Hostname: page-component-78c5997874-v9fdk Total loading time: 0 Render date: 2024-11-19T22:10:51.351Z Has data issue: false hasContentIssue false

A concise review of poultry vaccination and future implementation of plant-based vaccines

Published online by Cambridge University Press:  30 June 2017

N. SHAHID*
Affiliation:
Centre of Excellence in Molecular Biology, University of the Punjab, 87-West Canal Bank Road Lahore-53700, Pakistan
A.Q. RAO
Affiliation:
Centre of Excellence in Molecular Biology, University of the Punjab, 87-West Canal Bank Road Lahore-53700, Pakistan
P.E. KRISTEN
Affiliation:
Department of Biochemistry, School of Dental Medicine University of Pennsylvania, Philadelphia, PA 19104, USA
M.A. ALI
Affiliation:
Centre of Excellence in Molecular Biology, University of the Punjab, 87-West Canal Bank Road Lahore-53700, Pakistan
B. TABASSUM
Affiliation:
Centre of Excellence in Molecular Biology, University of the Punjab, 87-West Canal Bank Road Lahore-53700, Pakistan
S. UMAR
Affiliation:
Department of Pathology, PMAS, Arid Agriculture University Rawalpindi, Pakistan
S. TAHIR
Affiliation:
Centre of Excellence in Molecular Biology, University of the Punjab, 87-West Canal Bank Road Lahore-53700, Pakistan
A. LATIF
Affiliation:
Centre of Excellence in Molecular Biology, University of the Punjab, 87-West Canal Bank Road Lahore-53700, Pakistan
A. AHAD
Affiliation:
Centre of Excellence in Molecular Biology, University of the Punjab, 87-West Canal Bank Road Lahore-53700, Pakistan
A.A. SHAHID
Affiliation:
Centre of Excellence in Molecular Biology, University of the Punjab, 87-West Canal Bank Road Lahore-53700, Pakistan
T. HUSNAIN
Affiliation:
Centre of Excellence in Molecular Biology, University of the Punjab, 87-West Canal Bank Road Lahore-53700, Pakistan
*
Corresponding author: [email protected]
Get access

Abstract

Every year the growth of the poultry industry is severely threatened by a number of infectious viral, bacterial and parasitic diseases. There are a number of vaccines to control these diseases including inactivated virus vaccines, attenuated virus vaccines, live virus vaccines, and subunit vaccines, but they are often relatively expensive and require cold storage and trained people to administer them, especially in developing countries. Plant-based vaccines provide a better option to control these diseases in low profit margin poultry industry. Still there are some challenges in the field of plant-based, so called ‘green’ vaccines. Injection-based oral priming is a big challenge for commercialisation of green vaccines so, new techniques are needed in the field of plant-based vaccine to pass these barriers for commercialisation. This discusses the potential for plant-based vaccines and whether they are good option to control poultry diseases.

