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  1. NTU Theses and Dissertations Repository
  2. 醫學院
  3. 微生物學科所
Please use this identifier to cite or link to this item: http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/24457
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???org.dspace.app.webui.jsptag.ItemTag.dcfield???ValueLanguage
dc.contributor.advisor陳建源
dc.contributor.authorYang-Wei Liuen
dc.contributor.author劉楊威zh_TW
dc.date.accessioned2021-06-08T05:26:44Z-
dc.date.copyright2005-07-28
dc.date.issued2005
dc.date.submitted2005-07-19
dc.identifier.citation1. 生物技術研究中心,2001。生物技術方法卷一:生物技術核心實驗。國立台灣大學生物技術研究中心。
2. 李玉蘭,1999。箱網養殖海鱺化學組成特性及其季節與貯藏變化。國立海洋大學食品科學所碩士論文。
3. 吳文騰,2003。生物產業技術概論。
4. 吳仁佑,2003。海鱺淋巴囊腫瘤病毒之檢測及與其他虹彩病毒之親緣關係。國立台北師範學院數理教育研究所碩士論文。
5. 吳明峰,2001。石斑虹彩病毒之分子特性及其疫苗之開發。國立台灣大學獸醫學研究所碩士論文。
6. 周書瑜,2004。利用同源甘油醛-3-磷酸脫氫酶啟動子進行金針菇轉形系統之研究。國立台灣大學微生物與生化學研究所碩士論文。
7. 周淑芬,2000。多功能免疫反應型腫瘤標記生物感測器之開發研究。國立台灣大學農業化學所博士論文。
8. 郭倫甄,2003。人類鐵蛋白單株抗體之產製及其臨床檢測應用。國立台灣大學農業化學所碩士論文。
9. 許惠綺,2004。抗乳酸脫氫酶單株抗體之產製及其應用於石英晶體免疫感測器之開發。國立台灣大學微生物與生化學研究所碩士論文。
10. 莊榮輝,2000。酵素化學實驗。國立台灣大學農業化學系編印。
11. 張賜玲、謝介士、周瑞良、蘇茂森,1999。海鱺繁養殖技術簡介。養魚世界270(9):14-26。
12. 黃志中,2002。麩胺酸草醯乙酸轉胺酶單元抗體產製及其分析系統開發研究。國立台灣大學農業化學所碩士論文。
13. 賴昭伶,1997。氯黴素單源抗體之產製及其應用於壓電免疫感測器之開發研究。國立台灣大學農業化學所碩士論文。
14. 劉雨田等編著,1991。新編微生物學。永大書局。
15. 謝淨如,2002。魚類神經壞死症病毒單源抗體之建立、定性及應用。國立台灣大學動物學研究所碩士論文。
16. Alligood, K. J., M. Milla, et al. 2000. Monoclonal antibodies generated against recombinant ATM support kinase activity. Hybridoma 19(4): 317-21.
17. Bekaert, E. D., M. Ayrault-Jarrier, et al. 1988. Competitive enzyme inhibition immunoassay of apolipoprotein A-I: use of monoclonal antibodies. Clin Chem 34(6): 1030-5.
18. Bullard, S. A., G. W. Benz, et al. 2000. Dionchus postoncomiracidia (Monogenea: Dionchidae) from the skin of blacktip sharks, Carcharhinus limbatus (Carcharhinidae). J Parasitol 86(2): 245-50.
19. Bynum, J., J. L. Andrews, et al. 1999. Development of class-switched, affinity-matured monoclonal antibodies following a 7-day immunization schedule. Hybridoma 18(5): 407-11.
20. Cameron, I. R. 1990. Identification and characterization of the gene encoding the major structural protein of insect iridescent virus type 22. Virology 178(1): 35-42.
21. Cathleen Bester. 2005. Education profiles of cobia. http://www.flmnh.ufl.edu/fish/Gallery/Descript/Cobia/Cobia.html
22. Chou, S. F. and C. Y. Chen. 2001. Monoclonal and polyclonal antibodies against human ferritin, a nonspecific tumor marker. Hybridoma 20(1): 59-62.
23. D'Costa, S. M., H. Yao, et al. 2001. Transcription and temporal cascade in Chilo iridescent virus infected cells. Arch Virol 146(11): 2165-78.
24. Do, J. W., S. J. Cha, et al. 2005. Sequence variation in the gene encoding the major capsid protein of Korean fish iridoviruses. Arch Virol 150(2): 351-9.
