Abstract
Since the development of hybridoma technology (Köhler and Milstein, 1975), monoclonal antibodies (mAbs) produced by the technique of somatic cell hybridization have been widely used in plant virology for diagnostics (e.g. Halk et al., 1982; Hsu et al., 1983; Jordan and Hammond, 1991; D’Arcy et al., 1989; Massalski and Harrison, 1987; Erokhina et al., 1993; Erokhina, 1995), antigenic analysis, and epitope mapping (e.g. Andreeva et al., 1994; Commandeur et al., 1992; Koenig et al., 1990; van den Heuvel et al., 1990; Erokhina et al., 2001; Gorshkova et al., 2003) or subcellular localization of viruses and viral proteins (e.g. Lesemann et al., 1990; Bandla et al., 1994; MacKenzie and Tremaine, 1988; Liu et al., 1999; Erokhina et al., 2001; Yelina et al., 2005).
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References
Andreeva, L., L. Jarvekülg, F. Rabenstein, L. Torrance, B.D. Harrison, and M. Saarma, 1994. Antigenic analysis of potato virus A particles and coat protein, Ann. Appl. Biol., 125, 337–348.
Bandla, M.D., D.M. Westcot, K.D. Chenault, D.E. Ulmann, T.L. German, and J.L. Sherwood, 1994. Use of monoclonal antibody to the nonstructural protein encoded by the small RNA of the tomato spotted wilt tospovirus to identify viruliferous thrips, Phytopathology, 84, 1427–1431.
Baum, T.J., A. Hiatt, W.A. Parrott, L.H. Pratt, and R.S. Hussey, 1996. Expression in tobacco of a functional monoclonal antibody specific to stylet secretions of the root-knot nematode, Mol. Plant Microbe Interact, 9, 382–387.
Benvenuto, E., R.J. Ordas, R. Tavazza, G. Ancora, S. Biocca, A. Cattaneo, and P. Galeffi, 1991. Phytoantibodies: A general vector for expression of immunoglobulin domains in transgenic plants, Plant Mol. Biol., 17, 865–874.
Bird, R.E., K.D. Hardman, J.W. Jacobson, S. Johnson, B.M. Kaufman, S.M. Lee, T. Lee, S.H. Pope, G.S. Riordan, and M. Whitlow, 1988. Single-chain antigen-binding proteins, Science, 242, 423–426.
Boonrod, K., D. Galetzka, P.D. Nagy, U. Conrad, and G. Krczal, 2004. Single-chain antibodies against a plant viral RNA-dependent RNA polymerase confer virus resistance, Nature Biotechnol., 22, 856–862.
Buck, K., 1996. Comparison of the replication of positive-stranded RNA viruses of plants and animals, Adv.Virus Res., 47, 159–251.
Commandeur, U., R. Koenig, D.-E. Lesemann, L. Torrance, W. Burgermeister, Y. Liu, A. Schots, M. Arlic, and G. Grassi, 1992. Epitope mapping on fragments of beet necrotic yellow vein virus coat protein, J. Gen. Virol., 73, 695–700.
Commandeur, U., R. Koenig, R. Manteuffel, L. Torrance, P. Luedecke, and R. Frank, 1994. Location, size, and complexity of epitopes on the coat protein of beet necrotic yellow vein virus studied by means of synthetic overlapping peptides, Virology, 198, 282–287.
Conrad, U., and U. Fiedler, 1998. Compartment-specific accumulation of recombinant immunoglobulins in plant cells: An essential tool for antibody production and immunomodulation of physiological functions and pathogen activity, Plant Mol. Biol., 38, 101–109.
D’Arcy, C.J., L. Torrance, and R.R. Matrin, 1989. Discrimination among luteoviruses and their strains by monoclonal antibodies and identification of common epitopes, Phytopathology, 79, 869–873.
De Jaeger, G., C. De Wide, D. Eeckhout, E. Fiers, and A. Depicker, 2000. The plantibody approach: Expression of antibody genes in plants to modulate plant metabolism or to obtain pathogen resistance, Plant Mol. Biol., 43, 419–428.