Type
Reviews
Copyright
Copyright © World's Poultry Science Association 2017 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

ABEDULLAH, M. and BUKHSH, K. (2007) Issues and economics of poultry production: A case study of Faisalabad Pakistan. Pakistan Veterinary Journal 27: 25-28.Google Scholar
AINI, I. (2013) Diseases in rural family chickens in south-east Asia. Proceedings of the INFPDE-Conference, pp. 37.Google Scholar
ALEXANDER, D.J. (2012) Newcastle disease (Springer Science & Business Media).Google Scholar
ALEXANDER, D.J., ALDOUS, E.W. and FULLER, C.M. (2012) The long view: A selective review of 40 years of newcastle disease research. Avian Pathology 41: 329-335.Google Scholar
ALI, A. and KHAN, M. (2013) Livestock ownership in ensuring rural household food security in Pakistan. The Journl of Animal & Plant Science 23: 313-318.Google Scholar
ARMOUR, N.K. and GARCÍA, M. (2014) Current and future applications of viral-vectored recombinant vaccines in poultry. The poultry informed professional. Department of Population Health, University of Georgia, Athens, GA: 1-9.Google Scholar
ASHRAF, A. and SHAH, M. (2014) Newcastle disease: Present status and future challenges for developing countries. African Journal of Microbiology Research 8: 411-416.Google Scholar
ASWATHI, P.B., BHANJA, S.K., YADAV, A.S., REKHA, V., JOHN, J.K., GOPINATH, D., SADANANDAN, G.V., SHINDE, A. and JACOB, A. (2014) Plant based edible vaccines against poultry diseases: A review. Advances in Animal and Veterinary Sciences 2 (5): 305-311.Google Scholar
BALACHANDRAN, P., SRINIVASAN, P., SIVASEELAN, S., BALASUBRAMANLAM, G. and MUTHY, T.G.K. (2014) Isolation and characterization of newcastle disease virus from vaccinated commercial layer chicken. Veterinary World 7: 457-462.Google Scholar
BELOVA, A.V., SMUTKA, L. and ROSOCHATECKÁ, E. (2013) World chicken meat market–its development and current status. Acta Universitatis Agriculturae et Silviculturae Mendelianae Brunensis 60: 15-30.CrossRefGoogle Scholar
BERINSTEIN, A., VAZQUEZ-ROVERE, C., ASURMENDI, S., GÓMEZ, E., ZANETTI, F., ZABAL, O., TOZZINI, A., GRAND, D. C., TABOGA, O. and CALAMANTE, G. (2005) Mucosal and systemic immunization elicited by newcastle disease virus (ndv) transgenic plants as antigens. Vaccine 23: 5583-5589.Google Scholar
CHAN, H.T. and DANIELL, H. (2015) Plant‐made oral vaccines against human infectious diseases - are we there yet? Plant Biotechnology Journal 13: 1056-1070.Google Scholar
CHANSIRIPORNCHAI, N., WANASAWAENG, W., WONGCHIDWAN, N., CHAICHOTE, S. and SASIPREEYAJAN, J. (2012) Application of real-time polymerase chain reaction for quantitative detection of chicken infectious anaemia virus. The Thai Journal of Veterinary Medicine 42: 533.CrossRefGoogle Scholar
CHEN, T.-H., CHEN, T.-H., HU, C.-C., LIAO, J.-T., LEE, C.-W., LIAO, J.-W., LIN, M.-Y., LIU, H.-J., WANG, M.-Y. and LIN, N.-S. (2012) Induction of protective immunity in chickens immunized with plant-made chimeric bamboo mosaic virus particles expressing very virulent infectious bursal disease virus antigen. Virus Research 166: 109-115.Google Scholar
CONAN, A., GOUTARD, F.L., SORN, S. and VONG, S. (2012) Biosecurity measures for backyard poultry in developing countries: A systematic review. BMC Veterinary Research 8: 240.Google Scholar
