淹水逆境輔以高壓處理對提升毛豆γ-胺基丁酸含量之研究

Man-Shin Shiu; 許嫚芯

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/70939

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	徐源泰(Yuan-Tay Shyu)
dc.contributor.author	Man-Shin Shiu	en
dc.contributor.author	許嫚芯	zh_TW
dc.date.accessioned	2021-06-17T04:44:52Z	-
dc.date.available	2028-08-03
dc.date.copyright	2018-08-08
dc.date.issued	2018
dc.date.submitted	2018-08-02
dc.identifier.citation	1. 王雪芳. 2004. GABA之生理功效. 興大農業 49:19-23 2. 王輝、項麗麗、張鋒華. 2013. γ-胺基丁酸（GABA）的功能性及在食品中的應用. 食品工業 34(6):186-189 3. 台灣農家要覽策劃委員會. 台灣農家要覽. 1980. 豐年社. 臺北市 4. 吳昭慧、連大進. 1998. 毛豆之營養與效用. 臺南區農業專訊26:4-7 5. 吳玉婷、方怡丹. 2013. 台灣綠金-外銷毛豆生產專區概況與輔導成果. 農政與農情 253 6. 周國隆. 2006. 毛豆新品種『高雄9 號(綠晶)』問世. 高雄區農情月刊 101:3-4 7. 周國隆. 2008a. 毛豆外銷新尖兵-「高雄9號(綠晶)」. 高雄區農業專訊 65:8-9 8. 周國隆. 2008b. 毛豆外銷生力軍-高雄9號(綠晶). 高雄區農技報導 93:3-15 9. 周國隆. 2010. 毛豆高雄9號. 高雄區農業專訊 72:12 10. 姚琪、劉淑欣、張永忠. 2011. 大豆萌發過程中谷胺酸脫羧酶活性變化研究. 大豆科技 4:31-34 11. 陳冠妤. 2015. 高壓處理與其他富化技術提升豆科種子中γ-aminobutyric acid含量之研究. 國立臺灣大學園藝學系碩士論文. 臺北. 12. 張惠真. 2001. 黃豆營養與健康. 臺中區農業改良場八十九年度試驗研究暨推廣學術研討會報告摘要-特刊 49:46 13. 程台生、陳麗珠、連大進. 2006. 國產大豆抗氧化活性之研究. 作物、環境與生物資訊 3(4):325-336 14. 楊勝遠、陸兆新、呂鳳霞、別小妹. 2005. γ-胺基丁酸的生理功能和研究開發進展. 食品科學 26(9):546-551 15. 趙亞玲、邵岩、于娜. 2009. 鮮食毛豆的營養價值與栽培. 吉林蔬菜 6:55 16. 農委會農糧署. 農產品批發市場交易行情站. 2018年2月28日，取自: http://amis.afa.gov.tw/main/Main.aspx 17. 農委會. 農業統計資料庫. 2018年2月28日，取自: http://agrstat.coa.gov.tw/sdweb/public/trade/tradereport.aspx 18. 賴彥廷. 2017. 利用高壓加工技術提升毛豆γ-胺基丁酸含量及其抗憂鬱機能之研究. 國立臺灣大學園藝學系碩士論文. 臺北. 19. 衛生福利部食品藥物管理署. 2000. 現行藥品優良製造規範—分析確效作業指導手冊. 取自: https://www.fda.gov.tw/upload/46/11-%E8%A3%BD%E7%A8%8B%E7%A2%BA%E6%95%88%E4%BD%9C%E6%A5%AD%E6%8C%87%E5%B0%8E%E6%89%8B%E5%86%8A.pdf 20. 衛生福利部食品藥物管理署. 2013. 食品化學檢驗方法之確效規範第二次修正. 取自: https://www.fda.gov.tw/tc/siteList.aspx?sid=4115 21. 衛生福利部食品藥物管理署. 臺灣地區食品營養成分資料庫. 2018年2月27日，取自: https://consumer.fda.gov.tw/Food/TFND.aspx?nodeID=178 22. Abdou Adham, M., S. Higashiguchi, K. Horie, M. Kim, H. Hatta, and H. Yokogoshi. 2008. Relaxation and immunity enhancement effects of γ‐Aminobutyric acid (GABA) administration in humans. BioFactors 26(3):201-208. 23. Aghdam, M. S., R. Naderi, A. Jannatizadeh, M. Babalar, M. A. A. Sarcheshmeh, and M. Z. Faradonbe. 2016. Impact of exogenous GABA treatments on endogenous GABA metabolism in anthurium cut flowers in response to postharvest chilling temperature. Plant Physiology and Biochemistry 106:11-15. 24. Ahmed, F., M. Y. Rafii, M. R. Ismail, A. S. Juraimi, H. A. Rahim, R. Asfaliza, and M. A. Latif. 2013. Waterlogging Tolerance of Crops: Breeding, Mechanism of Tolerance, Molecular Approaches, and Future Prospects. BioMed Research International 2013:963525. 25. Akçay, N., M. Bor, T. Karabudak, F. Özdemir, and İ. Türkan. 2012. Contribution of Gamma amino butyric acid (GABA) to salt stress responses of Nicotiana sylvestris CMSII mutant and wild type plants. Journal of Plant Physiology 169(5):452-458. 26. Arazi, T., G. Baum, W. A. Snedden, B. J. Shelp, and H. Fromm. 1995. Molecular and Biochemical Analysis of Calmodulin Interactions with the Calmodulin-Binding Domain of Plant Glutamate Decarboxylase. Plant Physiology 108(2):551. 27. Armstrong, W. 1980. Aeration in Higher Plants. Advances in Botanical Research 7:225-332. 