25. Do, J. W., C. H. Moon, et al. 2004. Complete genomic DNA sequence of rock bream iridovirus. Virology 325(2): 351-63.
26. Fischer, M., P. Schnitzler, et al. 1988. Identification and characterization of the repetitive DNA element in the genome of insect iridescent virus type 6. Virology 167(2): 485-96.
27. Goldsby, R. A., Kindt, T. J., Osborne, B. A., Kuby, J. 2001. Immunology. 4th ed. W. H. Freeman and company. New York.
28. Grizzle, J. M., I. Altinok, et al. 2002. First isolation of largemouth bass virus. Dis Aquat Organ 50(3): 233-5.
29. Grizzle, J. M., I. Altinok, et al. 2003. PCR method for detection of largemouth bass virus. Dis Aquat Organ 54(1): 29-33.
30. He, J. G., L. L, et al. 2002. Sequence analysis of the complete genome of an iridovirus isolated from the tiger frog. Virology 292(2): 185-97.
31. Heddy Zola. 2000. Monoclonal antibodies: preparation and use of monoclonal antibodies and engineered antibody derivatives. Springer –Verlag., New York.
32. Hu, G. B., R. S. Cong, et al. 2004. Induction of apoptosis in a flounder gill cell line by lymphocystis disease virus infection. J Fish Dis 27(11): 657-62.
33. Huang, C., X. Zhang, et al. 2004. In situ hybridization of a marine fish virus, Singapore grouper iridovirus with a nucleic acid probe of major capsid protein. J Virol Methods 117(2): 123-8.
34. Hurrell, J. G. R. 1985. Monoclonal hybridoma antibodies: techniques and applications. CRC press, Inc., New York.
35. Jakob, N. J., R. G. Kleespies, et al. 2002. Comparative analysis of the genome and host range characteristics of two insect iridoviruses: Chilo iridescent virus and a cricket iridovirus isolate. J Gen Virol 83(Pt 2): 463-70.
36. Jakob, N. J., K. Muller, et al. 2001. Analysis of the first complete DNA sequence of an invertebrate iridovirus: coding strategy of the genome of Chilo iridescent virus. Virology 286(1): 182-96.
37. Jancovich, J. K., J. Mao, et al. 2003. Genomic sequence of a ranavirus (family Iridoviridae) associated with salamander mortalities in North America. Virology 316(1): 90-103.
38. Katie M. Kurkjian et al. Lymphocystis in Marine and Freshwater Fishes. http://www.vet.uga.edu/vpp/CLERK/Kurkjian/.
39. Kilpatrick, K. E., T. Cutler, et al. 1998. Gene gun delivered DNA-based immunizations mediate rapid production of murine monoclonal antibodies to the Flt-3 receptor. Hybridoma 17(6): 569-76.
40. Kilpatrick, K. E., S. A. Wring, et al. 1997. Rapid development of affinity matured monoclonal antibodies using RIMMS. Hybridoma 16(4): 381-9.
41. Kinard, G. R., O. W. Barnett, et al. 1995. Characterization of an iridescent virus isolated from the velvetbean caterpillar, Anticarsia gemmatalis. J Invertebr Pathol 66(3): 258-63.
42. Kinch, M. S., K. E. Kilpatrick, et al. 1998. Identification of tyrosine phosphorylated adhesion proteins in human cancer cells. Hybridoma 17(3): 227-35.
43. Kohler, G. and C. Milstein. 1975. Continuous cultures of fused cells secreting antibody of predefined specificity. Nature 256(5517): 495-7.
44. Lindley, K. M., J. L. Su, et al. 2000. Production of monoclonal antibodies using recombinant baculovirus displaying gp64-fusion proteins. J Immunol Methods 234(1-2): 123-35.
45. Littlefield, J. W. 1964. The Selection of Hybrid Mouse Fibroblasts. Cold Spring Harb Symp Quant Biol 29: 161-6.
46. Liu, P. C., J. Y. Lin, et al. 2004. Isolation and characterization of pathogenic Vibrio alginolyticus from diseased cobia Rachycentron canadum. J Basic Microbiol 44(1): 23-8.
47. Liu, P. C., J. Y. Lin, et al. 2003. Virulence of Photobacterium damselae subsp. piscicida in cultured cobia Rachycentron canadum. J Basic Microbiol 43(6): 499-507.