D'AOUST, M.A., LAVOIE, P.O., COUTURE, M.M.J., TRÉPANIER, S., GUAY, J.M., DARGIS, M., MONGRAND, S., LANDRY, N., WARD, B.J. and VÉZINA, L.P. (2008) Influenza virus‐like particles produced by transient expression in nicotiana benthamiana induce a protective immune response against a lethal viral challenge in mice. Plant Biotechnology Journal 6: 930-940.Google Scholar
DE PAIVA, J., PENHA FILHO, R., ARGÜELLO, Y., DA SILVA, M., GARDIN, Y., RESENDE, F., BERCHIERI, A. (Jr) and SESTI, L. (2009) Efficacy of several salmonella vaccination programs against experimental challenge with salmonella gallinarum in commercial brown layer and broiler breeder hens. Revista Brasileira de Ciência Avícola 11: 65-72.Google Scholar
DOU, W., LI, H., CHENG, Z., ZHAO, P., LIU, J., CUI, Z., LIU, H., JING, W. and GUO, H. (2013) Maternal antibody induced by recombinant gp85 protein vaccine adjuvanted with cpg-odn protects against alv-j early infection in chickens. Vaccine 31: 6144-6149.CrossRefGoogle ScholarPubMed
ESAKI, M., GODOY, A., ROSENBERGER, J.K., ROSENBERGER, S.C., GARDIN, Y., YASUDA, A. and DORSEY, K.M. (2013) Protection and antibody response caused by turkey herpesvirus vector newcastle disease vaccine. Avian Diseases 57: 750-755.Google Scholar
FERRARO, B., MORROW, M.P., HUTNICK, N.A., SHIN, T.H., LUCKE, C.E. and WEINER, D.B. (2011) Clinical applications of DNA vaccines: Current progress. Clinical Infectious Diseases 53: 296-302.Google Scholar
FIRSOV, A., TARASENKO, I., MITIOUCHKINA, T., ISMAILOVA, N., SHALOIKO, L., VAINSTEIN, A. and DOLGOV, S. (2015) High-yield expression of m2e peptide of avian influenza virus h5n1 in transgenic duckweed plants. Molecular Biotechnology 57: 653-661.Google Scholar
GÓMEZ, E., ZOTH, S.C. and BERINSTEIN, A. (2009) Plant-based vaccines for potential human application. Human Vaccines 5: 738-744.Google Scholar
GUERRERO-ANDRADE, O., LOZA-RUBIO, E., OLIVERA-FLORES, T., FEHÉRVÁRI-BONE, T. and GÓMEZ-LIM, M.A. (2006) Expression of the newcastle disease virus fusion protein in transgenic maize and immunological studies. Transgenic Research 15: 455-463.CrossRefGoogle ScholarPubMed
GUO, Q.-Q., ZHANG, Z.-L., JIANG, S.-J., MA, J.-T., XUE, W.-T. and WU, Y.-M. (2012) Expression of an avian influenza virus (h5n1) hemagglutinin gene in transgenic lotus corniculatus. Plant Molecular Biology Reporter 30: 1117-1124.Google Scholar
HAHN, B.-S., JEON, I.-S., JUNG, Y.-J., KIM, J.-B., PARK, J.-S., HA, S.-H., KIM, K.-H., KIM, H.-M., YANG, J.-S. and KIM, Y.-H. (2007) Expression of hemagglutinin-neuraminidase protein of newcastle disease virus in transgenic tobacco. Plant Biotechnology Reports 1: 85-92.CrossRefGoogle Scholar
HOLTZ, B.R., BERQUIST, B.R., BENNETT, L.D., KOMMINENI, V.J., MUNIGUNTI, R.K., WHITE, E.L., WILKERSON, D.C., WONG, K.Y.I., LY, L.H. and MARCEL, S. (2015) Commercial‐scale biotherapeutics manufacturing facility for plant‐made pharmaceuticals. Plant Biotechnology Journal 13: 1180-1190.Google Scholar
HUANG, L.-K., LIAO, S.-C., CHANG, C.-C. and LIU, H.-J. (2006) Expression of avian reovirus σc protein in transgenic plants. Journal of Virological Methods 134: 217-222.CrossRefGoogle ScholarPubMed
ISLAM, M., KHAN, M., ISLAM, M., KAYESH, M., KARIM, M., GANI, M. and KABIR, A. (2008) Comparative efficacy of imported fowl pox virus vaccine with locally produced one in backyard chicks. Bangladesh Journal of Veterinary Medicine 6: 23-26.Google Scholar
