落葵皺葉嵌紋病毒與感染藤三七之分離株之分子選殖與特性分析

Hong-Jyun Jhu; 朱鴻鈞

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/34821

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	張雅君
dc.contributor.author	Hong-Jyun Jhu	en
dc.contributor.author	朱鴻鈞	zh_TW
dc.date.accessioned	2021-06-13T06:35:08Z	-
dc.date.available	2010-05-20
dc.date.copyright	2006-01-26
dc.date.issued	2005
dc.date.submitted	2006-01-16
dc.identifier.citation	宋端靖。1993。藤三七之藥理學及病理學研究。私立高雄醫學院藥學研究所碩士論文。55 pp。胡文綺。2001。感染海芋之芋頭嵌紋病毒與蒟蒻嵌紋病毒台灣分離株之分子特性。國立台灣大學植物病理學研究所碩士論文。72 pp。陳俊呈。1999。感染臺灣落葵 closterovirus病毒之研究。高雄師範大學生物科學研究所碩士論文。82 pp。陳榮五，王仕賢。1993。嘉雲南地區藤三七及切花栽培利用之研究。台灣省台南區農業改良場研究報告。 Adams, M. J., J. F. Antoniw, and C. M. Fauquet. 2005. Molecular criteria for genus and species discrimination within the family Potyviridae. Arch Virol 150 (3):459-79. Aleman-Verdaguer, M. E., C. Goudou-Urbino, J. Dubern, R. N. Beachy, and C. Fauquet. 1997. Analysis of the sequence diversity of the P1, HC, P3, NIb and CP genomic regions of several yam mosaic potyvirus isolates: implications for the intraspecies molecular diversity of potyviruses. J Gen Virol 78 (6):1253-64. Anandalakshmi, R., G. J. Pruss, X. Ge, R. Marathe, A. C. Mallory, T. H. Smith, and V. B. Vance. 1998. A viral suppressor of gene silencing in plants. Proc Natl Acad Sci U S A 95 (22):13079-84. Anandalakshmi, R., R. Marathe, X. Ge, J. M. Herr, Jr., C. Mau, A. Mallory, G. Pruss, L. Bowman, and V. B. Vance. 2000. A calmodulin-related protein that suppresses posttranscriptional gene silencing in plants. Science 290 (5489):142-4. Anindya, R., and H. S. Savithri. 2004. Potyviral NIa proteinase, a proteinase with novel deoxyribonuclease activity. J Biol Chem 279 (31):32159-69. Anindya, R., J. Joseph1, T.D.S. Gowri1 and H.S. Savithri. 2004. Complete genomic sequence of Pepper vein banding virus (PVBV): a distinct member of the genus Potyvirus. Arch Virol 149 (3): 625–32. Anindya, R., S. Chittori, and H. S. Savithri. 2005. Tyrosine 66 of Pepper vein banding virus genome-linked protein is uridylylated by RNA-dependent RNA polymerase. Virology 336 (2):154-62. Arazi, T., Y. M. Shiboleth, and A. Gal-On. 2001. A nonviral peptide can replace the entire N terminus of zucchini yellow mosaic potyvirus coat protein and permits viral systemic infection. J Virol 75 (14):6329-36. Arbatova, J., K. Lehto, E. Pehu, and T. Pehu. 1998. Localization of the P1 protein of potato Y potyvirus in association with cytoplasmic inclusion bodies and in the cytoplasm of infected cells. J Gen Virol 79 (10):2319-23. Atreya, C. D., P. L. Atreya, D. W. Thornbury, and T. P. Pirone. 1992. Site-directed mutations in the potyvirus HC-Pro gene affect helper component activity, virus accumulation, and symptom expression in infected tobacco plants. Virology 191 (1):106-11. Baratova, L. A., A. V. Efimov, E. N. Dobrov, N. V. Fedorova, R. Hunt, G. A. Badun, A. L. Ksenofontov, L. Torrance, and L. Jarvekulg. 2001. In situ spatial organization of Potato virus A coat protein subunits as assessed by tritium bombardment. J Virol 75 (20):9696-702. Blanc, S., J. J. Lopez-Moya, R. Wang, S. Garcia-Lampasona, D. W. Thornbury, and T. P. Pirone. 1997. A specific interaction between coat protein and helper component correlates with aphid transmission of a potyvirus. Virology 231 (1):141-7. Blanc, S., E. D. Ammar, S. Garcia-Lampasona, V. V. Dolja, C. Llave, J. Baker, and T. P. Pirone. 