48. Mao, J., D. E. Green, et al. 1999. Molecular characterization of iridoviruses isolated from sympatric amphibians and fish. Virus Res 63(1-2): 45-52.
49. Mao, J., R. P. Hedrick, et al. 1997. Molecular characterization, sequence analysis, and taxonomic position of newly isolated fish iridoviruses. Virology 229(1): 212-20.
50. Mao, J., T. N. Tham, et al. 1996. Cloning, sequence analysis, and expression of the major capsid protein of the iridovirus frog virus 3. Virology 216(2): 431-6.
51. Marsh, I. B., R. J. Whittington, et al. 2002. Rapid differentiation of Australian, European and American ranaviruses based on variation in major capsid protein gene sequence. Mol Cell Probes 16(2): 137-51.
52. Muller, K., C. A. Tidona, et al. 1999. Identification of a gene cluster within the genome of Chilo iridescent virus encoding enzymes involved in viral DNA replication and processing. Virus Genes 18(3): 243-64.
53. Murti, K. G., M. Chen, et al. 1985. Interaction of frog virus 3 with the cytomatrix. III. Role of microfilaments in virus release. Virology 142(2): 317-25.
54. Nalcacioglu, R., H. Marks, et al. 2003. Promoter analysis of the Chilo iridescent virus DNA polymerase and major capsid protein genes. Virology 317(2): 321-9.
55. Oshima, S., J. Hata, et al. 1998. Rapid diagnosis of red sea bream iridovirus infection using the polymerase chain reaction. Dis Aquat Organ 32(2): 87-90.
56. Qin, Q. W., T. J. Lam, et al. 2001. Electron microscopic observations of a marine fish iridovirus isolated from brown-spotted grouper, Epinephelus tauvina. J Virol Methods 98(1): 17-24.
57. Rajan, P. R., J. H. Lin, et al. 2003. Simple and rapid detection of Photobacterium damselae ssp. piscicida by a PCR technique and plating method. J Appl Microbiol 95(6): 1375-80.
58. Caylor, R. E., Biesiot, P. M., Franks, J. S. 1994. Culture of cobia (Rachycentron canadum): cryopreservation of sperm and induced spawning. Aquaculture 125: 81-92.
59. Russo, C., L. Callegaro, et al. 1983. Re.: Purification of IgG monoclonal antibody by caprylic acid precipitation. J Immunol Methods 65(1-2): 269-71.
60. Sambrook, J., Russell, D. W. 2001. Molecular cloning: a laboratory manual. Cold Spring Harb Lab Press., New York.
61. Schnitzler, P. and G. Darai. 1993. Identification of the gene encoding the major capsid protein of fish lymphocystis disease virus. J Gen Virol 74 (Pt 10): 2143-50.
62. Stohwasser, R., K. Raab, et al. 1993. Identification of the gene encoding the major capsid protein of insect iridescent virus type 6 by polymerase chain reaction. J Gen Virol 74 (Pt 5): 873-9.
63. Tajbakhsh, S., P. E. Lee, et al. 1990. Molecular cloning, characterization, and expression of the Tipula iridescent virus capsid gene. J Virol 64(1): 125-36.
64. Tidona, C. A. and G. Darai. 1997. The complete DNA sequence of lymphocystis disease virus. Virology 230(2): 207-16.
65. Tidona, C. A. and G. Darai. 1997. Molecular anatomy of lymphocystis disease virus. Arch Virol Suppl 13: 49-56.
66. Tidona, C. A., P. Schnitzler, et al. 1998. Is the major capsid protein of iridoviruses a suitable target for the study of viral evolution? Virus Genes 16(1): 59-66.
67. Trevor Williams. 1996. The iridovirus. Advances in virus research 46: 345-412.
68. Wang, C. S., H. H. Shih, et al. 2003. Studies on epizootic iridovirus infection among red sea bream, Pagrus major (Temminck & Schlegel), cultured in Taiwan. J Fish Dis 26(3): 127-33.
69. Watanabe, K. H., F. W. Desimone, et al. 2003. Fish tissue quality in the lower Mississippi River and health risks from fish consumption. Sci Total Environ 302(1-3): 109-26.
70. Webby, R. and J. Kalmakoff. 1998. Sequence comparison of the major capsid protein gene from 18 diverse iridoviruses. Arch Virol 143(10): 1949-66.
