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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 林彥蓉 | |
dc.contributor.author | Ching-Shan Tseng | en |
dc.contributor.author | 曾清山 | zh_TW |
dc.date.accessioned | 2021-06-17T00:31:32Z | - |
dc.date.available | 2012-03-19 | |
dc.date.copyright | 2012-03-19 | |
dc.date.issued | 2012 | |
dc.date.submitted | 2012-02-10 | |
dc.identifier.citation | [1] 行政院主計處。2007。94年農林漁牧普查報告-初步綜合報告。台北:行政院主計處。
[2] 行政院農業委員會種子檢查室。1990。台灣地區農作物種苗檢查須知。p.1-58。 [3] 賴光隆。1979。水稻根群形成的特性與活力之診斷。台灣二期作稻作低產原因及其解決方法研討會專集。P.77-84。行政院國家委員會研討會專集(二)。 [4] Adair, C. R. 1934. Studies on blooming in rice. Agron. J. 26: 965-973. [5] Agawal, R. L. 1980. Seed technology. New Dlhi Mohar Oxford & IBH Publishing. p83-254. [6] Altman, D. W. 1991. Quantitative trait variation in phenotypically normal regenerants of cotton. In Vitro Cell DevBiol. 27: 132-138. [7] Amagasa, K. 2008. Buffer zones can not prevent GMO cross-contamination. http://www.gmwatch.org/latest-listing/1-news-items/9542-buffer-zones-can-not-prevent-gmo-cross-contamination- [8] Ammann, K. 2005. Effects of biotechnology on biodiversity: herbicide-tolerant and insect-resistant GM crops. Trends Biotechnol. 23:388-394. [9] Arnold, M. L. and S. A. Hodges. 1995. Are natural hybrids fit or unfit relative to their parents? Trends Ecol. Evol. 10:67-71. [10] Arriola, P. E. and N. C. Ellstrand. 1997. Fitness of interspecific hybrids in the genus Sorghum: Persistence of crop genes in wild populations. Ecol. Applic. 7:512-518. [11] Arritt, R. W., J. Astini, C. A. Clark, J. M. E. Westgabe, and A. S. Goggi. 2007. Biological windbreaks for pollen confinement. The 3rd International Conference on Coexistence between Genetically Modified (GM) and Non-GM Based Agricultural Supply Chains. Seville, Spain, 20-21 November 2007. 131-134. [12] Aycock, M. K. and C. C. Mckee. 1975. Root size variability among several cultivars and breeding lines of Maryland tobacco. Agron. J. 67:604-606. [13] Bajaj, S. and A. Mohanty. 2005. Plant Biotechnol. J. 3:275-307. [14] Benedict, J. H., E. S. Sachs, and D. W. Altman. 1996. Field performance of cottons expressing transgenic Cry1A insecticidal proteins for resistance to Heliothis virescens and Helicoverp azea. J. Econ. Entomal. 89:230-238. [15] Bergelson, J., C. B. Purington, and G. Wichmann. 1998. Promoiscuity in transgenic plants. Nature. 395:25. [16] Bio Journal. 2008. Cross-fertilization by airborne pollen found at surprisingly large distances. http://www5d.biglobe.ne.jp/~cbic/english/2008/journal0805.html [17] Bishun, D. P., J. Sanjay, and B. C. Bharat. 2008. Transgenic indica rice expressing Mirabilis jalapa antimicrobial protein (Mj-AMP2) shows enhanced resistance to the rice blast fungus Magnaporthe oryzae. Plant Sci. 175:364-371. [18] Burris, T. S., O. T. Edje, and A. H. Wahab. 1971. Effects of seed size on seedling performance in soybeans: I. Seedling growth and respiration in the dark. Crop Sci. 11:492-496. [19] Chandler, S. and J. M. Dunwell. 2008. Gene flow, risk assessment and the environmental release of transgenic plants. Criti. Rev. Plant Sci. 27:25-49. [20] Chang, T. T. 1976. The origin, evolution, cultivation, dissemination, and diversification of Asian and Afirican rices. Euphytica. 25:425-441. [21] Chen, L. J., H. S. Suh, D. S. Lee, W. Y. Gang, J. Y. Jung, and S. S. Kim. 2002. Field assessment of herbicide resistance gene flow to weedy rice (Oryza sativa) [abstract]. In International Rice Congress; September 16-20, 2002; Beijing, China. p. 273. [22] Chen, L. J., D. S. Lee, Z. P. Song, H. S. Suh, and B. R. Lu. 2004. Gene flow from cultivated rice (Oryza sativa) to its weedy and wild relatives. Ann. Bot. 93:67-73. [23] Cheng, K.J., L.B. Sellnger, L.J. Yanke, H.D. Bae, L. Zhou, C.W. Forsberg. 1999. Phytases of ruminal microorganisms. US Patent No. 5,939,303. [24] Chiang, C. M., F. S. Yeh, T. H. Tseng, C. S. Wang, H. S. Lur, J. F. Shaw, and S. M. Yu. 2005. Expression of a bifunctional and thermostable amylopullulanase in transgenic rice seeds leads to starch autohydrolysis and altered composition of starch. Mol. Breed. 