28. Arumugam, K., P. Tung, C. C. Chinnappa, and D. M. Reid. 1997. gamma-Aminobutyric acid stimulates ethylene biosynthesis in sunflower. Plant Physiology 115(1):129-135. 29. Awapara, J., A. J. Landua, R. Fuerst, and B. Seale. 1950. Free gamma-aminobutyric acid in brain. Journal of Biological Chemistry 187(1):35-39. 30. Bai, Q., M. Chai, Z. Gu, X. Cao, Y. Li, and K. Liu. 2009. Effects of components in culture medium on glutamate decarboxylase activity and γ-aminobutyric acid accumulation in foxtail millet (Setaria italica L.) during germination. Food Chemistry 116(1):152-157. 31. Bailey-Serres, J. and L. A. C. J. Voesenek. 2008. Flooding Stress: acclimations and genetic diversity. Annual Review of Plant Biology 59(1):313-339. 32. Bolarín, M. C., A. Santa-Cruz, E. Cayuela, and F. Pérez-Alfocea. 1995. Short-term Solute Changes in Leaves and Roots of Cultivated and Wild Tomato Seedlings Under Salinity. Journal of Plant Physiology 147(3):463-468. 33. Bouché, N. and H. Fromm. 2004. GABA in plants: just a metabolite? Trends in Plant Science 9(3):110-115. 34. Bouché, N., B. t. Lacombe, and H. Fromm. 2003. GABA signaling: a conserved and ubiquitous mechanism. Trends in Cell Biology 13(12):607-610. 35. Bowery, N. G. and T. G. Smart. 2006. GABA and glycine as neurotransmitters: a brief history. British Journal of Pharmacology 147(Suppl 1):S109-S119. 36. Bown, A. W., K. B. MacGregor, and B. J. Shelp. 2006. Gamma-aminobutyrate: defense against invertebrate pests? Trends in Plant Science 11(9):424-427. 37. Bradford, M. M. 1976. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical Biochemistry 72(1):248-254. 38. Calvo-Flores Guzmán, B., C. Vinnakota, K. Govindpani, H. Waldvogel, R. L Faull, and A. Kwakowsky. 2018. The GABAergic System as a Therapeutic Target for Alzheimer's Disease. Journal of Neurochemistry. 39. Chung, H.-J., S.-H. Jang, H. Y. Cho, and S.-T. Lim. 2009. Effects of steeping and anaerobic treatment on GABA (γ-aminobutyric acid) content in germinated waxy hull-less barley. LWT - Food Science and Technology 42(10):1712-1716. 40. Cohen, S. A. and D. J. Strydom. 1988. Amino acid analysis utilizing phenylisothiocyanate derivatives. Analytical Biochemistry 174(1):1-16. 41. Cooper, C., N. Packer, and K. Williams. 2001. Amino acid analysis protocols. Humana Press. 42. Daş, Z. A., G. Dimlioğlu, M. Bor, and F. Özdemir. 2016. Zinc induced activation of GABA-shunt in tobacco (Nicotiana tabaccum L.). Environmental and Experimental Botany 122:78-84. 43. Duhazé, C., G. Gouzerh, D. Gagneul, F. Larher, and A. Bouchereau. 2002. The conversion of spermidine to putrescine and 1,3-diaminopropane in the roots of Limonium tataricum. Plant Science 163(3):639-646. 44. Faës, P., M. Niogret, E. Montes, F. L. Cahérec, A. Bouchereau, and C. Deleu. 2015. Transcriptional profiling of genes encoding GABA-transaminases in Brassica napus reveals their regulation by water deficit. Environmental and Experimental Botany 116:20-31. 45. Fait, A., H. Fromm, D. Walter, G. Galili, and A. R. Fernie. 2008. Highway or byway: the metabolic role of the GABA shunt in plants. Trends in Plant Science 13(1):14-19. 46. Fehr, W. R. and C. E. Caviness. 1977. Stages of soybean development. Special Report 87. 