1998. Mutations in the potyvirus helper component protein: effects on interactions with virions and aphid stylets. J Gen Virol 79 (12):3119-22. Brantley, J. D., and A. G. Hunt. 1993. The N-terminal protein of the polyprotein encoded by the potyvirus tobacco vein mottling virus is an RNA-binding protein. J Gen Virol 74 (6):1157-62. Brigneti, G., O. Voinnet, W. X. Li, L. H. Ji, S. W. Ding, and D. C. Baulcombe. 1998. Viral pathogenicity determinants are suppressors of transgene silencing in Nicotiana benthamiana. EMBO J 17 (22):6739-46. Brunt, A. A., S. Phillips, R. A. C. Jones, and R. H. Kenten. 1982. Viruses detected in Ullucus tuberosus (Basellaceae) from Peru and Bolivia: Ann Appl Biol 101 (1):65-71. Carrington, J. C., D. D. Freed, and A. J. Leinicke. 1991. Bipartite signal sequence mediates nuclear translocation of the plant potyviral NIa protein. Plant Cell 3 (9):953-62. Carrington, J. C., P. E. Jensen, and M. C. Schaad. 1998. Genetic evidence for an essential role for potyvirus CI protein in cell-to-cell movement. Plant J 14 (4):393-400. Carrington, J. C., S. M. Cary, T. D. Parks, and W. G. Dougherty. 1989. A second proteinase encoded by a plant potyvirus genome. EMBO J 8 (2):365-70. Choi, I. R., K. M. Horken, D. C. Stenger, and R. French. 2005. An internal RNA element in the P3 cistron of Wheat streak mosaic virus revealed by synonymous mutations that affect both movement and replication. J Gen Virol 86 (9):2605-14. Cronin, S., J. Verchot, R. Haldeman-Cahill, M. C. Schaad, and J. C. Carrington. 1995. Long-distance movement factor: a transport function of the potyvirus helper component proteinase. Plant Cell 7 (5):549-59. Dolja, V. V., R. Haldeman-Cahill, A. E. Montgomery, K. A. Vandenbosch, and J. C. Carrington. 1995. Capsid protein determinants involved in cell-to-cell and long distance movement of tobacco etch potyvirus. Virology 206 (2):1007-16. Eagles, R. M., E. Balmori-Melian, D. L. Beck, R. C. Gardner, and R. L. Forster. 1994. Characterization of NTPase, RNA-binding and RNA-helicase activities of the cytoplasmic inclusion protein of tamarillo mosaic potyvirus. Eur J Biochem 224 (2):677-84. Fan, Z.F., H. Y. Chen, X.M. Liang, and H.F. Li. 2003. Complete sequence of the genomic RNA of the prevalent strain of a potyvirus infecting maize in China. Arch Virol 148 (4): 773–82 Felsenstein, J. 1993. Phylogenetic Inference Package. Department of Genetic, University of Washington, Seattle. Fernandez, A., S. Lain, and J. A. Garcia. 1995. RNA helicase activity of the plum pox potyvirus CI protein expressed in Escherichia coli. Mapping of an RNA binding domain. Nucleic Acids Res 23 (8):1327-32. Fernandez, A., H. S. Guo, P. Saenz, L. Simon-Buela, M. Gomez de Cedron, and J. A. Garcia. 1997. The motif V of plum pox potyvirus CI RNA helicase is involved in NTP hydrolysis and is essential for virus RNA replication. Nucleic Acids Res 25 (22):4474-80. Gallie, D. R. 2002. The 5'-leader of tobacco mosaic virus promotes translation through enhanced recruitment of eIF4F. Nucleic Acids Res 30 (15):3401-11. Gorbalenya, A. E., A. P. Donchenko, V. M. Blinov, and E. V. Koonin. 