15:125-143. [25] Clive, J. 2010. Global Status of Commercialized Biotech/GM Crops. ISAAA Briefs 42. [26] Conner, A. J., T. R. Glare, and J. P. NAP. 2003. The release of genetically modified crops into th environment. PartII. Overview of ecological risk assessment. Plant J. 33:19-46. [27] Council of Agriculture. 2008. Annual Report of Rice Improvement. http://www.afa.gov.tw/Public/GrainStatistics/20094221216525334.pdf. [28] Cui, H. R., Q. Y. Shu, and Y. B. Xiang. 1998. Field performances of transgenic rice with a cry1 Ab gene. p.810-815. in: Exploration and Investigation on Life Sciences. (Zhu M. Y., Y. N. Li, eds.) Hangzhou: Hangzhou Univ. Press. [29] Daleck, Y. A., T. D. Bourgue, And S. Ponsard. 2007. Does the European corn borer disperse enough for a sustainable control of resistanceto Bt maize via the high dose/refuge strategy ? Cahiers Agric. 16:171-176. [30] Damgaard, C. and G. Kjellsson. 2005. Gene flow of oilseed rape (Brassica napus) according to isolation distance and buffer zone. Agric. Ecosyst. Env.. 108:291-301. [31] David, R. G., H. M. Donna, and J. N. Rutger. 2003. Gene Flow Between Red Rice (Oryza sativa) and Herbicide-Resistant Rice (O. sativa): Implications for Weed Management. Weed Technol. 17:627-645. [32] DEFRA. 2006. Consultation on Proposals for Managing the Coexistence of GM, Conventional and Organic Crops. London. p.92. [33] Devos, Y., D. Reheul, and A. Schrijver. 2005. The co-existence between transgenic and non-transgenic maize in the European Union: a focus on pollen flow and cross-fertilization. Env. Biosafety Res. 4:71-87. [34] Duan, Y. B., F. L. Zhao, and D. K. Zhao. 2007. Study on the seed germination and seedling chilling tolerance of transgenic rice with isopentenyl transferase (ipt). J. Anhui Agric. Sci. 35(6):1591-1592. (in Chinese) [35] Eastman, K. and J. Sweet. 2002. Eur. Env. Agency, p1-75. [36] Ellis, R. H. and E. H. Roberts 1981 The quantification of aging and survival in orthodox seeds. Seed Sci. and Tech. 9:373-409. [37] Ellstrand, N. C., H. C. Prentice, and J. F. Hancock. 1999. Gene flow and introgression from domesticated plants into their wild relatives. Annual Review of Ecol. Syst. 30:539-563. [38] Ellstrand, N. C. and D. R. Elam. 1993. Population genetic conse- quences of small population size: Implication for plant conservation. Annu. Rev. Ecol. Syst. 24:217-242. [39] Estorninos, L. E., D. R. Gealy, T. L. Dillon, F. L. Baldwin, R. R. Burgos, and T. H. Tai. 2002. Determination of hybridization between rice and red rice using four microsatellite markers. Proc. South. Weed Sci. Soc. 55:197-198. [40] Farris, M. A. and J. B. Mitton. 1984. Population density, outcrossing rate, and heterozygote superiority in ponderosa pine. Evolution. 38:1151-1154. [41] Fisher, K. S., J. Barton, G. S. Khush, H. Leung, and R. Cantrell. 2000. Genomics and Agriculture. Collaborations in rice. Science. 290:279-280. [42] Gepts, P. 2002. A comparison between crop domestication, classical plant breeding, and genetic engineering. Crop Sci. 42:1780-1790. [43] Germ, H. 1960. Methodology of the vigour test for wheat, rey and barley in rolled filter paper. Proc. Int. Seed Test. Ass. 25:515-518. [44] Govindaraju, D. R. 1988a. Relationship between dispersal ability and levels of gene flow in plants. Oikos. 52:31-35. [45] Govindaraju, D. R. 1988b. A note on the relationship between outcrossing rate and gene flow in plants. Heredity. 61:401-404. [46] Gura, T. 1999. Biotechnology. New genes boost rice nutrients. Science. 285:994-995. [47] Hancock, J. E. and L. E. Hokanson. 2001. Invasiveness of transgenic vs. exotic plant species: how useful is the analogy ? p.187-192. in the Proceeding of the First International Symposium on Ecological and Societal Aspects of Transgenic Plantations. [48] Hasler, C. M. 2000. The changing face of functional foods. J. Am. Coll. Nutr. 19:499-506. [49] Hayashimoto, A. L. and N. Murai. 1990. Aployethyleneglycol mediated protop last transformation system for the production of fertile transgenic rice plants. Plant Physiol. 