47. Fortmeier, R. and S. Schubert. 1995. Salt tolerance of maize (Zea mays L.): the role of sodium exclusion. Plant, Cell and Environment 18(9):1041-1047. 48. Fukao, T., K. Xu, P. C. Ronald, and J. Bailey-Serres. 2006. A variable cluster of ethylene response factor–like genes regulates metabolic and developmental acclimation responses to submergence in rice. The Plant Cell 18(8):2021. 49. Gibberd, M. R., J. D. Gray, P. S. Cocks, and T. D. Colmer. 2001. Waterlogging Tolerance Among a Diverse Range of Trifolium Accessions is Related to Root Porosity, Lateral Root Formation and ‘Aerotropic Rooting’. Annals of Botany 88(4):579-589. 50. Hamed, S. A. 2016. The effect of epilepsy and antiepileptic drugs on sexual, reproductive and gonadal health of adults with epilepsy. Expert Review of Clinical Pharmacology 9(6):807-819. 51. Hao, H., T. Zhou, T. Koutchma, F. Wu, and K. Warriner. 2016a. High hydrostatic pressure assisted degradation of patulin in fruit and vegetable juice blends. Food Control 62:237-242. 52. Hao, J., T. Wu, H. Li, W. Wang, and H. Liu. 2016b. Dual effects of slightly acidic electrolyzed water (SAEW) treatment on the accumulation of γ-aminobutyric acid (GABA) and rutin in germinated buckwheat. Food Chemistry 201:87-93. 53. Hattori, Y., K. Nagai, and M. Ashikari. 2011. Rice growth adapting to deepwater. Current Opinion in Plant Biology 14(1):100-105. 54. Hirabayashi, Y., R. Mahendran, S. Koirala, L. Konoshima, D. Yamazaki, S. Watanabe, H. Kim, and S. Kanae. 2013. Global flood risk under climate change. Nature Climate Change 3:816. 55. Hu, X., Z. Xu, W. Xu, J. Li, N. Zhao, and Y. Zhou. 2015. Application of γ-aminobutyric acid demonstrates a protective role of polyamine and GABA metabolism in muskmelon seedlings under Ca(NO3)2 stress. Plant Physiology and Biochemistry 92:1-10. 56. Hurtado, A., P. Picouet, A. Jofré, M. D. Guàrdia, J. M. Ros, and S. Bañón. 2015. Application of high pressure processing for obtaining “fresh-like” fruit smoothies. Food and Bioprocess Technology 8(12):2470-2482. 57. Hyun, T. K., S. H. Eom, X. Han, and J.-S. Kim. 2014. Evolution and expression analysis of the soybean glutamate decarboxylase gene family. Journal of Biosciences 39(5):899-907. 58. Ishikawa, K. and S. Saito. 1978. Effect of intraventricular γ-aminobutyric acid (GABA) on discrimination learning in rats. Psychopharmacology 56(2):127-132. 59. Kasagi, M., T. Motegi, K. Narita, K. Fujihara, Y. Suzuki, M. Tagawa, K. Ujita, H. Shimada, and M. Fukuda. 2018. γ-Aminobutyric acid type A receptor binding affinity in the right inferior frontal gyrus at resting state predicts the performance of healthy elderly people in the visual sustained attention test. International Psychogeriatrics:1-7. 60. Kim, Y., S. Hwang, M. Waqas, A. L. Khan, J. Lee, J. Lee, H. T. Nguyen, and I. Lee. 2015. Comparative analysis of endogenous hormones level in two soybean (Glycine max L.) lines differing in waterlogging tolerance. Frontiers in Plant Science 6:714. 61. Kinnersley, A. M. and F. J. Turano. 2000. Gamma Aminobutyric Acid (GABA) and Plant Responses to Stress. Critical Reviews in Plant Sciences 19(6):479-509. 