De Neve, M., M. De Loose, A. Jacobs, H. Vanhoudt, B. Kaluza, U. Weidle, M. Vanmontagu, and A. Depicker, 1993. Assembly of an antibody and its derived antibody fragment in Nicotiana and Arabidopsis, Transgenic Res., 2, 227–237.
Düring, K., S. Hippe, F. Kreuzaler, and J. Schell, 1990. Synthesis and selfassembly of a functional monoclonal antibody in transgenic Nicitiana tabacum, Plant Mol. Biol., 15, 281–293.
Erhardt, M., G. Vetter, D. Gilmer, K. Bouzoubaa, G. Richards, G. Jonard, and H. Guilley, 2005. Subcellular localization of the triple gene block movement proteins of Beet necrotic yellow vein virus by electron microscopy, Virology, 340, 155–166.
Erokhina, T.N., 1995. Monoclonal antibodies to barley yellow dwarf virus: An immuno-enzyme test system for virus diagnostics, Bioorg. Khim. (in Russian), 21, 256–260.
Erokhina, T.N., S.M. Ambrosova, Yu.A. Varitsev, Yu.S. Malofeeva, V.P. Knyazeva, and A.V. Kulyavtsev, 1993. A hybrid immuno-enzyme test system for the potato virus A detection, Bioorg. Khim. (in Russian), 19, 941–949.
Erokhina, T.N., T.B. Kastalieva, and K.A. Mozhaeva, 2002. Preparing of monoclonal antibodies against BYDV using viruses purified from naturally infected plants, Proceedings of International Symposium “Barley Yellow Dwarf Disease: Recent Advances and Future Strategies,” 1–5 Sept., El Batan, Texcoco, Mexico, pp. 101–103.
Erokhina, T.N., R.A. Zinovkin, M.V. Vitushkina, W. Jelkmann, and A.A. Agranovsky, 2000. Detection of beet yellows closterovirus methyltransferase-like and helicase-like proteins in vivo using monoclonal antibodies, J. Gen. Virol., 81, 597–603.
Erokhina, T.N., M.V. Vitushkina, R.A. Zinovkin, D.-E. Lesemann, W. Jelkmann, E.V. Koonin, and A.A. Agranovsky, 2001. Ultrastructural localization and epitope mapping of beet yellows closterovirus methyltransferase-like and helicase-like proteins, J. Gen. Virol., 82, 983–1994.
Esau, K., and L.L. Hoefert, 1971. Cytology of beet yellows virus infection in Tetragonia. I. Parenchyma cells in infected leaf, Protoplasma, 72, 255–273.
Fecker, L.F., R. Koenig, and C. Obermeier, 1997. Nicotiana benthamiana plants expressing beet necrotic yellow vein virus (BNYVV) coat protein-specific scFv are partially protected against the establishment of the virus in the early stages of infection and its pathogenic effects in the late stages of infection, Arch. Virol., 142, 1857–1863.
Fisher, R., D. Schumann, S. Zimmermann, J. Drossard, M. Sack, and S. Schillberg, 1999. Expression and characterization of bispecific single chain Fv fragments produced in transgenic plants, Eur. J. Biochem, 262, 810–816.
Geysen, H.M., S.J. Rodda, T.J. Mason, G. Tribbik, and P.G. Schoofs, 1987. Strategies for epitope analysis using peptide synthesis, J. Immunol. Methods., 102, 259–274.
Gorshkova, E.N, T.N. Erokhina, T.A. Stroganova, N.E. Yelina, A.A. Zamyatnin, Jr., N.O. Kalinina, J. Schiemann, A.G. Solovyev, and S.Yu. Morozov, 2003. Immunodetection and fluorescent microscopy of transgenically expressed hordeivirus TGBp3 movement protein reveals its association with endoplasmic reticulum elements in close proximity to plasmodesmata, J. Gen. Virol., 84, 985–994.
Halk, E.L., H.T. Hsu, and J. Aebig, 1982. Properties of virus-specific monoclonal antibodies to Prunus necrotic ringspot, apple mosaic, tobacco streak and alfalfa mosaic viruses, Phytopathology, 72, 953–959.
Hein, M.B., Y. Tang, D.A. McLeod, K.D. Janda, and A. Hiatt, 1991. Evaluation of immunoglobulins from plant cells, Biotechnol. Prog., 7, 455–461.