71. Webby, R. J. and J. Kalmakoff. 1999. Comparison of the major capsid protein genes, terminal redundancies, and DNA-DNA homologies of two New Zealand iridoviruses. Virus Res 59(2): 179-89.
72. Weir D. W. 1978. Immunochemical analysis of immunoglobulins and their subunits. Chapter 6 in Handbook of experimental immunology, 1:241-253.
73. Weissenberg. 1951. Studies on lymphocystis tumor cells of fish. II. Granular structures of the inclusion substance as stages of the developmental cycle of the lymphocystis virus. Cancer Res 11(8): 608-13.
74. Willis, D. B. and A. Granoff. 1980. Frog virus 3 DNA is heavily methylated at CpG sequences. Virology 107(1): 250-7.
75. Wring, S. A., K. E. Kilpatrick, et al. 1999. Shorter development of immunoassay for drugs: application of the novel RIMMS technique enables rapid production of monoclonal antibodies to ranitidine. J Pharm Biomed Anal 19(5): 695-707.
76. Yu, Y. X., M. Bearzotti, et al. 1999. Partial mapping and sequencing of a fish iridovirus genome reveals genes homologous to the frog virus 3 p31, p40 and human eIF2alpha. Virus Res 63(1-2): 53-63.
77. Zhang, Q. Y., F. Xiao, et al. 2004. Complete genome sequence of lymphocystis disease virus isolated from China. J Virol 78(13): 6982-94.
dc.identifier.urihttp://tdr.lib.ntu.edu.tw/jspui/handle/123456789/24457-
dc.description.abstract本論文以罹患淋巴囊腫病的海鱺為材料,自數種組織及器官分離出基因組DNA (genomic DNA)後,設計專一性引子並進行聚合酶連鎖反應(polymerase chain reaction),以偵測並放大主要鞘蛋白的DNA序列mcp,經由定序後可知此段序列長度為1295個鹽基(base pair),利用Bioedit軟體分析其限制切位圖譜(restriction map)以及下游轉譯胺基酸序列組成,推測其下游產物分子量應介於45至50 kD之間。
自含有病毒的器官及組織中分離出病毒顆粒,進行免疫以生產單株抗體,免疫方法包括傳統法以及快速免疫法(RIMMS),將免疫完成的小鼠脾細胞取出,與骨髓癌細胞NS-1利用PEG 1500進行細胞融合,以HAT(Hypoxanthine、Aminopterin、Thymidine)培養液進行選擇性培養,並以酵素免疫分析法(ELISA)篩選出具分泌抗淋巴囊腫病毒主要鞘蛋白之融合瘤(hybridoma)細胞,共獲得3C6抗體與2A10抗體兩株高效價的單株細胞。分型結果顯示3C6的重鏈為IgG1而2A10的重鏈為IgG2a,兩者的輕鏈均為κ。其中3C6單株細胞生長快速且分泌出的抗體效價較高,以之作為生產抗體細胞株。將其產生的單株抗體進行純化。步驟包括先以硫酸銨沉澱後,以DEAE-Sepharose離子交換樹脂與Protein-G管柱進行親和性層析,再以原態膠體電泳、變性膠體電泳(SDS-PAGE)與ELISA進行分析。
最後將mcp基因以pQE31表現載體於大腸桿菌DH5α中進行蛋白質生產,pQE31上帶有His-tag,因此重組蛋白質可利用Ni-NTA親和管柱進行純化,純化後的MCP蛋白質經由SDS-PAGE分析後可知其分子量約48kD,而經由ELISA與西方墨點染色(Western blotting)而知其可與單株抗體3C6結合。
以單株抗體進行海鱺淋巴囊腫病毒主要鞘蛋白的檢測,利用間接ELISA的方式,將純化後的3C6抗體經稀釋104倍後使其與不同濃度的MCP進行結合並呈色,實驗結果顯示檢測範圍介於0.5至5 μg/mL 時有良好的線性關係,可偵測MCP的極限為0.5 μg/mL。
由以上結果可知,針對淋巴囊腫病毒主要鞘蛋白之單株抗體可應用於進行病毒顆粒的檢測,並可能進一步發展如免疫反應型生物感測器等快速檢測平台。此外,利用基因重組大腸桿菌大量生產主要鞘蛋白MCP,亦具有發展成魚用疫苗的潛力。		zh_TW
dc.description.abstractThe material of this study is the Cobia(Rachycentron canadum) which were infected by iridovirus and had lymphocystis syndrome. We isolated the genomic DNA of several organs and tissues and designed specific primers to detect and amplify the major capsid protein gene mcp by polymerase chain reaction (PCR). After sequencing, the total length of mcp is 1295 base pairs. Then, we used the software Bioedit to analyze the restriction map and simulate its translation product, MCP. The number of amino acid composing MCP is 431, which suggested that the molecular weight should be between 45 to 50 kD.