KELEMEN, M., FORGÁCH, K., IVÁN, J., PALYA, V., SÜVEGES, T., TOTH, B. and MESZAROS, J. (2000) Pathological and immunological study of an in ovo complex vaccine against infectious bursal disease. Acta Veterinaria Hungarica 48: 443-454.Google Scholar
KWON, K.C. and DANIELL, H. (2015) Low‐cost oral delivery of protein drugs bioencapsulated in plant cells. Plant Biotechnology Journal 13: 1017-1022.Google Scholar
LACORTE, C., LOHUIS, H., GOLDBACH, R. and PRINS, M. (2007) Assessing the expression of chicken anaemia virus proteins in plants. Virus Research 129: 80-86.Google Scholar
LAI, K.S., YUSOFF, K. and MAHMOOD, M. (2013) Functional ectodomain of the hemagglutinin-neuraminidase protein is expressed in transgenic tobacco cells as a candidate vaccine against newcastle disease virus. Plant Cell, Tissue and Organ Culture (PCTOC) 112: 117-121.Google Scholar
LAMICHHANE, A., AZEGAMI, T. and KIYONO, H. (2014) The mucosal immune system for vaccine development. Vaccine 32: 6711-6723.Google Scholar
LEE, E.H. and AL-ATTAR, M. (2010) Gel droplets for the delivery of poultry vaccines in the barns. Proceedings of the Proceeding of the Fifty-Ninth Western Poultry Disease Conference. Vancouver, BC, Canada, pp. 72-74.Google Scholar
LEE, G., NA, Y.J., YANG, B.G., CHOI, J.P., SEO, Y.B., HONG, C.P., YUN, C.H., KIM, D.H., SOHN, E.J. and KIM, J.H. (2015) Oral immunization of hemagglutinin h5 expressed in plant endoplasmic reticulum with adjuvant saponin protects mice against highly pathogenic avian influenza a virus infection. Plant Biotechnology Journal 13: 62-72.Google Scholar
LOSSL, A.G. and WAHEED, M.T. (2011) Chloroplast‐derived vaccines against human diseases: Achievements, challenges and scopes. Plant Biotechnology Journal 9: 527-539.CrossRefGoogle ScholarPubMed
LOZA-RUBIO, E. and ROJAS-ANAYA, E. (2010) Vaccine production in plant systems—an aid to the control of viral diseases in domestic animals: A review. Acta Veterinaria Hungarica 58: 511-522.CrossRefGoogle Scholar
MASON, H.S., WARZECHA, H., MOR, T. and ARNTZEN, C.J. (2002) Edible plant vaccines: Applications for prophylactic and therapeutic molecular medicine. Trends in molecular medicine 8: 324-329.Google Scholar
MENGESHA, M. (2012) The issue of feed-food competition and chicken production for the demands of foods of animal origin. Asian Journal of Poultry Science 6: 31-43.Google Scholar
MOHTAR, S.H., LOH, H.-S., MASSAWE, F. and OMAR, A.R. (2013) Antigenicity and immunogenicity evaluations of plant-based vp2 protein of Malaysian highly virulent infectious bursal disease virus (hvibdv) expressed in nicotiana tabacum. Journal of Agriculture and Veterinary Science 2 (6): 64-72.Google Scholar
MOREKI, J., DIKEME, R. and POROGA, B. (2010) The role of village poultry in food security and hiv/aids mitigation in Chobe district of Botswana. Livestock Research for Rural Development 22.Google Scholar
NOCHI, T., TAKAGI, H., YUKI, Y., YANG, L., MASUMURA, T., MEJIMA, M., NAKANISHI, U., MATSUMURA, A., UOZUMI, A. and HIROI, T. (2007) Rice-based mucosal vaccine as a global strategy for cold-chain-and needle-free vaccination. Proceedings of the National Academy of Sciences 104: 10986-10991.Google Scholar
PAKPINYO, S., WANARATANA, S., SANGTHONGDANG, K. and PANIAGO, M. (2013) Efficacy and safety of different live mycoplasma gallisepticum vaccines in layer chickens. Thai Journal of Veterinary Medicine 43: 533.Google Scholar