93:857-863. [50] He, L. F., S. Q. Wei, and S. A. Lu. 2002. Studies on the variations of agronomic characteristic from rice transformed with SCK gene progeny. J. Guangxi Agric. Biol. Sci. 21:73-77. (in Chinese) [51] Heslop-Harrison, J. and Y. Heslop-Harrison. 1970. Evaluation of pollen viability by induced fluorescence; intracellular hydrolysis of fluorescein diacetate. Stain Technol. 45:115-120. [52] Heydecker, W. 1962. From seed to seedling: fsctors affecting the establishment of vegetable crops. Ann. Appl. Biol. 50:622-627. [53] Hokanson, S. C., J. F. Hancock. And R. Grumet. 1994. Can border rows serve to limit the long distance movement of transgenic pollen ? In: Jones DD (ed.) Proceedings of the 3rd International Symposium on the Biosafety Results of Field Tests of Genetically Modified Plants and microorganisms. The Univ. of California, Oakland, California. pp.418 [54] Hong, C. Y., K. J. Chen, L. F. Liu, T. H. Tseng, C. S. Wang, and S. M. Yu. 2004. Production of two highly active bacterial phytases with broad pH optima in germinating transgenic rice seeds. Transgenic Res. 13:29-39. [55] Hu, H., M. Dai, J. Yao, B. Xiao, X. Li, Q. Zhang, and L. Xiong. 2006. Overexpressing a NAM, ATAF, and CUC (NAC) transcription factor enhances drought resistance and salt tolerance in rice. Proc. Natl. Acad. Sci. U.S.A. 103: 12987-12992. [56] Huang, J., R. Hu, R. Rozelle, and C. Pray. 2005. Insect-resistance GM rice in farmers' field: assessing productivity and health effects in China. Science. 308:688-690. [57] Ingram, J. 2000. Review of the Use of Separation Distances Between GM and Other Crops. MAFF Research Project, RG0123. [58] IRRI. 1996. Standard Evaluation System for Rice. IRRI press, Los Banos, Laguna, Philippines. 52 pp. [59] Ishida, H. and T. Sasahara. 1989. Correlations between Floral Characters and the Days to Heading in Rice (Oryza sativa L.). Jan. J. of breeding. 39:275-283. [60] Jarvis, D. I. and T. Hodgkin. 1999. Wild relatives and crop cultivars: detecting natural introgression and farmer selection of new enetic combinations in agroecosystems. Mol. Ecol. 8:159-173. [61] Jia, H., K. S. Jayaraman, and S. Louet. 2004. China ramps up efforts to commercialize GM rice. Nat. Biotechnol. 22:642. [62] Jia, S., F. Wang, L. Shi, Q. Yuan, W. Liu, Y. Liao, S. Li, W. Jin, and H. Peng. 2007. Transgene flow to hybrid rice and its male-sterile lines. Transgenic Res. 16:491-501. [63] Jodon, N. E. 1938. Experiments on artificial hybridization of rice. Agron. J. 30:294-305. [64] Kato, H. and H. Namai. 1987. Floral characteristics and environment factors for increasing natural outcrossing rate for F1 hybrid seed production of rice Oryza sativa L. J. Breed. 37: 318-330. (in Japanese with English summary) [65] Kaufmann, M. L. and A. A. Guitard. 1967. The effect of seed size on early plant development in barley. Can. J. Plant Sci. 47:73-78. [66] Kawahigashi, H., S. Hirose, H. Ohkawa, and Y. Ohkawa, 2007. Herbicide resistance of transgenic rice plants expressing human CYP1A1. Biotechnol. Adv. 25: 75-84. [67] Khush, G. S. 1993. Floral structure, pollination biology, breeding behaviour, transfer distance and isolation considerations. World Bank Technical Paper, Biotechnology Series No1, Rice Biosafety. The Rockefeler Foundation. [68] Khush, G. S. 2005. What it will take to feed 5.0 billion rice consumers in 2030. Plant Mol. Bio. 59:1-6. [69] Klinger, T. and N. C. Ellstrand. 1999. Transgenic movement via gene flow:Recommendations for improved biosafety assessment. p.129-140. In K. Ammann et al. (ed.) Methods for risk assessment of transgenic plants: III. Ecological risks and prospects of transgenic plants. Birkha¨user Verlag, Basel, Switzerland. [70] Krishnan, S., K. Datta, N. Baisakh, M. D. Vasconcelos, and S. K. Datta. 2003. Tissue specific localization of b-carotene and iron in transgenic indica rice (Oryza sativa L.). Curr. Sci. 84:1232-1234. [71] Kumar, V., R. R. Bellinder, D. C. Brainard, R. K. Malik, and R. K. Gupta. 2008. Risks of herbicide-resistant rice in India: A review. Crop Prot. 27:320-329. [72] Lee, J. T., V. Prasad, P. T. Yang, J. F. Wu, Y. Y. Charng, T. H. D. Ho, and M. T. Chan. 2003. Expression of Arabidopsis CBF1 regulated by an ABA/stress inducible promoter in transgenic tomato confers stress tolerance without affecting yield. Plant Cell Env. 26:1181-1190. [73] Lefol, E., A. Fleury, and H. Darmency. 