We isolated viral particles from infected organs and tissues by blending method and emulsified viral particles to immune Balb/c female mouse in order to produce monoclonal antibody (mAb). Immunization methods are traditional method and RIMMS. Then the spleen cells of immuned Balb/c mouse were collected and fused with NS-1 myeloma cells by PEG-inducing method. The fused cells were then selected in HAT medium. The hybridomas, which could secrete anti-MCP antibodies, were screened with enzyme-linked immunosorbant assay (ELISA). Then the hybridomas were subcloned by limit dilution. Two hybridomas producing anti-MCP mAb were obtained and designated as 3C6 and 2A10. The isotypes of 3C6 and 2A10 were IgG1 and IgG2a as heavy chain and same κ as light chain. 3C6 hybridoma secreted higher titer of anti-MCP antibodies and had better growth conditions than 2A10 hybridoma, thus we chose 3C6 hybridoma to produce anti-MCP mAb. Then we purified antibodies by following methods: ammonium sulfate participation, ion-exchange (DEAE) chromatography, and Protein-G affinity chromatography. SDS-PAGE and ELISA were used to analyzed purified products.
Finally, we cloned mcp gene into pQE31 expression vectors and expressed MCP by E. coli DH5α. The recombinant MCP protein was purified easily because it carried 6x His-tag on N-terminal. After Ni-NTA affinity chromatography, pure MCP protein was collected, and its molecular weight was about 48 kD. Western blotting showed that recombinant MCP would interact with 3C6 mAb specifically.
With indirect ELISA, purified 3C6 antibodies were diluted to 104 times to interact with different concentrations of MCP protein. The MCP concentration ranged form 0.5 to 5 μg/mL showed a better linear relationship, and the detection limit was 0.5 μg/mL.
In summary, we produced antibodies which interacted with major capsid protein of iridovirus that were isolated from cobia with lymphocystis syndrome. We hope that the mAb produced in this study can apply in virus detection. Otherwise, the recombinant MCP also has a potential to develop as vaccines.		en
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dc.description.tableofcontents表目錄……………........………………………………………………………IV
圖目錄………………........…………………………………………………….V
中文摘要…………………....………………………………………………VIII
Abstract…………………………...............................................................X
第一章、研究背景………………………………………………………………1
1. 海鱺(cobia)簡介…………………………… …………….………………..1
1.1 海鱺的分類及生活習性……………………………..………………..1
1.2 海上箱網養殖………………………………………...……………….3
1.3 海鱺的營養組成………………………………………..……………..4
1.4 海鱺的疾病………………………………………………..…………..5
1.5 淋巴囊腫病……………………………………………………………6
2. 虹彩病毒………………………………………………………….....……10
2.1 虹彩病毒概述…………………………………………………..……10
2.2 虹彩病毒分類……………………………………………………..…11
2.3 虹彩病毒生活史…………………………………………………..…13
2.4 虹彩病毒之主要鞘蛋白…………………………………………..…16
3. 抗體結構及特性………………………………………………………..…19
3.1 抗體與免疫機制………………………………………………..……19
3.2 抗體的一般特性………………………………………………..……20
3.3 多株抗體與單株抗體…………………………………………..……23
3.4 單株抗體的生產…………………………………………………..…24
4. 研究動機……………………………………………………………..……31