1989. Cysteine proteases of positive strand RNA viruses and chymotrypsin-like serine proteases. A distinct protein superfamily with a common structural fold. FEBS Lett 243 (2):103-14. Guo, D., C. Spetz, M. Saarma, and J. P. Valkonen. 2003. Two potato proteins, including a novel RING finger protein (HIP1), interact with the potyviral multifunctional protein HCpro. Mol Plant Microbe Interact 16 (5):405-10. Hajimorad, M. R., X. S. Ding, S. Flasinski, S. Mahajan, E. Graff, R. Haldman-Cahill, J. C. Carrington, and B. G. Cassidy. 1996. Nla and Nlb of peanut stripe potyvirus are present in the nucleus of infected cells, but do not form inclusions. Virology 224 (2):368-79. Hong, Y., and A. G. Hunt. 1996. RNA polymerase activity catalyzed by a potyvirus-encoded RNA-dependent RNA polymerase. Virology 226 (1):146-51. Howell and Mink. 1976. purification. Phytopathology 66: 949, Huang, C. H., and Chang, Y. C. 2001. Molecular characterization of a new potyvirus infecting Basella rubra L. and the expression of its coat protein in Escherichia coli. Plant Pathol 50 (2) Bull 10: 216-17. Huang, C. H., and Chang, Y. C. 2005. Identification and molecular characterization of Zantedeschia mild mosaic virus, a new calla lily-infecting potyvirus. Arch Virol 150 (6):1221-30 Hu, W. C., and Chang, Y. C. 2004. A new mosaic disease of Amazon lily in Taiwan. Plant Pathology 53 (2): 240. Hwang, D. C., D. H. Kim, J. S. Lee, B. H. Kang, J. Han, W. Kim, B. D. Song, and K. Y. Choi. 2000. Characterization of active-site residues of the NIa protease from tobacco vein mottling virus. Mol Cells 10 (5):505-11. Jagadish, M. N., C. W. Ward, K. H. Gough, P. A. Tulloch, L. A. Whittaker, and D. D. Shukla. 1991. Expression of potyvirus coat protein in Escherichia coli and yeast and its assembly into virus-like particles. J Gen Virol 72 (7):1543-50. Jenner, C. E., K. Tomimura, K. Ohshima, S. L. Hughes, and J. A. Walsh. 2002. Mutations in Turnip mosaic virus P3 and cylindrical inclusion proteins are separately required to overcome two Brassica napus resistance genes. Virology 300 (1):50-9. Jenner, C. E., X. Wang, K. Tomimura, K. Ohshima, F. Ponz, and J. A. Walsh. 2003. The dual role of the potyvirus P3 protein of Turnip mosaic virus as a symptom and avirulence determinant in brassicas. Mol Plant Microbe Interact 16 (9):777-84. Kamer, G., and P. Argos. 1984. Primary structural comparison of RNA-dependent polymerases from plant, animal and bacterial viruses. Nucleic Acids Res 12 (18):7269-82. Kasschau, K. D., and J. C. Carrington. 1998. A counterdefensive strategy of plant viruses: suppression of posttranscriptional gene silencing. Cell 95 (4):461-70. Kekarainen, T., H. Savilahti, and J. P. Valkonen. 2002. Functional genomics on potato virus A: virus genome-wide map of sites essential for virus propagation. Genome Res 12 (4):584-94. Kim, D. H., D. C. Hwang, B. H. Kang, J. Lew, and K. Y. Choi. 1996. Characterization of Nla protease from turnip mosaic potyvirus exhibiting a low-temperature optimum catalytic activity. Virology 221 (1):245-9. Kimalov, B., A. Gal-On, R. Stav, E. Belausov, and T. Arazi. 2004. Maintenance of coat protein N-terminal net charge and not primary sequence is essential for zucchini yellow mosaic virus systemic infectivity. J Gen Virol 85 (11):3421-30. Klein, P. G., R. R. Klein, E. Rodriguez-Cerezo, A. G. Hunt, and J. G. Shaw. 1994. Mutational analysis of the tobacco vein mottling virus genome. Virology 204 (2):759-69. Koonin, E. V., G. H. Choi, D. L. Nuss, R. Shapira, and J. C. Carrington. 