1996. Gene dispersal from transgenic crops Ⅱ. Hybridization between oilseed rape and the wild hoary mustard. Sex Plant Reprod. 9:189-196. [74] Leuhrsen, K. R. 1990. Insertion of Mulelements in the first intron of the Adh 12S gene of maize results in novel RNA p rocessing events. Plant Cell. 2:1225-1238. [75] Li, G. P., K. M. Wu, and F. Gould. 2007. Increasing tolerance to Cry1Ac cotton from cotton boll worm, Helicoverpa armigera, was confirmed in Bt cotton farming area of China. Ecol. Entom. 32:366-375. [76] Li, X., Z. M. Z. Liang, and G. Q. Zhou. 2002. Effect of environment condition on pollen vigor and seed set during flowing time of rice. Acta Agron Sin. 28:417-420. [77] Lin, S. S., M. L. Peterson, and D. B. Jones. 1974. Low temperature induced floret sterility in rice. In Proceedings of the Fifteenth Rice Technical Working Group. College Station, TX: Texas Agricultural Experiment Station. pp.22-23. Marchezan, E., F. M. [78] Lord, L. 1935. The cultivation of rice in Ceylon. J. Exp. Agric. 3:119-128 [79] Lu, B. A. and A. A. Snow. 2005. Gene flow from genetically modified rice and its environmental consequences. BioScience. 55:669-678. [80] Lu, B. A., Z. P. Song, and J. K. Chen. 2003. Can transgenic rice cause ecological risks through transgene escape? Prog. Nat. Sci. 13:17-24. [81] Lynch, P. T., J. Jones, and N. W. Blackhall. 1995. The phenotypic characterization of R2 generation transgenic rice plants under field and glasshouse conditions. Euphytica. 85:395-401. [82] Majee, M., S. Maitra, K. Ghose, S. Pattnaik, A. Chatterjee, N. Hait, K. P. Das, and A. L. Majumder. 2004. A novel salt-tolerant L-myo-inositol 1-phosphate synthase from Porteresia coarctata Tateoka , a halophytic wild rice: Molecular cloning, bacterial overexpression, characterization and functional introgression into tobacco conferring salt-tolerance phenotype. J. Biol. Chem. 279:28539-28552. [83] Malone, L. A., E. P. Burgess, D. Stefanovic, and H. S. Gatehouse. 2000. Effects of four protease inhibitors on the survival of worker bumblebees, Bombus terrestris L. Apidologie. 31:25-38. [84] Manasse, R.S. 1992. Ecological risks of transgenic plants: Effects of spatial dispersion on gene flow. Ecol. Applic. 2:431-438. [85] Mascia, P. N. and R. B. Flavell. 2004. Safe and acceptable strategies for producing foreign molecules in plants. Curr. Opin. Plant Biol. 7:189-195. [86] Mercer, K. L., D. A. Andow, and D. L. Wyse. 2007. Stress and domestieation traits increase the relative fitness of crop-wild hybrids in sunflower. Ecology Letters. 10:383-393. [87] Messeguer, J. 2003.Gene flow assessment in transgenic plants. Plant Cell, Tissue and Organ Culture. 73:201-212. [88] Messeguer, J., C. Fogher, E. Guiderdoni, V. Marfà, M. M. Català, G. Baldi, and E. Melé. 2001. Field assessment of gene flow from transgenic to cultivated rices (Oryza sativa L.) using a herbicide gene as tracer marker. Theor. Appl. Genet. 103:1151-1159. [89] Messeguer, J., V. Marfà, M. M. Català, E. Guiderdoni, and E. Melé. 2004. A field study of pollen-mediated gene flow from Mediterranean GM rice to conventional rice and the red rice weed. Mol. Breed. 13:103-112. [90] Mikkelsen, T. R. 1996. The risk of crop transgene spread. Nature. 380:31. [91] Nanda, K. K., J. J. Chinoy, and S. M. Gupta. 1959. A method for the determination of the rate of seedling growth and its application to the study of the effect of presowing hardening treatment on wheat grain. Phyton. 12:153-155. [92] NRC (National Research Council) 2002. Environmental Effects of Transgenic Plants: The Scope and Adequacy of Regulation. National Academy Press. Washington, DC. pp.317. [93] Oard, J. H., K. A. Cock, and J. H. Gomez. 1998. Development, field evaluation and agronomic performance of transgenic herbicide resistant rice. Mol. Breeding. 44(1): 67-70. [94] OECD 1993. Group of National Experts on Safety in Biotechnology. Analysis of field release experiments. Organisation for Ecinomic Co-operation and Development, Par. [95] Oka, H. I. 1988. Origin of cultivated rice. Japan Sci Soc Press, Tokyo [96] Oliveira, A. R., T. R. Castro, and M. F. Capalbod. 