第二章、材料與方法……………………………………………………..……32
1. 海鱺病魚之採樣…………………………………………………………32
2. 海鱺淋巴囊腫病毒之分離與主要鞘蛋白基因選殖………..……………32
2.1 感染海鱺淋巴囊腫病毒(CbIV)各組織核酸之萃取…….………….32
2.2 利用PCR放大海鱺各組織中CbIV 之主要鞘蛋白基因….………34
2.3 DNA之分離與純化與TA cloning ………………………….………35
2.4 質體轉形、抗生素篩選與colony PCR……………………..………36
2.5 質體DNA的分離……………………………………………..……..38
2.6 海鱺淋巴囊腫病毒(CbIV)之分離…………………………….…….39
3. mcp基因表現與MCP蛋白質的純化…………………………………...40
3.1 限制酵素切位設計、限制酵素截切與接合反應…………………....40
3.2 重組MCP蛋白質的誘導與表現…………………………………....42
3.3 MCP蛋白質純化…………………………………………………....43
4. 單株抗體(monoclonal antibody)之製備…………………………….….45
4.1 動物免疫………………………………………………………...…...47
4.2 骨髓癌細胞培養……………………………………………………..50
4.3 細胞融合…………………………………………………………..…52
4.4 細胞保存…………………………………………………………..…55
4.5 單株化與ELISA篩選………………………………………………..56
4.6 生產單株抗體…………………………………………………..……61
5. 抗體純化方法………………………………………………………..……63
5.1 硫酸銨飽和度分劃(硫酸銨沉澱)……………………………………63
5.2 離子交換法………………………………………………………......65
5.3 親和層析法 (Protein-G管柱) …………………………….............66
6. 抗體之分析方法…………………………………….…………………....68
6.1 蛋白質定量法………………………………………………………..68
6.2 原態膠體電泳 (Native-PAGE) …………………………………....69
6.3 變性膠體電泳(SDS-PAGE) ………………………………….........71
6.4 膠體染色法………………………………………………………..…73
6.5 免疫轉印法 (Immunoblotting) ……………………………............75
第三章、結果與討論………………………………………………………..…78
1. 海鱺淋巴囊腫病毒之分離與基因選殖……………………..……………78
1.1 感染淋巴囊腫病毒(CbIV)海鱺各組織核酸之萃取........………..…78
1.2 利用PCR放大海鱺各組織中CbIV之主要鞘蛋白基因…………...79
1.3 mcp基因選殖與定序……………………………………………..…80
1.4 海鱺淋巴囊腫病毒之分離………………………………….............84
2. 單株抗體之製備……………………………………………………….....85
2.1 動物免疫…………………………………………………….........…85
2.2 細胞融合…………………………………………………………….92
2.3 單株抗體分型鑑定………………………………..................…….98
2.4 單株抗體之生產……………………………………………………100
2.5 單株抗體之純化……………………………………………………101
3. CbIV主要鞘蛋白基因mcp之表現與MCP之純化…………………...106
3.1 限制酵素切位設計以及產物選殖…………………………………106
3.2 接合反應、PCR與定序………………………………...............…107
3.3 MCP蛋白質的表現………………………………….........………109
3.4 MCP蛋白質的純化………………………………….................…109
3.5 西方墨點分析 (Western analysis) ………………………………111
3.6 建立以ELISA偵測MCP之系統…………………………………112
第四章、結論…………………………………………………………………115
參考文獻…………………………………………………………….........…117
dc.language.isozh-TW
dc.subject快速免疫法RIMMSzh_TW
dc.subject海鱺淋巴囊腫病zh_TW
dc.subject虹彩病毒zh_TW
dc.subject主要鞘蛋白zh_TW
dc.subject單株抗體zh_TW
dc.subjectmonoclonal antibody(mAb)en
dc.subjectRIMMS.en
dc.subjectCobia lymphocystis diseaseen
dc.subjectiridovirusen
dc.subjectmajor capsid proteinen
dc.title利用基因重組大腸桿菌表現海鱺淋巴囊腫病毒
之主要鞘蛋白及其單株抗體生產與分析系統之建立		zh_TW
dc.titleExpression of the Major Capsid Protein of Cobia (Rachycentron canadum) Lymphocystis Disease Virus by recombinant E. coli and the production of its monoclonal antibodyen
dc.typeThesis
dc.date.schoolyear93-2
dc.description.degree碩士
dc.contributor.oralexamcommittee劉雨田,許文林,周淑芬,張谷昇
dc.subject.keyword海鱺淋巴囊腫病,虹彩病毒,主要鞘蛋白,單株抗體,快速免疫法RIMMS,zh_TW
dc.subject.keywordCobia lymphocystis disease,iridovirus,major capsid protein,monoclonal antibody(mAb),RIMMS.,en
dc.relation.page122
dc.rights.note未授權
dc.date.accepted2005-07-19
dc.contributor.author-college生命科學院zh_TW
dc.contributor.author-dept微生物與生化學研究所zh_TW
Appears in Collections:微生物學科所

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