Research Advance on Oral Vaccine for Aquatic Animals

doi:10.13560/j.cnki.biotech.bull.1985.2017-0805

Abstract

Abstract: The application of vaccines may effectively improve their resistances against various common diseases in aquaculture，thus decrease the possibility of the incidence of diseases and infections，reduce the use of chemical drugs，eliminate the environmental pollution，and even decrease economic losses from environmental governances. Vaccination by injection is time-consuming and easily causes injuries to fishes. Vaccination by immersion needs high dosages and thus easily results in strong stress reaction. The oral vaccine can be applied to any variety and size of fish，thus may avoid the problems by injection or immersion，and it is an ideal immune approach. Among the present oral vaccines，the adjuvants like polymeric microspheres and biofilm used to prevent the antigens in vaccine from the effects of all digestive enzymes are widely applied；however，the cost is quite high in field application. Biological carrier can be a genetic engineering vaccine with antigens delivery work by non-pathogenic microorganisms，such as bacteria. These biological carrier vaccines are actually in low costs for application and induce a solid immunization effect，however，the cycle of safety evaluation is long and there is difficulty in large-scale production. This paper reviews the status and key technologies of different forms and formulations of main oral vaccines. Also the paper prospects that the study on aquatic animal oral vaccines should focus on vaccine safety and applicability in the future research work，and developing oral vaccine simultaneously in lower cost and better immunization effect.

Key words: aquatic animal, immunity, oral, vaccine, forms

LIU Shi-xu ,WANG Qing ,FANG Zhen-zhen ,CHANG Ou-qin ,ZENG Wei-wei ,HUANG Zhi-bin. Research Advance on Oral Vaccine for Aquatic Animals[J]. Biotechnology Bulletin, 2018, 34(6): 30-37.