62. Kisaka, H., T. Hiroaki, and T. Miwa. 2006. Antisense suppression of glutamate decarboxylase in tomato (Lycopersicon esculentum L.) results in accumulation of glutamate in transgenic tomato fruits. Plant Biotechnology 23(3):267-274. 63. Komatsu, S., M. Tougou, and Y. Nanjo. 2015. Proteomic Techniques and Management of Flooding Tolerance in Soybean. Journal of Proteome Research 14(9):3768-3778. 64. Laan, P., M. J. Berrevoets, S. Lythe, W. Armstrong, and C. W. P. M. Blom. 1989. Root Morphology and Aerenchyma Formation as Indicators of the Flood-Tolerance of Rumex Species. Journal of Ecology 77(3):693-703. 65. Lamers, L. P. M., L. L. Govers, I. C. J. M. Janssen, J. J. M. Geurts, M. E. W. Van der Welle, M. M. Van Katwijk, T. Van der Heide, J. G. M. Roelofs, and A. J. P. Smolders. 2013. Sulfide as a soil phytotoxin—a review. Frontiers in Plant Science 4(268). 66. Li, Y., Q. Bai, X. Jin, H. Wen, and Z. Gu. 2009. Effects of cultivar and culture conditions on γ‐aminobutyric acid accumulation in germinated fava beans (Vicia faba L.). Journal of the Science of Food and Agriculture 90(1):52-57. 67. Liao, J., X. Wu, Z. Xing, Q. Li, Y. Duan, W. Fang, and X. Zhu. 2017. γ-Aminobutyric Acid (GABA) Accumulation in Tea (Camellia sinensis L.) through the GABA Shunt and Polyamine Degradation Pathways under Anoxia. Journal of Agricultural and Food Chemistry 65(14):3013-3018. 68. Ling, V., W. A. Snedden, B. J. Shelp, and S. M. Assmann. 1994. Analysis of a soluble calmodulin binding protein from fava bean roots: identification of glutamate decarboxylase as a calmodulin-activated enzyme. The Plant Cell 6(8):1135-1143. 69. Mei, X., Y. Chen, L. Zhang, X. Fu, Q. Wei, D. Grierson, Y. Zhou, Y. Huang, F. Dong, and Z. Yang. 2016. Dual mechanisms regulating glutamate decarboxylases and accumulation of gamma-aminobutyric acid in tea (Camellia sinensis) leaves exposed to multiple stresses. Scientific Reports 6:23685. 70. Meng, J., Y. Gong, P. Qian, J.-Y. Yu, X.-J. Zhang, and R.-R. Lu. 2016. Combined effects of ultra-high hydrostatic pressure and mild heat on the inactivation of Bacillus subtilis. LWT-Food Science and Technology 68:59-66. 71. Mittler, R. 2006. Abiotic stress, the field environment and stress combination. Trends in Plant Science 11(1):15-19. 72. Molina-Rueda, J. J., M. B. Pascual, F. M. Cánovas, and F. Gallardo. 2010. Characterization and developmental expression of a glutamate decarboxylase from maritime pine. Planta 232(6):1471-1483. 73. Molyneux, R. J., S. T. Lee, D. R. Gardner, K. E. Panter, and L. F. James. 2007. Phytochemicals: The good, the bad and the ugly? Phytochemistry 68(22):2973-2985. 74. Mommer, L. and E. J. W. Visser. 2005. Underwater Photosynthesis in Flooded Terrestrial Plants: A Matter of Leaf Plasticity. Annals of Botany 96(4):581-589. 75. Mustroph, A., G. A. B. JR, K. A. Kaiser, C. K. Larive, and J. Bailey-serres. 2014. Characterization of distinct root and shoot responses to low‐oxygen stress in Arabidopsis with a focus on primary C‐ and N‐metabolism. Plant, Cell and Environment 37(10):2366-2380. 76. Oey, I., M. Lille, A. Van Loey, and M. Hendrickx. 2008a. Effect of high-pressure processing on colour, texture and flavour of fruit-and vegetable-based food products: a review. Trends in Food Science and Technology 19(6):320-328. 