2007. Toxicological evaluation of genetieally modified cotton( Bollgard') and Dipe1 WP on the non-target soil mite Schezoribates praeincisus (Aeari: Oribatida). Exp. Appl. Acarol. 41:191-201. [97] Paine, J. A., C. A. Shipton, S. Chaggar, R. M. Howells, M. J. Kennedy, G. Vernon, S. Y. Wright, E. Hinchliffe, J. L. Adams, A. L. Silverstone, and R. Drake. 2005. Improving the nutritional value of Golden Rice through increased pro-vitamin A content. Nat. Biotechnol. 23:482-487. [98] Peñas, G., M. Català, E. Melé, T. Llorach, E. Pla, and J. Messeguer. 2007. Effects of field size and physical barriers on GM-pollen mediated gene flow in rice. The 3rd International Conference on Coexistence between Genetically Modified (GM) and Non-GM Based Agricultural Supply Chains. Seville, Spain, 20-21 November 2007. [99] Peng, J., H. Kononowicz, and T. K. Hodges. 1992. Transgenic indica rice plants. Theor Appl Genet. 83:855-863. [100] Prescher, S., J. Schiemann, and A. Hüsken. 2010. Study of maize fields and their surroundings in European regions regarding the suitability for coexistence of different maize cultivars. In B. Breckling and R. Verhoeven eds., Implication of GM-Crop Cultivation at Large Spatial Scales. Peter Lang, Frankfurt, German. [101] Ramessar, K., A. Peremarti, S. Go´mez-Galera, S. Naqvi, M. Moralejo, P. Mun˜oz, T. Capell, and P. Christou. 2007. Biosafety and risk assessment framework for selectable marker genes in transgenic crop plants: a case of the science not supporting the politics. Transgenic Res. 16:261-280. [102] Remund, K., D. Dixon, D. Wright, and L. Holden. 2001. Statistical considerations in seed purity testing for transgenic traits. Seed Sci. Res. 11:101-120. [103] Rong, J., B. R. Lu, Z. Song, J. Su, A. A. Snow, X. Zhang, S. Sun, R. Chen, and F. Wang. 2007. Dramatic reduction of crop-to-crop gene flow within a short distance from transgenic rice fields. New Phytol. 173:346-353. [104] Rong, J., Z. Song, T. J. Jong, X. Zhang, S. Sun, X. Xu, H. Xia, B. Liu, and B. R. Lu. 2010. Modelling pollen-mediated gene flow in rice: risk assessment and management of transgene escape. Plant Biotechnol. J. 8:452-464. [105] Saha, P., P. Majumder, I. Dutta, T. Ray, S. C. Roy, and S. Das, 2006. Transgenic rice expressing Allium sativum leaf lectin with enhanced resistance against sap-sucking insect pests. Planta 23:1329-1343. [106] Scheffler, J., R. Parkinson, and P. J. Dale. 1993. Frequency and distance of pollon dispersal from transgenic oil seed rap (Brassican apus). Transgenic Res. 2:356-36. [107] Sears, M. K., R. L. Hellmich, D. E. Stanley-Horn, K. S. Oberhauser, J. M. Pleasants, H. R. Mattila, B. D. Siegfried, and G. P. 2001. Dively. Impact of Bt corn pollen on monarch butterfly populations: A risk assessment. Proceeding of National Academy Sciences. USA. 98:11937-11942. [108] Shelton, A. M. and M. K. Sears. 2001. The monarch butterfly Controversy: scientific intelpretations of a phenomenon. The Plant Journal. 27:483-488. [109] Shivanna, K. R. and N. S. Rangaswamy. 1992. Pollen biology: a laboratory manual. Springer, Berlin Heidelberg New York. pp.9-20. [110] Shivrain, V.K., N. R. Burgos, M. M. Anders, S. N. Rajguru, J. Moore, and M A. Sales. 2007. Gene flow between ClearfieldTM rice and red rice. Crop Prot. 26:349-356. [111] Sivaprakash, K. R., S. Krishnan, S. K. Datta, and A. K. Parida. 2006. Tissue-specific histochemical localization of iron and ferritin gene expression in transgenic indica rice Pusa Basmati (Oryza sativa L.). J. Genet. 85:157-160. [112] Song, X. L., S. Qiang, and M .Z. Sun. 2003. Gene Flow Between Herbicide Resistant Transgenic Rice and Echinochloa crusgalli var. mitis Under Mentor Pollen Inducement. Chinese J. Rice Sci. 17(3):191-195 [113] Song, X. L., S. Qiang, L. L. Liu, and Y. H. Xu. 2002. Assessment on gene flow through detection of sexual compatibility between transgenic rice with bar and Echinochloa crusgalli var. mitis. Acta Agric. Sin. 35(10):1128 - 1131. [114] Song, X., L. Liu, Z. Wang, and S. Qiang. 