1991. Evidence for common ancestry of a chestnut blight hypovirulence-associated double-stranded RNA and a group of positive-strand RNA plant viruses. Proc Natl Acad Sci U S A 88 (23):10647-51. Lain, S., J. L. Riechmann, and J. A. Garcia. 1990. RNA helicase: a novel activity associated with a protein encoded by a positive strand RNA virus. Nucleic Acids Res 18 (23):7003-6. Lain, S., M. T. Martin, J. L. Riechmann, and J. A. Garcia. 1991. Novel catalytic activity associated with positive-strand RNA virus infection: nucleic acid-stimulated ATPase activity of the plum pox potyvirus helicaselike protein. J Virol 65 (1):1-6. Leonard, S., D. Plante, S. Wittmann, N. Daigneault, M. G. Fortin, and J. F. Laliberte. 2000. Complex formation between potyvirus VPg and translation eukaryotic initiation factor 4E correlates with virus infectivity. J Virol 74 (17):7730-7. Li, X. H., and J. C. Carrington. 1995. Complementation of tobacco etch potyvirus mutants by active RNA polymerase expressed in transgenic cells. Proc Natl Acad Sci U S A 92 (2):457-61. Lopez, L., A. Urzainqui, E. Dominguez, and J. A. Garcia. 2001. Identification of an N-terminal domain of the plum pox potyvirus CI RNA helicase involved in self-interaction in a yeast two-hybrid system. J Gen Virol 82 (3):677-86. Maia, I. G., A. Haenni, and F. Bernardi. 1996. Potyviral HC-Pro: a multifunctional protein. J Gen Virol 77 (7):1335-41. Merits, A., D. Guo, L. Jarvekulg, and M. Saarma. 1999. Biochemical and genetic evidence for interactions between potato A potyvirus-encoded proteins P1 and P3 and proteins of the putative replication complex. Virology 263 (1):15-22. Moreno, M., B. F. Brandwagt, J. G. Shaw, and E. Rodriguez-Cerezo. 1999. Infectious virus in transgenic plants inoculated with a nonviable, P1-proteinase defective mutant of a potyvirus. Virology 257 (2):322-9. Murphy, J. F., P. G. Klein, A. G. Hunt, and J. G. Shaw. 1996. Replacement of the tyrosine residue that links a potyviral VPg to the viral RNA is lethal. Virology 220 (2):535-8. Murphy, J. F., W. Rychlik, R. E. Rhoads, A. G. Hunt, and J. G. Shaw. 1991. A tyrosine residue in the small nuclear inclusion protein of tobacco vein mottling virus links the VPg to the viral RNA. J Virol 65 (1):511-3. Nicolas, O., S. W. Dunnington, L. F. Gotow, T. P. Pirone, and G. M. Hellmann. 1997. Variations in the VPg protein allow a potyvirus to overcome va gene resistance in tobacco. Virology 237 (2):452-9. Oh, C. S., and J. C. Carrington. 1989. Identification of essential residues in potyvirus proteinase HC-Pro by site-directed mutagenesis. Virology 173 (2):692-9. Page, R. D. 1996. TreeView: an application to display phylogenetic trees on personal computers. Comput Appl Biosci 12 (4):357-8. Peng, Y. H., D. Kadoury, A. Gal-On, H. Huet, Y. Wang, and B. Raccah. 1998. Mutations in the HC-Pro gene of zucchini yellow mosaic potyvirus: effects on aphid transmission and binding to purified virions. J Gen Virol 79 (4):897-904. Plisson, C., M. Drucker, S. Blanc, S. German-Retana, O. Le Gall, D. Thomas, and P. Bron. 2003. Structural characterization of HC-Pro, a plant virus multifunctional protein. J Biol Chem 278 (26):23753-61. Pruss, G., X. Ge, X. M. Shi, J. C. Carrington, and V. Bowman Vance. 