Hiatt, A., R. Cafferkey, and K. Bowdish, 1989. Production of antibodies in transgenic plants, Nature, 342, 76–78.
Hsu, H.T., J. Aebig, W.F. Rochow, and R.H. Lawson, 1983. Isolations of hybridomas secreting antibodies reactive to RPV and MAV isolates of Barley yellow dwarf virus and Carnation etched ring virus, Phytopathology, 73, 790.
Jordan, R., and J. Hammond, 1991. Comparison and differentiation of potyvirus isolates and identification of strain-, virus-, subgroup-specific and potyvirus group-common epitopes using monoclonal antibodies, J. Gen. Virol., 72, 25–36.
Koenig, R., U. Commandeur, D.-E. Lesemann, W. Burgermeister, L. Torrance, G. Grassi, M. Arlic, J. Kallerhoff, and A. Schots, 1990. Antigenic analysis of the coat protein of beet nec- rotic yellow vein virus by means of monoclonal antibodies, J. Gen. Virol., 71, 2229–2232.
Köhler, G., and C. Milstein, 1975. Continuous cultures of fused cells secreting antibody of predefined specificity, Nature, 256, 495–497.
Lesemann, D.-E., 1988. Cytopathology, in The Plant Viruses, edited by R.G. Milne, Plenum, New York, pp. 179–235.
Lesemann, D.-E., R. Koenig, L. Torrance, G. Buxton, P.M. Boonekamp, D. Peters, and A. Schots, 1990. Electron microscopical demonstration of different binding sites for monoclonal antibodies on particles of beet necrotic yellow vein virus, J. Gen. Virol., 71, 731–733.
Liu, F., E. Sukhacheva, T. Erokhina, and J. Schubert, 1999. Detection of potyviral nuclear inclusion b proteins by monoclonal antibodies raised to synthetic peptides, Eur. J. Plant. Pathol, 105, 389–395.
Ma, J.K.-C., A. Hiatt, M. Hein, N.D. Vine, F. Wang, P. Stabila, C. Vandolleweerd, K. Mostov, and T. Lehner, 1995. Generation and assembly of secretory antibodies in plants, Science, 268, 716–719.
MacKenzie, D.J., and J.H. Tremaine, 1988. Ultrastructural location of non-structural protein 3A of cucumber mosaic virus in infected tissue using monoclonal antibodies to a cloned chimeric fusion protein, J. Gen. Virol., 69, 2387–2395.
Massalski, P.R., and B.D. Harrison, 1987. Properties of monoclonal antibodies to potato leafroll luteovirus and their use to distinguish virus isolates differing in aphid transmissibility, J. Gen. Virol., 68, 1813–1821.
Mayo, M.A., and V. Ziegler-Graff, 1996. Molecular biology of luteoviruses, Adv. Virus Res., 46, 413–460.
Owen, M., A. Gandecha, B. Cockburn, and G. Whitelam, 1992. Synthesis of a functional anti-phytochrome single-chain Fv protein in transgenic tobacco, Biotechnology, 10, 790–794.
Peng, C.W., and V.V. Dolja, 2000. Leader proteinase of the beet yellows closterovirus: Mutation analysis of the function in genome amplification, J. Virol., 74, 9766–9770.
Peng, C.W., A.J. Napuli, and V.V. Dolja, 2003. Leader proteinase of beet yellows virus functions in long-distance transport, J. Virol., 77, 2843–2849.
Schillberg, S., S. Zimmermann, A. Voss, and R. Fisher, 1999. Apoplastic and cytosolic expression of full-size antibodies and antibody fragments in Nicotiana tabacum, Transgenic Res., 8, 255–263.
Schillberg, S., S. Zimmermann, M.-Y. Zhang, and R. Fisher, 2001. Antibody-based resistance to plant pathogens, Transgenic. Res., 10, 1–12.
Schouten, A., J. Roosien, F.A. van Engelen, G.A.M.I. de Jong, A.W.M. BorstVrenssen, J.F. Zilverentant, D. Bosch, W.J. Stiekema, F.J. Gommers, A. Schots, and J. Bakker, 1996. The C-terminal KDEL sequence increases the expression level of a single chain antibody designed to be targeted to both the cytosol and the secretory pathway in transgenic tobacco, Plant Mol. Biol., 30, 781–793.