77. Oey, I., I. Van der Plancken, A. Van Loey, and M. Hendrickx. 2008b. Does high pressure processing influence nutritional aspects of plant based food systems? Trends in Food Science and Technology 19(6):300-308. 78. Oh, S. 2003. Stimulation of gamma-aminobutyric acid synthesis activity in brown rice by a chitosan/glutamic acid germination solution and calcium/ calmodulin. Journal of biochemistry and molecular biology 36(3):319-325. 79. Okada, T., T. Sugishita, T. Murakami, H. Murai, T. Saikusa, T. Horino, A. Onoda, O. Kajimoto, R. Takahashi, and T. Takahashi. 2000. Effect of the Defatted Rice Germ Enriched with GABA for Sleeplessness, Depression, Autonomic Disorder by Oral Administration. Nippon Shokuhin Kagaku Kogaku Kaishi 47(8):596-603. 80. Porges, E. C., A. J. Woods, R. A. E. Edden, N. A. J. Puts, A. D. Harris, H. Chen, A. M. Garcia, T. R. Seider, D. G. Lamb, J. B. Williamson, and R. A. Cohen. 2017. Frontal Gamma-Aminobutyric Acid Concentrations Are Associated With Cognitive Performance in Older Adults. Biological Psychiatry: Cognitive Neuroscience and Neuroimaging 2(1):38-44. 81. Purwana, I., J. Zheng, X. Li, M. Deurloo, D. O. Son, Z. Zhang, C. Liang, E. Shen, A. Tadkase, Z.-P. Feng, Y. Li, C. Hasilo, S. Paraskevas, R. Bortell, D. L. Greiner, M. Atkinson, G. J. Prud’homme, and Q. Wang. 2014. GABA Promotes Human β-Cell Proliferation and Modulates Glucose Homeostasis. Diabetes 63(12):4197. 82. Pytka, K., A. Dziubina, K. Młyniec, A. Dziedziczak, E. Żmudzka, A. Furgała, A. Olczyk, J. Sapa, and B. Filipek. 2016. The role of glutamatergic, GABA-ergic, and cholinergic receptors in depression and antidepressant-like effect. Pharmacological Reports 68(2):443-450. 83. Qiu, F., Y. Zheng, Z. Zhang, and S. Xu. 2007. Mapping of QTL Associated with Waterlogging Tolerance during the Seedling Stage in Maize. Annals of Botany 99(6):1067-1081. 84. R., F. and S. S. 1995. Salt tolerance of maize (Zea mays L.): the role of sodium exclusion. Plant, Cell and Environment 18(9):1041-1047. 85. Ramesh, S. A., S. D. Tyerman, M. Gilliham, and B. Xu. 2017. γ-Aminobutyric acid (GABA) signalling in plants. Cellular and Molecular Life Sciences 74(9):1577-1603. 86. Renault, H., A. El Amrani, A. Berger, G. Mouille, L. Soubigou‐Taconnat, A. Bouchereau, and C. Deleu. 2012. γ‐Aminobutyric acid transaminase deficiency impairs central carbon metabolism and leads to cell wall defects during salt stress in Arabidopsis roots. Plant, Cell and Environment 36(5):1009-1018. 87. Renault, H., V. Roussel, A. El Amrani, M. Arzel, D. Renault, A. Bouchereau, and C. Deleu. 2010. The Arabidopsis pop2-1 mutant reveals the involvement of GABA transaminase in salt stress tolerance. BMC Plant Biology 10:20-20. 88. Rendueles, E., M. K. Omer, O. Alvseike, C. Alonso-Calleja, R. Capita, and M. Prieto. 2011. Microbiological food safety assessment of high hydrostatic pressure processing: A review. LWT - Food Science and Technology 44(5):1251-1260. 89. Roberts, E. and S. Frankel. 1950. gamma-Aminobutyric acid in brain: its formation from glutamic acid. Journal of Biological Chemistry 187(1):55-63. 90. Roberts, M. R. 2007. Does GABA Act as a Signal in Plants? Hints from Molecular Studies. Plant Signaling and Behavior 2(5):408-409. 