1997. Plant viral synergism: the potyviral genome encodes a broad-range pathogenicity enhancer that transactivates replication of heterologous viruses. Plant Cell 9 (6):859-68. Puurand, U., K. Makinen, L. Paulin, and M. Saarma. 1994. The nucleotide sequence of potato virus A genomic RNA and its sequence similarities with other potyviruses. J Gen Virol 75 (2):457-61. Puustinen, P., and K. Makinen. 2004. Uridylylation of the potyvirus VPg by viral replicase NIb correlates with the nucleotide binding capacity of VPg. J Biol Chem 279 (37):38103-10. Rajamaki, M. L., and J. P. Valkonen. 1999. The 6K2 protein and the VPg of potato virus A are determinants of systemic infection in Nicandra physaloides. Mol Plant Microbe Interact 12 (12):1074-81. Rajamaki, M. L. Valkonen, J. P. 2002. Viral genome-linked protein (VPg) controls accumulation and phloem-loading of a potyvirus in inoculated potato leaves. Mol Plant Microbe Interact 15 (2):138-49. Restrepo-Hartwig, M. A., and J. C. Carrington. 1992. Regulation of nuclear transport of a plant potyvirus protein by autoproteolysis. J Virol 66 (9):5662-6. Restrepo-Hartwig, M. A.Carrington, J. C. 1994. The tobacco etch potyvirus 6-kilodalton protein is membrane associated and involved in viral replication. J Virol 68 (4):2388-97. Revers, F., O. Le Gall, T. Candresse, and A. J. Maule. 1999. New advances in understanding the molecular biology of plant potyvirus interactions. Mol Plant Microbe Interact 12 (5):367-76. Riechmann, J. L., S. Lain, and J. A. Garcia. 1992. Highlights and prospects of potyvirus molecular biology. J Gen Virol 73 (1):1-16. Riechmann, J. L., M. T. Cervera, and J. A. Garcia. 1995. Processing of the plum pox virus polyprotein at the P3-6K1 junction is not required for virus viability. J Gen Virol 76 (4):951-6. Robaglia, C., M. Durand-Tardif, M. Tronchet, G. Boudazin, S. Astier-Manifacier, and F. Casse-Delbart. 1989. Nucleotide sequence of potato virus Y (N Strain) genomic RNA. J Gen Virol 70 (4):935-47. Roberts, I. M., D. Wang, K. Findlay, and A. J. Maule. 1998. Ultrastructural and temporal observations of the potyvirus cylindrical inclusions (Cls) show that the Cl protein acts transiently in aiding virus movement. Virology 245 (1):173-81. Rodriguez-Cerezo, E., K. Findlay, J. G. Shaw, G. P. Lomonossoff, S. G. Qiu, P. Linstead, M. Shanks, and C. Risco. 1997. The coat and cylindrical inclusion proteins of a potyvirus are associated with connections between plant cells. Virology 236 (2):296-306. Rojas, M. R., F. M. Zerbini, R. F. Allison, R. L. Gilbertson, and W. J. Lucas. 1997. Capsid protein and helper component-proteinase function as potyvirus cell-to-cell movement proteins. Virology 237 (2):283-95. Roudet-Tavert, G., S. German-Retana, T. Delaunay, B. Delecolle, T. Candresse, and O. Le Gall. 2002. Interaction between potyvirus helper component-proteinase and capsid protein in infected plants. J Gen Virol 83 (7):1765-70. Rybicki, E. P., and D. D. Shukla. 1992. Coat protein phylogeny and systematics of potyviruses. Arch Virol Suppl 5:139-70. Saenz, P., M. T. Cervera, S. Dallot, L. Quiot, J. B. Quiot, J. L. Riechmann, and J. A. Garcia. 