PALYA, V., TATÁR-KIS, T., MATÓ, T., FELFÖLDI, B., KOVÁCS, E. and GARDIN, Y. (2014) Onset and long-term duration of immunity provided by a single vaccination with a turkey herpesvirus vector and vaccine in commercial layers. Veterinary Immunology and Immunopathology 158: 105-115.Google Scholar
PRADHAN, S.N., PRINCE, P.R., MADHUMATHI, J., ROY, P., NARAYANAN, R.B. and ANTONY, U. (2012) Protective immune responses of recombinant vp2 subunit antigen of infectious bursal disease virus in chickens. Veterinary Immunology and Immunopathology 148: 293-301.CrossRefGoogle ScholarPubMed
RAUW, F., GARDIN, Y., PALYA, V., VAN BORM, S., GONZE, M., LEMAIRE, S., VAN DEN BERG, T. and LAMBRECHT, B. (2009) Humoral, cell-mediated and mucosal immunity induced by oculo-nasal vaccination of one-day-old spf and conventional layer chicks with two different live newcastle disease vaccines. Vaccine 27: 3631-3642.Google Scholar
REHMAN, Z., MENG, C., UMAR, S., MUNIR, M. and DING, C. (2016) Interaction of infectious bursal disease virus with the immune system of poultry. World's Poultry Science Journal 72: 805-820.Google Scholar
RYAN, M.P. and WALSH, G. (2012) Veterinary-based biopharmaceuticals. Trends in Biotechnology 30: 615.Google Scholar
SACK, M., HOFBAUER, A., FISCHER, R. and STOGER, E. (2015) The increasing value of plant-made proteins. Current Opinion in Biotechnology 32: 163-170.Google Scholar
SARWAR, F., USMAN, M., UMAR, S., HASSAN, M., REHMAN, A. and RASHID, A. (2015) Some aspects of backyard poultry management practices in rural areas of district Rawalpindi, Pakistan. International Journal of Livestock Research 5: 14-20.Google Scholar
SATHISH, K., SRIRAMAN, R., SUBRAMANIAN, B.M., RAO, N.H., KASA, B., DONIKENI, J., NARASU, M.L. and SRINIVASAN, V. (2012) Plant expressed coccidial antigens as potential vaccine candidates in protecting chicken against coccidiosis. Vaccine 30: 4460-4464.Google Scholar
SHAHID, N. and DANIELL, H. (2016) Plant based oral vaccines against zoonotic and non‐zoonotic diseases. Plant Biotechnology Journal 14 (11): 2079-2099.Google Scholar
SHAHRIARI, A.G., BAGHERI, A., BASSAMI, M.R., MALEKZADEH SHAFAROUDI, S. and AFSHARIFAR, A.R. (2015) Cloning and expression of fusion (f) and haemagglutinin-neuraminidase (hn) epitopes in hairy roots of tobacco (nicotiana tabaccum) as a step toward developing a candidate recombinant vaccine against newcastle disease. Journal of Cell and Molecular Research 7: 11-18.Google Scholar
SHIL, N., MAHMUD, M., AMIN, M. and HOSSAIN, M.A. (2012) Comparative analysis of haemagglutination inhibition antibody production against three lentogenic newcastle disease virus vaccines in broiler chicks. Bangladesh Journal of Microbiology 28: 41-43.Google Scholar
SHOJI, Y., FARRANCE, C.E., BAUTISTA, J., BI, H., MUSIYCHUK, K., HORSEY, A., PARK, H., JAJE, J., GREEN, B.J. and SHAMLOUL, M. (2012) A plant‐based system for rapid production of influenza vaccine antigens. Influenza and other respiratory viruses 6: 204-210.Google Scholar
SHOJI, Y., JONES, R.M., METT, V., CHICHESTER, J.A., MUSIYCHUK, K., SUN, X., TUMPEY, T.M., GREEN, B.J., SHAMLOUL, M. and NORIKANE, J. (2013) A plant-produced h1n1 trimeric hemagglutinin protects mice from a lethal influenza virus challenge. Human Vaccines & Immunotherapeutics 9: 553-560.Google Scholar