91. Rodrigo, D., F. Sampedro, A. Silva, A. Palop, and A. Martínez. 2010. New food processing technologies as a paradigm of safety and quality. British Food Journal 112(5):467-475. 92. Rozan, P., Y. Kuo, and F. Lambein. 2000. Free Amino Acids Present in Commercially Available Seedlings Sold for Human Consumption. A Potential Hazard for Consumers. Journal of Agricultural and Food Chemistry 48(3):716-723. 93. Rubinigg, M., I. Stulen, J. T. M. Elzenga, and T. D. Colmer. 2002. Spatial patterns of radial oxygen loss and nitrate net flux along adventitious roots of rice raised in aerated or stagnant solution. Functional Plant Biology 29(12):1475-1481. 94. Salminen, A., P. Jouhten, T. Sarajärvi, A. Haapasalo, and M. Hiltunen. 2016. Hypoxia and GABA shunt activation in the pathogenesis of Alzheimer's disease. Neurochemistry International 92:13-24. 95. Salvatierra, A., P. Pimentel, R. Almada, and P. Hinrichsen. 2016. Exogenous GABA application transiently improves the tolerance to root hypoxia on a sensitive genotype of Prunus rootstock. Environmental and Experimental Botany 125:52-66. 96. Sarkar, R. K. and D. Panda. 2009. Distinction and characterisation of submergence tolerant and sensitive rice cultivars, probed by the fluorescence OJIP rise kinetics. Functional Plant Biology 36(3):222-233. 97. Sasidharan, R., A. Mustroph, A. Boonman, M. Akman, A. M. H. Ammerlaan, T. Breit, M. E. Schranz, L. A. C. J. Voesenek, and P. H. van Tienderen. 2013. Root Transcript Profiling of Two Rorippa Species Reveals Gene Clusters Associated with Extreme Submergence Tolerance. Plant Physiology 163(3):1277. 98. Sasidharan, R. and L. A. C. J. Voesenek. 2015. Ethylene-Mediated Acclimations to Flooding Stress. Plant Physiology 169(1):3. 99. Sauter, M. 2013. Root responses to flooding. Current Opinion in Plant Biology 16(3):282-286. 100. Septiningsih, E. M., A. M. Pamplona, D. L. Sanchez, C. N. Neeraja, G. V. Vergara, S. Heuer, A. M. Ismail, and D. J. Mackill. 2009. Development of submergence-tolerant rice cultivars: the Sub1 locus and beyond. Annals of Botany 103(2):151-160. 101. Serment-Moreno, V., D. A. Jacobo-Velázquez, J. A. Torres, and J. Welti-Chanes. 2017. Microstructural and Physiological Changes in Plant Cell Induced by Pressure: Their Role on the Availability and Pressure-Temperature Stability of Phytochemicals. Food Engineering Reviews 9(4):314-334. 102. Shelp, B. J., A. W. Bown, and M. D. McLean. 1999. Metabolism and functions of gamma-aminobutyric acid. Trends in Plant Science 4(11):446-452. 103. Shelp, B. J., G. G. Bozzo, C. P. Trobacher, G. Chiu, and V. S. Bajwa. 2012. Strategies and tools for studying the metabolism and function of γ-aminobutyrate in plants. I. Pathway structure. Botany 90(8):651-668. 104. Shetty, A. K. and D. Upadhya. 2016. GABA-ergic cell therapy for epilepsy: Advances, limitations and challenges. Neuroscience and Biobehavioral Reviews 62:35-47. 105. Shiono, K., S. Ogawa, S. Yamazaki, H. Isoda, T. Fujimura, M. Nakazono, and T. D. Colmer. 2011. Contrasting dynamics of radial O2-loss barrier induction and aerenchyma formation in rice roots of two lengths. Annals of Botany 107(1):89-99. 