2000. Identification of a pathogenicity determinant of Plum pox virus in the sequence encoding the C-terminal region of protein P3+6K(1). J Gen Virol 81 (3):557-66. Sakai, J., M. Mori, T. Morishita, M. Tanaka, K. Hanada, T. Usugi, and M. Nishiguchi. 1997. Complete nucleotide sequence and genome organization of sweet potato feathery mottle virus (S strain) genomic RNA: the large coding region of the P1 gene. Arch Virol 142 (8):1553-62. Sambrook, J., and Russell, D.W. 2001. Molecular Cloning, a Laboratory Manual, 3rd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, New York, USA. Schaad, M. C., R. Haldeman-Cahill, S. Cronin, and J. C. Carrington. 1996. Analysis of the VPg-proteinase (NIa) encoded by tobacco etch potyvirus: effects of mutations on subcellular transport, proteolytic processing, and genome amplification. J Virol 70 (10):7039-48. Shukla, D. D., and C. W. Ward. 1989. Identification and classification of potyviruses on the basis of coat protein sequence data and serology. Brief review. Arch Virol 106 (3-4):171-200. Shukla, D. D., and C. W. Ward. 1991. Structure and function of the potyvirus genome with special reference to the coat protein coding region. Can J Plant Pathol 13: 178–91. Starr, F., Starr, K., and Loope, L. 2003. Anredera cordifolia Plants of Hawaii reports. http://www.hear.org/starr/hiplants/reports/html/anredera_cordifolia.htm. Suehiro, N., T. Natsuaki, T. Watanabe, and S. Okuda. 2004. An important determinant of the ability of Turnip mosaic virus to infect Brassica spp. and/or Raphanus sativus is in its P3 protein. J Gen Virol 85 (7):2087-98. Thornbury, D. W., G. M. Hellmann, R. E. Rhoads, and T. P. Pirone. 1985. Purification and characterization of potyvirus helper component. Virology 144:260-267. Thompson, J. D., T. J. Gibson, F. Plewniak, F. Jeanmougin, and D. G. Higgins. 1997. The CLUSTAL_X windows interface: flexible strategies for multiple sequence alignment aided by quality analysis tools. Nucleic Acids Res 25 (24):4876-82. Turpen, T. 1989. Molecular cloning of a potato virus Y genome: nucleotide sequence homology in non-coding regions of potyviruses. J Gen Virol 70 (8):1951-60. Urcuqui-Inchima, S., A. L. Haenni, and F. Bernardi. 2001. Potyvirus proteins: a wealth of functions. Virus Res 74 (1-2):157-75. van Regenmortel, M. H. V., Fauquet, C. M., Bishop, D. H. L., Carstens, E. E., Estes, M. K., Lemon, S. M., Maniloff, J., Mayo, M. A., McGeoch, D. J., PRINGLE, C. R., and Wickner, R. B. 2000. Virus Taxonomy. Seventh Report of the International Committee on Taxonomy of Viruses. 703-724. Academic Press, London San Diego. Verchot, J., and J. C. Carrington. 1995. Evidence that the potyvirus P1 proteinase functions in trans as an accessory factor for genome amplification. J Virol 69 (6):3668-74. Verchot, J., E. V. Koonin, and J. C. Carrington. 1991. The 35-kDa protein from the N-terminus of the potyviral polyprotein functions as a third virus-encoded proteinase. Virology 185 (2):527-35. Verchot, J., K. L. Herndon, and J. C. Carrington. 1992. Mutational analysis of the tobacco etch potyviral 35-kDa proteinase: identification of essential residues and requirements for autoproteolysis. Virology 190 (1):298-306. Voloudakis, A. E., C. A. Malpica, M. E. Aleman-Verdaguer, D. M. Stark, C. M. Fauquet, and R. N. Beachy. 