Schouten, A., J. Roosien, J.M. de Boer, A. Wilmink, M.N. Rosso, D. Bosch, W.J. Stiekema, F.J. Gommers, J. Bakker, and A. Schots, 1997. Improving scFv antibody expression levels in the plant cytosol, FEBS Lett., 415, 235–241.
Tavladoraki, P., E. Benvenuto, S. Trinca, D. De Martinis, A. Cattaneo, and P. Galeffi, 1993. Transgenic plants expressing a functional single-chain Fv antibody are specifically protected from virus attack, Nature, 366, 469–472.
Vaquero, C., M. Sack, J. Chandler, J. Drossard, F. Schuster, M. Monecke, S. Schillberg, and R. Fischer, 1999. Transient expression of a tumor-specific single-chain fragment and a chimeric antibody in tobacco leaves, Proc. Natl. Acad. Sci. USA, 96, 11128–11133.
van den Heuvel, J.F.J.M., C.M. de Blank, R.W. Goldbach, and D. Peters, 1990. A characterization of epitopes on potato leaf roll virus coat protein, Arch. Virol. 115, 185–197.
Van Engelen, F.A., A. Schouten, J.W. Molthoff, J. Roosien, J. Salinas, W.G. Dirkse, A. Schots, J. Bakker, F.J. Gommers., M.A. Jongsma, D. Bosch, and W.J. Stiekema, 1994. Coordinate expression of antibody subunit genes yields high levels of functional antibodies in roots of transgenic tobacco, Plant Mol. Biol., 26, 1701–1710.
van Regenmortel, M.H.V., 1984. Monoclonal antibodies in plant virology, Microbiol. Sci., 1 (3), 73–78.
van Regenmortel, M.H.V., 1990. Plant viruses, in Immunochemistry of Viruses, II. The Basis for Serodiagnosis and Vaccines, edited by M.H.V. van Regenmortel and A.R. Neurath, Elsevier, Amsterdam, pp. 505–515.
van Regenmortel, M.H.V., 1992. Molecular dissection of protein antigens, in Structure of Antigens, edited by M.V.H. van Regenmortel., CRC Press, Boca Baton, pp. 1–29.
Voss, A., M. Niersbach, R. Hain, H.J. Hirsch, Y.C. Liao, F. Kreuzaler, and R. Fischer, 1995. Reduced virus infectivity in N. tabacum secreting a TMV-specific full-size antibody, Mol. Breed., 1, 39–50.
Yelina, N.E., T.N. Erokhina, N.I. Lukhovitskaya, E.A. Minina, M.V. Schepetinnikov, D.-E. Lesemann, J. Schiemann, A.G. Solovyev, S.Yu. Morozov, 2005. Localization of Poa semilatent virus cysteine-rich protein in peroxisomes is dispensable for the ability to suppress RNA silencing, J. Gen. Virol., 86, 479–489.
Zimmermann, S., S. Schillberg, Y.-C. Liao, and R. Fisher, 1998. Intracellular expression of TMV-specific single-chain Fv fragments to improved virus resistance in Nicotiana tabacum, Mol. Breed., 4, 369–379.
Zinovkin, R.A., T.N. Erokhina, D.-E. Lesemann, W. Jelkmann, and A.A. Agranovsky, 2003. Processing and subcellular localization of the leader papain-like proteinase of Beet yellows closterovirus, J. Gen. Virol., 84, 2265–2270.
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Erokhina, T.N. (2006). THE USE OF MONOCLONAL ANTIBODIES IN PLANT PROTECTION AND FOR STUDYING VIRUS-INDUCED PATHOGENIC PROCESSES. In: Cooper, I., Kühne, T., Polishchuk, V.P. (eds) Virus Diseases and Crop Biosecurity. NATO Security through Science Series. Springer, Dordrecht. https://doi.org/10.1007/978-1-4020-5298-9_8
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DOI: https://doi.org/10.1007/978-1-4020-5298-9_8
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