References

[1] 马悦, 张元兴. 国外鱼类疫苗之路[J] . 海洋与渔业, 2013, 1：80-83.
[2] 王忠良, 王蓓, 鲁义善, 等. 水产疫苗研究开发现状与趋势分析[J] . 生物技术通报, 2015, 31（6）：55-59.
[3] 耿晓修. 我国水产疫苗的现状及应用前景[J] . 河北渔业, 2005（6）：1-2.
[4] 吴淑勤, 陶家发, 巩华, 等. 渔用疫苗发展现状及趋势[J] . 中国渔业质量与标准, 2014, 4（1）：1-13.
[5] 王荻, 李绍戊, 师东方, 等. 渔用疫苗递送途径研究进展[J] . 水产学杂志, 2016, 29（2）：55-60.
[6] Corbeil S, Kurath G, Lapatra SE. Fish DNA vaccine against infectious hematopoietic necrosis virus：efficacy of various routes of immunisation[J] . Fish & Shellfish Immunology, 2000, 10（8）：711-723.
[7] Nakajima N, Kawanishi M, Imamura S, et al. Development of a serology-based assay for efficacy evaluation of a lactococcicosis vaccine in Seriola fish[J] . Fish & Shellfish Immunology, 2014, 38（1）：135-139.
[8] Salgado MC, Loza RE, Rojas AE, et al. Viral vaccines for bony fish：past, present and future[J] . Expert Review of Vaccines, 2013, 12（5）：567-578.
[9] Parra D, Korytá? T, Takizawa F, et al. B cells and their role in the teleost gut[J] . Developmental & Comparative Immunology, 2016, 64：150-166.
[10] Abelli L, Picchietti S, Romano N, et al. Immunohistochemistry of gut-associated lymphoid tissue of the sea bass Dicentrarchus labrax（L.）[J] . Fish & Shellfish Immunology, 1997, 7（4）：235-245.
[11] 安伟, 肖雨, 张明辉, 等. 鱼类新型口服疫苗的研究概况[J] . 黑龙江畜牧兽医, 2015（17）：82-84.
[12] Mutoloki S, Munang AHM, Evensen ?. Oral vaccination of fish-antigen preparations, uptake, and immune induction[J] . Frontiers in Immunology, 2015, 6：519.
[13] Wong G, Kaattari SL, Christensen JM. Effectiveness of an oral enteric coated vibrio vaccine for use in Salmonid fish[J] . Immunological Investigations, 1992, 21（4）：353.
[14] Companjen AR, Florack DE, Bastiaans JH, et al. Development of a cost-effective oral vaccination method against viral disease in fish[J] . Dev Biol, 2005, 121：143-150.
[15] Rodrigues AP, Hirsch D, Figueiredo HCP, et al. Production and characterisation of alginate microparticles incorporating Aeromonas hydrophila designed for fish oral vaccination[J] . Process Biochemistry. 2006, 41（3）：638-643.
[16] 黄钧, 施金谷, 陈明, 等. 水产口服疫苗研究进展[J] . 广西畜牧兽医, 2013, 29（1）：55-57.
[17] Baker K, Lencer WI, Blumberg RS. Beyond IgA：The mucosal immunoglobulin alphabet[J] . Mucosal Immunology, 2010, 3（3）：324-325.
[18] Lazado CC, Caipang CMA. Mucosal immunity and probiotics in fish[J] . Fish & Shellfish Immunology, 2014, 39（1）：78.
[19] Ghosh B, Nguyen TD, Crosbie PB, et al. Oral vaccination of first-feeding Atlantic salmon, Salmo salar L., confers greater protection against yersiniosis than immersion vaccination[J] . Vaccine, 2015, 4（5）：599-608.
[20] Ruiz JT, Luján L, Blank M, et al. Adjuvants-and vaccines-induced autoimmunity：animal models[J] . Immunologic Research, 2017, 65（1）：55-65.
[21] Brudeseth BE, Wiulsr?d R, Fredriksen BN, et al. Status and future perspectives of vaccines for industrialised fin-fish farming[J] . Fish & Shellfish Immunology, 2013, 35（6）：1759.
[22] Romalde JL, Luzardo AA, Blanco MJ, et al. Oral immunization using alginate microparticles as a useful strategy for booster vaccination against fish lactoccocosis[J] . Aquaculture, 2004, 236（1）：119-129.
[23] 余俊红, 纪伟尚, 徐怀恕. 鲈鱼口服生物胶囊疫苗的研究[J] . 高技术通讯, 2001, 11（3）：15-18.
[24] 孙翰昌, 耿晓修, 张芬, 等. 肠型点状产气单胞菌口服疫苗对草鱼的免疫保护效应研究[J] . 西南大学学报, 2007, 29（11）：115-118.
[25] Caruffo M, Maturana C, Kambalapally S. Protective oral vaccination against infectious salmon anaemia virus in Salmo salar[J] . Fish & Shellfish Immunology, 2016, 54：54-59.
[26] 任燕, 张小江, 陶家发, 等. 壳聚糖-海藻酸盐复合微囊疫苗的制备及其对斜带石斑鱼的口服免疫效果[J] . 中国生物制品学杂志, 2015, 28（2）：110-114.
[27] Dubey S, Avadhani K, Mutalik S, et al. Edwardsiella tarda Omp A encapsulated in chitosan nanoparticles shows superior protection over inactivated whole cell vaccine in orally vaccinated fringed-lipped peninsula carp（Labeo fimbriatus）[J] . Vaccines, 2016, 4（4）：40.
[28] de las Heras AI, Rodriguez Saint-JeanS, Pérez-prieto SI. Immunogenic and protective effects of an oral DNA vaccine against infectious pancreatic necrosis virus in fish[J] . Fish & Shellfish Immunology, 2010, 28（4）：562-570.
[29] Ren Y, Zhang XJ, Chang OQ, et al. Partial characteristics of PELA-Omp K microsphere vaccine and its immune effect in Crucian carp inoculated by oral route[J] . Chinese Journal of Biologicals, 2011, 24（11）：1306-1309.
[30] Kim YB, Kim HY, Beuchat LR, et al. Development of non-pathogenic bacterial biofilms on the surface of stainless steel which are inhibitory to Salmonella enterica[J] . Food Microbiology, 2018, 69：136-142.
[31] 丁诗华, 王一丁, 彭远义, 等. 鱼用嗜水气单胞菌口服疫苗的免疫保护效应[J] . 西南大学学报, 2005, 27（6）：888-891.
[32] Josepriya TA, Chien KH, Lin HY, et al. Immobilization antigen vaccine adjuvanted by parasitic heat shock protein 70C confers high protection in fish against cryptocaryonosis[J] . Fish & Shellfish Immunology, 2015, 45（2）：517-527.
[33] Chen YM, Shih CH, Liu HC, et al. An oral nervous necrosis virus vaccine using Vibrio anguillarum as an expression host provides early protection[J] . Aquaculture, 2011, 321（1-2）：26-33.
[34] Rivas-Aravena A, Fuentes Y, Cartagena J, et al. Development of a nanoparticle-based oral vaccine for Atlantic salmon against ISAV using an alphavirus replicon as adjuvant[J] . Fish & shellfish immunology, 2015, 45（1）：157-166.
[35] 黄钧, 施金谷, 陈明, 等. 鱼用口服疫苗免疫佐剂研究进展[J] . 南方农业学报, 2012, 43（6）：869-872.
[36] Perrie Y, Crofts F, Devitt A, et al. Designing liposomal adjuvants for the next generation of vaccines[J] . Advanced Drug Delivery Reviews, 2016, 99（Pt A）：85.
[37] 王志明. 疫苗递送技术的研究进展[J] . 中国生物工程杂志, 2017（4）：98-103.
[38] Trimaille T, Verrier B. Micelle-based adjuvants for subunit vaccine delivery[J] . Vaccines, 2015, 3（4）：803-813.
[39] 李珊珊, 黄倢, 田黎. 鱼类口服疫苗的研究进展[J] . 海洋湖沼通报, 2007, （s1）：189-194.
[40] 魏克强, 许梓荣. 家蚕蛹表达对虾白斑综合征病毒囊膜蛋白Vp28和Vp19的免疫原性[J] . 中国兽医学报, 2006, 26（4）：360-362.
[41] 任鹏丽. 草鱼呼肠孤病毒外衣壳蛋白VP4保护性免疫作用的研究[D] . 中山：中山大学, 2016.
[42] 张毅. 抗口服亚单位疫苗研究及促克氏螯虾生长口服DNA药物研究[D] . 武汉：武汉大学, 2011.
[43] Jia XH, Zhang CL, Shi DJ, et al. Oral administration of Anabaena-expressed VP28 for both drug and food against white spot syndrome virus in shrimp[J] . Journal of Applied Phycology, 2016, 28（2）：1001-1009.
[44] Klug B, Robertson JS, Condit RC, et al. Adventitious agents and live viral vectored vaccines：Considerations for archiving samples of biological materials for retrospective analysis[J] . Vaccine, 2016, 4（51）.
[45] 孟庆峰, 徐展, 王伟利. 活载体疫苗的研究进展[J] . 黑龙江畜牧兽医, 2013（19）：28-31.
[46] 邹伟斌, 陈丹, 谢少霞, 等. 基因工程活载体疫苗的研究进展[J] . 广东畜牧兽医科技, 2016, 41（4）：1-5.
[47] 付天增, 郝金婷, 李宁求, 等. 迟缓爱德华菌菌蜕疫苗对罗非鱼注射和口服免疫的效果分析[J] . 水生生物学报, 2016, 40（6）：294-301.