2009. Potential gene flow from transgenic rice (Oryza sativa L.) to different weedy rice (Oryza sativa f. spontanea) accessions based on reproductive compatibility. Pest Manag. Sci. 65:862-869. [115] Song, Z. P., B. R. Lu, Y. G. Zhu, and J. K. Chen. 2002. Pollen competition between cultivated and wild rice species (Oryza sativa and O. rufipogon). New Phytol. 153:289-296. [116] Song, Z.P., B. R. Lu, and J. K. Chen. 2004. Pollen flow of cultivated rice measured under experimental conditions. Biodivers. Conserv. 13:579-590. [117] Song, Z.P., B. R. Lu, Y. G. Zhu, and J. K. Chen. 2003. Gene flow from cultivated rice to wild species Oryza rufipogon under experimental field conditions. New Phytol. 157:657-665. [118] Stanley-Horn, D. E., G. P. Dively, R. L. Hellmich, H. R. Mattila, M. K. Sears, R. R. Laura, C. H. Jesse, J. E. Losey, J. J. Obrycki, and L. Lewis. 2001. Assessing the impact of Cry1Ab-expressing corn pollen on monarch butterfly larvae in field studies. Proceeding of National Academy of Seiences, USA. 98:11931-11936. [119] Stelly, D. M., D. W. Altman, and R. J. Kohel. 1989. Cytogenetic abnormalities of cotton somaclones from callus cultures. Genome. 32:762-770. [120] Ting, M.Y., H. D. Shih, and C. Y. Lin. 2008. Increased susceptibility of rice following insertion of amylopullulanase gene, to brown spot caused by Bipolaris oryzae. J. Phytopathol. 156:530-533. [121] Tsay, J.Y., R. B. Chen, J. C. Chang, C. H. Liao, H. Y. Yang, S. R. Wang, and L. J. Chen. 2001. Production of porcine lactoferrin in transgenic rice. The 3rd Cross-strait Symposium on Plant Molecular Biology and Biotechnology. Hong Kong, 5-11 August 2001. [122] Lijsebettens, M., R. Vanderhaeghen and M. Montagu. 1991. Insertional mutagenesis in Arabidopsis thaliana: isolation of a TDNA linked mutation that alters leaf morphology. Theor Appl Genet. 81:277-284. [123] Wang, M. J. and Z. P. Xu. 1994. Relationship of pollen vigor with fertility of Nongken 58s. Hubei Agric. Sci. 2:5. [124] Wang, F., Q. H. Yuan. L. Shi, Q. Qian, W. G. Liu, B. G. Kuang, D. L. Zeng, Y. L. Liao, B. Cao, and S. R. Jia. 2006. A large-scale field study of transgene flow from cultivated rice (Oryza sativa) to common wild rice (O. rufipogon) and barnyard grass (Echinochloa crusgalli). Plant Biotechnol. J. 4:667-676. [125] Woodstock, L. W. 1969. Seedling growth as a measure of seed vigor. Proc. Int. Seed Test. Ass. 34:273-280. [126] Wu, W. X., Q. F. Ye, and H. Min. 2003. Bt-transgenic rice straw affects the culturable microbiota and dehydrogenase and phosphatase activities in a flooded paddy soi1. Biol. Biochem. 36:289-295. [127] Xu, H. B., G. M. Wang, and M. Wei. 2001. Correlation analysis of the characters of pollen grains and seed-setting of rice under high temperature stress. J. Southwest Agric Univ. 23:205-207. [128] Ye, X., S. Al-Babili, A. Klöti, J. Zhang, P. Lucca, P. Beyer, and I. Potrykus. 2000. Engineering the provitamin A (beta-carotene) biosynthetic pathway into (carotenoid-free) rice endosperm. Science. 287:303-305. [129] Yuan, Q. H., L. Shi, F. Wang, B. Cao, Q. Qian, X. M. Lei, Y. L. Liao, W. G. Liu, L. Cheng, and S. R. Jia. 2007. Investigation of rice transgene flow in compass sectors by using male sterile line as a pollen detector. Theor. Appl. Genet. 115:549-560. [130] Zhang, S., D. Warkentin, and B. Sun. 1996. Variation in the inheritance of expression among subclones for unselected (uidA) and selected (bar) transgenes in maize ( Zea mays L.). Theor. Appl. Genet. 92:752-761. [131] Zhang, N., S. Linscombe, and J. Oard. 2003. Outcrossing frequency and genetic analysis of hybrids between transgenic glufosinate herbicide-resistant rice and the weed, red rice. Euphytica. 130:35-45. [132] Zhang, Q. J., C. G. Lu, S. J. Xia, S. Y. Zong, Q. M. Qi, D. R. Yu, and Y. H. Sun. 2008. Obtaining transgenic rice plants harboring sbk and sck insecticidal genes. Mol. Plant Breed. 6:49-52. | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/66351 | - |