2004. Structural characterization of Tobacco etch virus coat protein mutants. Arch Virol 149 (4):699-712. Wang, X., Z. Ullah, and R. Grumet. 2000. Interaction between zucchini yellow mosaic potyvirus RNA-dependent RNA polymerase and host poly-(A) binding protein. Virology 275 (2):433-43. Wittmann, S., H. Chatel, M. G. Fortin, and J. F. Laliberte. 1997. Interaction of the viral protein genome linked of turnip mosaic potyvirus with the translational eukaryotic initiation factor (iso) 4E of Arabidopsis thaliana using the yeast two-hybrid system. Virology 234 (1):84-92. Yambao, M. L., C. Masuta, K. Nakahara, and I. Uyeda. 2003. The central and C-terminal domains of VPg of Clover yellow vein virus are important for VPg-HCPro and VPg-VPg interactions. J Gen Virol 84 (10):2861-9.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/34821	-
dc.description.abstract	自台北縣新店市發現藤三七(Anredera cordifolia)葉片上有疑似病毒引起的輪點狀病徵，將罹病材料以汁液機械接種於指示植物白藜及紅藜上，分別造成系統性的感染及局限性斑點的病徵。於紅藜植株進行三次單斑分離，得到一病毒分離株N。在寄主範圍測試方面，將分離株N機械接種於八科二十二種的植物，其中除了紅藜白藜外，僅在菸草(Nicotiana benthamiana) 以及番杏(Tetragonia expansa) 葉片上分別造成嵌紋和褪綠單斑的病徵，回接健康藤三七，則能在新葉上產生褪綠病徵，以穿透式電子顯微鏡觀察病毒分離株，可見長約650 nm的長絲狀病毒顆粒，經由酵素連結免疫吸附反應檢測 (ELISA)，發現與anti-potyvirus group之單元抗體呈正反應。利用針對potyvirus所設計的廣效性引子對進行RT-PCR的分析，發現能增幅出1.8 kb大小的片段。將此片段選殖後進行解序，經由BLASTn程式，與資料庫中的病毒序列進行比對，確定其為potyvirus的部份序列，包含部份NIb基因、鞘蛋白基因及3’非轉譯區的序列，且與先前本實驗室所發現的落葵皺葉嵌紋病毒(Basella rugose mosaic virus, BaRMV)之核苷酸序列相同度達98%。因此判定此病毒株為落葵皺葉嵌紋病毒在藤三七上所發現的分離株，名為BaRMV-N。利用本實驗室針對potyvirus所設計的廣效性引子及此病毒的專一性引子，配合RT-PCR或RACE進行病毒其餘基因體部分的選殖。經過解序以及序列分析，已獲得BaRMV-N完整的病毒序列。因為感染落葵和藤三七之BaRMV基因體序列的相同度極高，選用適合的引子對從罹病落葵中選殖出BaRMV-J的序列片段並定序之。從序列分析結果可知BaRMV-N與BaRMV-J具有相同的長度，皆為9804個核苷酸，除5’和3’非轉譯區外，全長序列可轉譯出包含P1、HC-Pro、P3、6K1、CI、6K2、NIa、NIb及CP九個蛋白共3079個胺基酸的大蛋白 (polyprotein)，經過和其他已發表的38種potyvirus的序列進行排並比較，可以推測出這九種蛋白裂解的位置，在BaRMV-N與BaRMV-J之間，這些蛋白的胺基酸相同度分別為95%、98%、97%、96%、97%、96%、98%、99%、98%。 BaRMV各個病毒蛋白的胺基酸序列、大蛋白胺基酸序列和全長核苷酸序列，也分別與這38種potyvirus進行排並比較以及類緣關係分析。在鞘蛋白部分，結果顯示其胺基酸序列相同度在各種病毒間最高為68%，而最低為44%；在病毒基因體全長部分，其核苷酸相同度最高則為62%。依現行國際病毒分類委員會(ICTV)分類標準，BaRMV為一新種的potyvirus而與之類源關係最為相近的是甜菜嵌紋病毒(Beet mosaic virus)。經由ELISA檢測，約有八成的受測檢體出現正反應，證實BaRMV 普遍存在於台灣的藤三七上。	zh_TW
dc.description.abstract	Anredera cordifolia planted in Sindian city exhibited virus-like ringspot symptom on leaves. Leaf saps were mechanically inoculated on indicator plant Chenopodium amaranticolor and C. quinoa. Systemic symptom developed on C. quinoa but only local lesions appeared on inocualted C. amaranticolor. Through three times of successive single lesion isolation on C. amaranticolor, a virus isolate N was obtained. In host range test, in addition to C. amaranticolor and C. quinoa, the virus isolate can only infect Nicotiana benthamiana and Tetragonia expansa and develope mosaic and chlorotic local lesion on leaves, respectively, in 20 species of 8 families plants. When performing backinoculations, newly formed leaves of A. cordifolia exhibit chlorotic foliar symptom. With electron microscopy inspection, the virus particles were found to be filamentous and about 650 nm in length. Indirect ELISA indicated the viruses in the symptomatic leaves reacted with anti-potyvirus monoclonal antibody. Subsequently, the degenerate primers designed for detecting potyviruses were used for further confirmation. The amplified fragments, about 1.8 kb in size, were cloned and