Report 2021[R]. Geneva: World Health Organization, 2021.
[2]	Zhang L, Feng J, Tu H, et al. Malaria epidemiology in China in 2020[J]. Chin J Parasitol Parasit Dis, 2021, 39(2): 195-199. (in Chinese)
[2]	(张丽, 丰俊, 涂宏, 等. 2020年全国疟疾疫情分析[J]. 中国寄生虫学与寄生虫病杂志, 2021, 39(2): 195-199.)
[3]	Feng J, Zhou SS. From control to elimination: the historical retrospect of malaria control and prevention in China[J]. Chin J Parasitol Parasit Dis, 2019, 37(5): 505-513. (in Chinese)
[3]	(丰俊, 周水森. 从控制走向消除: 我国疟疾防控的历史回顾[J]. 中国寄生虫学与寄生虫病杂志, 2019, 37(5): 505-513.)
[4]	Wang J, Shen Y, Li Y, et al. Recent progress in immune checkpoint molecules in Plasmodium infection and immunity[J]. Chin J Parasitol Parasit Dis, 2019, 37(4): 472-480. (in Chinese)
[4]	(王军, 沈燕, 李悦, 等. 免疫检查点分子调控在疟原虫感染与免疫中的研究进展[J]. 中国寄生虫学与寄生虫病杂志, 2019, 37(4): 472-480.)
[5]	Baldwin MR, Li X, Hanada T, et al. Merozoite surface protein 1 recognition of host glycophorin a mediates malaria parasite invasion of red blood cells[J]. Blood, 2015, 125(17): 2704-2711.
[6]	Holder AA. The precursor to major merozoite surface antigens: structure and role in immunity[J]. Prog Allergy, 1988, 41: 72-97.
[7]	Blackman MJ, Holder AA. Secondary processing of the Plasmodium falciparum merozoite surface protein-1 (MSP1) by a calcium-dependent membrane-bound serine protease: shedding of MSP1₃₃ as a noncovalently associated complex with other fragments of the MSP1[J]. Mol Biochem Parasitol, 1992, 50(2): 307-315.
[8]	Thái TL, Jun H, Lee J, et al. Genetic diversity of merozoite surface protein-1 C-terminal 42 kDa of Plasmodium falciparum (PfMSP-1₄₂) may be greater than previously known in global isolates[J]. Parasit Vectors, 2018, 11(1): 455.
[9]	Soares IS, Levitus G, Souza JM, et al. Acquired immune responses to the N- and C-terminal regions of Plasmodium vivax merozoite surface protein 1 in individuals exposed to malaria[J]. Infect Immun, 1997, 65(5): 1606-1614.
[10]	Versiani FG, Almeida ME, Mariuba LA, et al. N-terminal Plasmodium vivax merozoite surface protein-1, a potential subunit for malaria vivax vaccine[J]. Clin Dev Immunol, 2013, 2013: 965841.
[11]	Elizardez YB, Fotoran WL, Junior AJG, et al. Recombinant proteins of Plasmodium malariae merozoite surface protein 1 (PmMSP1): testing immunogenicity in the BALB/c model and potential use as diagnostic tool[J]. PLoS One, 2019, 14(7): e0219629.
[12]	Chu R, Zhang X, Xu S, et al. Limited genetic diversity of N-terminal of merozoite surface protein-1 (MSP-1) in Plasmodium ovale curtisi and P. ovale wallikeri imported from Africa to China[J]. Parasit Vectors, 2018, 11(1): 596.
[13]	Chen J, Liu YB, Tang F, et al. Polymorphism analysis of K13 gene of Plasmodium ovale isolates from Africa[J]. Chin J Parasitol Parasit Dis, 2019, 37(2): 167-172. (in Chinese)
[13]	(陈静, 刘耀宝, 唐凤, 等. 卵形疟原虫非洲分离株K13基因的多态性分析[J]. 中国寄生虫学与寄生虫病杂志, 2019, 37(2): 167-172.)
[14]	Peng H, Wang YY, Zhou AG, et al. Enhancement of immunogenicity of Plasmodium falciparum antigens by combination of CpG ODN protein with montanide ISA720 adjuvant[J]. Chin Trop Med, 2010, 10(7): 786-788. (in Chinese)
[14]	(彭恒, 王颖玉, 周爱国, 等. ISA720与CpG联合佐剂增强恶性疟原虫抗原的免疫原性[J]. 中国热带医学, 2010, 10(7): 786-788.)
[15]	Mamillapalli A, Sunil S, Diwan SS, et al. Polymorphism and epitope sharing between the alleles of merozoite surface protein-1 of Plasmodium falciparum among Indian isolates[J]. Malar J, 2007, 6: 95.
[16]	Takala SL, Coulibaly D, Thera MA,, et al. Extreme polymorphism in a vaccine antigen and risk of clinical malaria: implications for vaccine development[J]. Sci Transl Med, 2009, 1(2): 2ra5.
[17]	Duffy PE, Patrick GJ. Malaria vaccines since 2000: progress, priorities, products[J]. Npj Vaccines, 2020, 5(1): 1-9.
[18]	Read AF, Baigent SJ, Powers C, et al. Imperfect vaccination can enhance the transmission of highly virulent pathogens[J]. PLoS Biol, 2015, 13(7): e1002198.
[19]	Qian F, Xu HJ. Malaria conjugate vaccine[J]. Chin J Parasitol Parasit Dis, 2012, 30(5): 393-395, 400. (in Chinese)
[19]	(钱锋, 徐沪济. 疟疾偶联疫苗[J]. 中国寄生虫学与寄生虫病杂志, 2012, 30(5): 393-395, 400.)
[20]	Chen JT, Li J, Zha GC, et al. Genetic diversity and allele frequencies of Plasmodium falciparum msp1 and msp2 in parasite isolates from Bioko Island, Equatorial Guinea[J]. Malar J, 2018, 17: 458.
[21]	Soares LA, Evangelista J, Orlandi PP, et al. Genetic diversity of MSP1 Block 2 of Plasmodium vivax isolates from Manaus (central Brazilian Amazon)[J]. J Immunol Res, 2014, 2014: 671050.
[22]	Noranate N, Prugnolle F, Jouin H, et al. Population diversity and antibody selective pressure to Plasmodium falciparum MSP1 block 2 locus in an African malaria-endemic setting[J]. BMC Microbiol, 2009, 9: 219.
[23]	Cheng Y, Wang B, Sattabongkot J, et al. Immunogenicity and antigenicity of Plasmodium vivax merozoite surface protein 10[J]. Parasitol Res, 2014, 113(7): 2559-2568.

重组卵形疟原虫裂殖子表面蛋白1 N端的抗原性及免疫原性分析

Antigenicity and immunogenicity analysis of the recombinant merozoite surface protein 1 N-terminal of Plasmodium ovale

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[15]	黄炳成，徐超，李瑾，肖婷，尹昆，刘功振，王卫艳，赵桂华，魏艳彬，王用斌，赵长磊，魏庆宽* . 巢式PCR技术在输入性卵形疟诊断中的应用研究[J]. 中国寄生虫学与寄生虫病杂志, 2015, 33(1): 10-49-51.