SONG LAI, K., YUSOFF, K. and MAHMOOD, M. (2012) Heterologous expression of hemagglutinin-neuraminidase protein from newcastle disease virus strain af2240 in centella asiatica. Acta Biologica Cracoviensia Series Botanica 54: 142-147.Google Scholar
SU, J., ZHU, L., SHERMAN, A., WANG, X., LIN, S., KAMESH, A., NORIKANE, J.H., STREATFIELD, S.J., HERZOG, R.W. and DANIELL, H. (2015) Low cost industrial production of coagulation factor ix bioencapsulated in lettuce cells for oral tolerance induction in hemophilia b. Biomaterials 70: 84-93.Google Scholar
TOPP, E., IRWIN, R., MCALLISTER, T., LESSARD, M., JOENSUU, J.J., KOLOTILIN, I., CONRAD, U., STÖGER, E., MOR, T. and WARZECHA, H. (2016) The case for plant-made veterinary immunotherapeutics. Biotechnology Advances 34: (5) 597-604.CrossRefGoogle ScholarPubMed
UMAR, S., GUÉRIN, J.-L. and DUCATEZ, M. (2016) Low pathogenic avian influenza and co-infecting pathogens: A review of experimental infections in avian models. Avian Diseases 61: (1) 3-15.Google Scholar
UMAR, S., ULLAH, S., YAQOOB, M., SHAH, M. and DUCATEZ, M. (2014) Chicken infectious anaemia, an immunosuppressive disease of poultry birds. World's Poultry Science Journal 70: 759-766.Google Scholar
VERMA, D., MOGHIMI, B., LODUCA, P.A., SINGH, H.D., HOFFMAN, B.E., HERZOG, R.W. and DANIELL, H. (2010) Oral delivery of bioencapsulated coagulation factor ix prevents inhibitor formation and fatal anaphylaxis in hemophilia b mice. Proceedings of the National Academy of Sciences 107: 7101-7106.Google Scholar
WU, H., SCISSUM-GUNN, K., SINGH, N.K. and GIAMBRONE, J.J. (2009) Toward the development of a plant-based vaccine against reovirus. Avian Diseases 53: 376-381.Google Scholar
WU, H., SINGH, N.K., LOCY, R.D., SCISSUM-GUNN, K. and GIAMBRONE, J.J. (2004) Immunization of chickens with vp2 protein of infectious bursal disease virus expressed in arabidopsis thaliana. Avian diseases 48: 663-668.Google Scholar
WU, J., YU, L., LI, L., HU, J., ZHOU, J. and ZHOU, X. (2007) Oral immunization with transgenic rice seeds expressing vp2 protein of infectious bursal disease virus induces protective immune responses in chickens. Plant Biotechnology Journal 5: 570-578.Google Scholar
XIAO, Y., KWON, K.-C., HOFFMAN, B.E., KAMESH, A., JONES, N.T., HERZOG, R.W. and DANIELL, H. (2016) Low cost delivery of proteins bioencapsulated in plant cells to human non-immune or immune modulatory cells. Biomaterials 80: 68-79.Google Scholar
YANG, Z.-Q., LIU, Q.-Q., PAN, Z.-M., YU, H.-X. and JIAO, X.-A. (2007) Expression of the fusion glycoprotein of Newcastle disease virus in transgenic rice and its immunogenicity in mice. Vaccine 25: 591-598.Google Scholar
YIN, G., LIN, Q., WEI, W., QIN, M., LIU, X., SUO, X. and HUANG, Z. (2014) Protective immunity against Eimeria tenella infection in chickens induced by immunization with a recombinant c-terminal derivative of etimp1. Veterinary Immunology and Immunopathology 162: 117-121.Google Scholar
ZHANG, R., WANG, X., SU, J., ZHAO, J. and ZHANG, G. (2010) Isolation and analysis of two naturally-occurring multi-recombination newcastle disease viruses in china. Virus Research 151: 45-53.Google Scholar
ZHAO, Y. and HAMMOND, R.W. (2005) Development of a candidate vaccine for newcastle disease virus by epitope display in the cucumber mosaic virus capsid protein. Biotechnology Letters 27: 375-382.Google Scholar