sequenced. The sequencing data were analysed with BLAST program with other viruses in the database. The result clearly indicated that the amplified fragments were derived from a potyvirus and contained partial NIb gene, coat protein gene and 3'UTR. Furthermore, these virus clones share 98% nucleotide identity with Basella rugose mosaic virus (BaRMV) previously identified by our laboratory. Therefore, the virus isolate was named as BaRMV-N. By means of RT-PCR or RACE method utilizing potyvirus degenerate primers and BaRMV-N specific primers designed from sequencing data, the remaining genomic fragments of BaRMV-N were cloned and sequenced. Because of the high identity between the two virus isolates, the full length of BaRMV-J genome sequence was cloned and sequenced by appropriate BaRMV-N primers. Both BaRMV-N and BaRMV-J are composed of 9804 nucleotides, excluding the 3’ terminal poly(A) tail, and contain an open reading frame of 9237 nt, encoding a polyprotein of 3079 amino acids. Nine putative proteinase cleavage sites were predicted by analogy with genome arrangements of other potyviruses. The nine mature viral proteins and the amino acid identity between BaRMV-N and BaRMV-J are P1 (95%), HC-Pro (98%), P3 (97%), 6K1 (96%), CI (97%), 6K2 (96%), NIa (98%), NIb (99%) and coat protein (98%). The amino acid identity of viral proteins, polyprotein and the identity of complete nucleotide sequence when comparing with 38 different species of potyvirus were calculated. Additionally these data were used for constructing phylogenetic trees. The highest amino acid identities of CP and highest nucleotide sequence identity of whole genome of BaRMV-N and other potyviruses were 68% and 54%, respectively. Therefore, in terms of species demarcating criteria in the genus Potyvirus, BaRMV is considered as a new potyvirus and the most closely related virus is Beet mosaic virus (BtMV). In detection by ELISA, there were about 80% sample positively reacting with BaRMV antiserum so we presumed that BaRMV exist in Taiwan commonly.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T06:35:08Z (GMT). No. of bitstreams: 1 ntu-94-R92633020-1.pdf: 3261345 bytes, checksum: db72bf071cfba1bfeac81f0102768f05 (MD5) Previous issue date: 2005	en
dc.description.tableofcontents	中文摘要 …………………………………………………….1 英文摘要 …………………………………………………….3 Introduction ……………………………………………….5 Materials and Methods…………………………………….13 Results……………………………………………………….20 Discussion ………………………………………………….29 References ………………………………………………….33 Tables …………………………………………………….44 Figures …………………………………………………….52 Appendix …………………………………………………….84
dc.language.iso	en
dc.title	落葵皺葉嵌紋病毒與感染藤三七之分離株之分子選殖與特性分析	zh_TW
dc.title	Molecular cloning and characterization of Basella rugose mosaic virus and the isolate infecting Anredera cordifolia	en
dc.type	Thesis
dc.date.schoolyear	94-1
dc.description.degree	碩士
dc.contributor.oralexamcommittee	胡仲琦,詹富智
dc.subject.keyword	藤三七,落葵皺葉嵌紋病毒,	zh_TW
dc.subject.keyword	Anredera cordifolia,Basella rugose mosaic virus,potyvirus,	en
dc.relation.page	85
dc.rights.note	有償授權
dc.date.accepted	2006-01-17
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	植物病理與微生物學研究所	zh_TW
顯示於系所單位：	植物病理與微生物學系

文件中的檔案：

檔案	大小	格式
ntu-94-1.pdf 目前未授權公開取用	3.18 MB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。