dc.description.abstract | 近年來應用基因轉殖技術所培育出之基因轉殖作物,其種類及栽培面積逐年上升,然而生物安全議題和對環境風險的影響也受到越來越多的關注。本研究利用台農67號 (Oryza sativa L. ssp japonica, TNG 67) 的3個基因轉殖水稻為材料,分別為轉殖澱粉普魯楠糖水稻 (APU) 、轉殖豬乳鐵蛋白水稻 (LAC) 和轉殖植酸酵素水稻 (AAN) ,進行農藝性狀之調查、基因轉殖水稻外源基因藉由花粉媒介的基因流佈頻率之田間評估和防範基因轉殖水稻花粉污染的策略,以瞭解基因轉殖水稻在商業化生產種植前,對目前已有之水稻耕作及環境無不良影響。
在田間評估試驗中,進行為期一年二期作的農藝及產量性狀評估,結果顯示轉殖澱粉普魯楠糖水稻、轉殖豬乳鐵蛋白水稻和轉殖植酸酵素水稻的農藝性狀與其受體品種台農67號水稻相比,普遍表現較差,三個轉殖品系每公頃產量皆低於台農67號水稻。在雜草化評估試驗中,包括種子生產量、不同溫度下種子最終發芽率與平均發芽時間及不同溫控下之幼苗生長勢,目前所得數據未顯示三個轉殖品系比台農67號水稻具有較大的優勢,由此推測,本研究三個轉殖品系轉變成雜草的風險性極小。 基因轉殖水稻花粉性狀評估試驗中,結果顯示轉殖澱粉普魯楠糖水稻的花粉數量、花粉離體發芽率及花粉活力均低於台農67號水稻。基因轉殖水稻花粉流佈田間試驗中,結果顯示在交叉種植設計中,以轉殖豬乳鐵蛋白水稻的花粉流佈頻率最高為7.82%,其次台農67號水稻及轉殖植酸酵素水稻分別為7.13%和5.91%,最低為轉殖澱粉普魯楠糖水稻只有3.18%。在間隔種植設計中,則以TNG 67的花粉流佈頻率最高為2.8%,其次LAC及AAN轉殖品系分別為2.32%和1.53%,最低為APU轉殖品系只有0.54%。整體而言三個轉殖品系的花粉流佈頻率平均為3.55%,低於其非基因轉殖的TNG 67的4.97%。 水稻花粉流佈之田間試驗中,貢獻親台農糯73號水稻的雜交種子頻率受到接受親台農67號水稻種植距離和方向所影響,花粉流佈頻率隨著種植距離增加而下降。在3 m內,8個方向皆有檢測到雜交種子,在相距1 m時其花粉流佈平均頻率為1.68%,在2 m及3 m處分別為0.74%及0.61%。在距離5 m處仍有6個方向測得雜交種子,在距離30 m和35 m處僅有1個地方檢測到雜交種子,花粉流佈頻率平均從0.33%到0.01%,超過40 m並未發現有任何雜交種子。在南方及東南方35 m內有顯著地測得較高的雜交種子,花粉流佈頻率平均分別為0.78%和0.73%,最遠在南方35 m處仍可以檢測到雜交種子。然而相對地在東北、西北及北方僅測到較少的雜交種子,在東北方及北方5 m以後未檢測到任何雜交種子。 有無緩衝區設置對水稻花粉流佈之評估試驗中,結果顯示有無緩衝區設置的效果受到距離及風向所影響。在順風狀況下,位於下風南方與東南方7 m之內,有無緩衝區設置對花粉流佈頻率差異不大,然而在9 m處其花粉流佈頻率有顯著的差別。緩衝區設置南方與東南方9 m處的花粉流佈頻率分別為0.83%和0.84%,而無緩衝設置則分別為1.53%和1.65%。在逆風狀況下,位於上風北方與東北方1、3和5 m處有緩衝區設置的花粉流佈頻率高於無緩衝區設置,但在7 m以後有緩衝區設置的花粉流佈頻率則明顯低於無緩衝區設置,顯示在上風處之風速較小的情況下,5 m的緩衝區設置仍可減少花粉流佈頻率。 利用2 m高、0.6 m寬之朱槿當綠籬設置對水稻花粉流佈之評估試驗中,在台農糯73號水稻並未發現有來自貢獻親轉殖植酸酵素水稻的雜交種子,其花粉流佈頻率為0%。顯示在本試驗條件下,利用朱槿當綠籬可以有效地防止台農糯73號水稻受到相鄰田區轉殖植酸酵素水稻花粉的污染。 | zh_TW |
dc.description.abstract | In recent years, more and more transgenic plants are being developed and cultivated for the commercial around the world. However, safety issues and environmental risks arisen by transgenic crops still evoke serious considerations. Three transgenic rice lines, line AAN, LAC, and APU, which were the phytase-, lactoferrine-, and amylopullulanase-gene transformed cv. Tainung 67 (Oryza sativa L. ssp japonica, TNG 67 ), respectively, were employed for investigation of agronomic traits of the transgenic lines, pollen-mediate gene flow in fields, and the strategy of preventing pollution of transgenic pollens The aim of study is to comprehend whether there is any negative influence on current rice cultivation and environments prior to commercialize transgenic rice or not.
Field trials of evaluating agronomic traits of three transgenic strains and TNG 67 were carried out in two crops seasons, the first crop season and the second crop seasons of 2004. Based on the evaluation of seed production, final germination rate and average germination time, and seedling growth under various temperatures, the three transgenic lines performed worse in agronomic traits and weediness assessment than TNG 67 did. All three important factors accounting for capabilities of pollen flow, quantity, germination rate, and viability of pollen were lower in the transgenic rice line, APU, than in the non-transgenic rice, TNG67. The mean frequency of outcrossed seeds was significantly lower from APU (3.18%) than TNG 67 (7.13%) In the arrangement of the checker-board pattern, the mean frequency of outcrossed seeds was 7.82%, 7.13%, 5.91%, and 3.18% in LAC (the highest), TNG 67, AAN, and APU (the lowest), respectively. In the alternating row arrangement, the mean frequency of outcrossed seeds was 2.8%, 2.32%, 1.53%, and 0.54% in TNG 67 (the highest), LAC, AAN, and APU (the lowest), respectively. Overall, the mean frequency of outcrossed seeds of three transgenic lines was 3.55% which was lower than their non-transgenic variety TNG 67 was 4.97%. In the open field, the frequency of outcrossed seeds varied with the distances and directions of the pollen donor TNG 67 to the pollen recipient TNG 73. Pollen dispersal leading to outcrossing was negatively associated with distance. Outcrossed seeds were found from all 8 directions within a 3-m distance. The mean frequency of outcrossed seeds was 1.68%, 0.74%, and 0.61% at the distance of 1, 2, and 3 m, respectively. Outcrossed TNG 73 seeds were still detected in 6 directions in 5-m plots and only 1 direction in 30- and 35-m plots, and the mean outcrossed TNG 73 seeds of each direction ranged from 0.33% to 0.01%. No outcrossed TNG 73 seeds were detected in any direction farther than 40 m. The frequency of outcrossed seeds was significantly higher in plots to the south and southeast, which showed the highest mean frequencies of outcrossed seeds (0.73% and 0.78%) and in the plot located at 35 m. Nevertheless, relatively fewer outcrossed seeds were observed from the plots to the northeast, northwest, and north, and no outcrossed seeds were detected from plots to the northeast and north beyond 5 m. With and without buffer zones were used for assessing pollen-mediated gene flow in the open fields, which results also indicated that the frequency of outcrossed seeds varied by the distances and directions. In the directions with wind, the frequency of outcrossed seeds of with and without buffer zone was not significantly difference in the south and southeast directions within 7 m. However, there was significantly different frequency of outcrosses seeds between plots with and without buffer zones at 9-m distance, which frequency of outcrossed seeds with buffer zone was 0.83% (south) and 0.84% (southeast) and without buffer zone was 1.53% (south) and 1.65% (southeast), respectively. In the directions against wind, the frequency of outcrossed seeds of plots with buffer zones was higher than those without buffer zones in the north and northeast at distance of 1, 3, and 5 m. Nevertheless, the frequency of outcrossed seeds of plots with buffer zones was significantly lower than those without buffer zone beyond 7 m. This study indicated 5-m buffer zones could decrease the frequency of outcrossed seeds by pollen-mediated gene flow in the directions against wind. Chinese hibiscus (Hibiscus rosa-sinensis L.) with 2-m tall and 0.6-m thick were used for assessing pollen-mediated gene flow. We found none outcrossed with pollen from AAN, regardless of the distance between recipient plants and donor plants. Thus, Chinese hibiscus as a green fence effectively prevented TNG 73 from outcrossing with pollen from phytase-transgenic rice in neighboring fields. | en |
dc.description.provenance | Made available in DSpace on 2021-06-17T00:31:32Z (GMT). No. of bitstreams: 1 ntu-101-D93621102-1.pdf: 5950717 bytes, checksum: 3e42d6a815e98156e1bd985db9c18d2d (MD5) Previous issue date: 2012 | en |
dc.description.tableofcontents | 口試委員會審定書 #
誌謝 ii 中文摘要 iii ABSTRACT v 目錄 vii 表目錄 x 圖目錄 xii Chapter 1 緒論 1 1.1 前言 1 1.2 基因轉殖作物概況及趨勢 1 1.3 基因轉殖作物的環境風險 2 1.4 基因轉殖水稻的環境風險 4 1.5 基因轉殖水稻基因流佈的要件 5 1.6 基因轉殖水稻基因流佈的途徑 7 1.7 結語 9 Chapter 2 基因轉殖水稻之田間生物安全性評估 10 2.1 前言 10 2.2 材料與方法 11 2.2.1 試驗地點 11 2.2.2 試驗材料 11 2.2.3 生物安全評估調查項目 12 2.2.4 基因轉殖水稻演變成有害植物 (如雜草等) 可能性之評估 13 2.3 結果 14 2.3.1 基因轉殖水稻農藝性狀及產量性狀之評估 14 2.3.2 基因轉殖水稻演變成有害植物 (如雜草等) 可能性之評估 18 2.4 討論 26 Chapter 3 基因轉殖水稻花粉流佈之田間評估 30 3.1 前言 30 3.2 材料與方法 33 3.2.1 水稻花粉性狀調查 33 3.2.2 不同基因轉殖水稻花粉流佈之研究 34 3.2.3 水稻花粉流佈田間評估之研究 37 3.3 結果 39 3.3.1 水稻花粉性狀調查 39 3.3.2 不同基因轉殖水稻花粉流佈結果 41 3.3.3 水稻花粉流佈田間評估結果 43 3.4 討論 47 3.4.1 花粉性狀與花粉流佈之關聯性 47 3.4.2 不同外源基因插入對花粉流佈之影響 47 3.4.3 花粉流佈與花粉密度和貢獻親距離之關聯性 48 3.4.4 氣象因子與花粉流佈之關聯性 49 Chapter 4 緩衝區及綠籬設置對基因轉殖水稻花粉流佈之影響 51 4.1 前言 51 4.2 材料與方法 53 4.2.1 緩衝區設置對基因轉殖水稻花粉流佈之影響 53 4.2.2 綠籬設置對基因轉殖水稻花粉流佈之影響 56 4.2.3 花粉流佈頻率評估 59 4.3 結果 60 4.3.1 緩衝區設置對花粉流佈之影響 60 4.3.2 綠籬設置對花粉流佈之影響 66 4.4 討論 67 4.4.1 緩衝區設置對防止花粉流佈之效果 67 4.4.2 氣象因子與緩衝區設置之關聯性 67 4.4.3 綠籬設置對防止花粉流佈之效果 68 參考文獻 70 | |
dc.language.iso | zh-TW | |
dc.title | 基因轉殖水稻之農藝性狀及花粉流佈評估 | zh_TW |
dc.title | Agronomic Traits and Pollen Flow Assessment of Transgenic Rice | en |
dc.type | Thesis | |
dc.date.schoolyear | 100-1 | |
dc.description.degree | 博士 | |
dc.contributor.oralexamcommittee | 黃懿秦,黃鵬林,彭雲明,胡凱康,張孟基 | |
dc.subject.keyword | 農藝性狀,生物安全性評估,緩衝區,綠籬,花粉性狀,花粉媒介基因流佈,基因轉殖水稻, | zh_TW |
dc.subject.keyword | Agronomic traits,Biosafety assessment,Buffer zone,Green fence,Pollen characters,Pollen-mediated gene flow,Transgenic rice, | en |
dc.relation.page | 84 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2012-02-10 | |
dc.contributor.author-college | 生物資源暨農學院 | zh_TW |
dc.contributor.author-dept | 農藝學研究所 | zh_TW |
顯示於系所單位: | 農藝學系 |
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