106. Silva, F. V. 2016. High pressure processing pretreatment enhanced the thermosonication inactivation of Alicyclobacillus acidoterrestris spores in orange juice. Food Control 62:365-372. 107. Snedden, W. A., T. Arazi, H. Fromm, and B. J. Shelp. 1995. Calcium/Calmodulin Activation of Soybean Glutamate Decarboxylase. Plant Physiology 108(2):543-549. 108. Soleimani Aghdam, M., R. Naderi, P. Malekzadeh, and A. Jannatizadeh. 2016. Contribution of GABA shunt to chilling tolerance in anthurium cut flowers in response to postharvest salicylic acid treatment. Scientia Horticulturae 205:90-96. 109. Soltani, N., H. Qiu, M. Aleksic, Y. Glinka, F. Zhao, R. Liu, Y. Li, N. Zhang, R. Chakrabarti, T. Ng, T. Jin, H. Zhang, W.-Y. Lu, Z.-P. Feng, G. J. Prud'homme, and Q. Wang. 2011. GABA exerts protective and regenerative effects on islet beta cells and reverses diabetes. Proceedings of the National Academy of Sciences of the United States of America 108(28):11692-11697. 110. Steward, F. C. 1949. γ-Aminobutyric acid : a constituent of potato tubers? Science 110:439-440. 111. Tahiri, I., J. Makhlouf, P. Paquin, and I. Fliss. 2006. Inactivation of food spoilage bacteria and Escherichia coli O157: H7 in phosphate buffer and orange juice using dynamic high pressure. Food Research International 39(1):98-105. 112. Takahashi, Y., T. Sasanuma, and T. Abe. 2013. Accumulation of gamma-aminobutyrate (GABA) caused by heat-drying and expression of related genes in immature vegetable soybean (edamame). Breeding Science 63(2):205-210. 113. Torres, J. A. and G. Velazquez. 2005. Commercial opportunities and research challenges in the high pressure processing of foods. Journal of Food Engineering 67(1–2):95-112. 114. Udenfriend, S. 1950. Identification of gamma-aminobutyric acid in brain by the isotope derivative method. Journal of Biological Chemistry 187(1):65-69. 115. Valliyodan, B., T. Van Toai, J. Alves, P. de Fátima P. Goulart, J. Lee, F. Fritschi, M. Rahman, R. Islam, J. Shannon, and H. Nguyen. 2014. Expression of Root-Related Transcription Factors Associated with Flooding Tolerance of Soybean (Glycine max). International Journal of Molecular Sciences 15(10):17622. 116. Valliyodan, B., H. Ye, L. Song, M. Murphy, J. G. Shannon, and H. T. Nguyen. 2017. Genetic diversity and genomic strategies for improving drought and waterlogging tolerance in soybeans. Journal of Experimental Botany 68(8):1835-1849. 117. Van Der Straeten, D., Z. Zhou, E. Prinsen, H. A. Van Onckelen, and M. C. Van Montagu. 2001. A Comparative Molecular-Physiological Study of Submergence Response in Lowland and Deepwater Rice. Plant Physiology 125(2):955. 118. van Veen, H., A. Mustroph, G. A. Barding, M. Vergeer-van Eijk, R. A. M. Welschen-Evertman, O. Pedersen, E. J. W. Visser, C. K. Larive, R. Pierik, J. Bailey-Serres, L. A. C. J. Voesenek, and R. Sasidharan. 2013. Two Rumex Species from Contrasting Hydrological Niches Regulate Flooding Tolerance through Distinct Mechanisms. The Plant Cell 25(11):4691-4707. 119. Vashisht, D., A. Hesselink, R. Pierik, J. M. H. Ammerlaan, J. Bailey‐Serres, E. J. W. Visser, O. Pedersen, M. van Zanten, D. Vreugdenhil, D. C. L. Jamar, L. A. C. J. Voesenek, and R. Sasidharan. 2010. Natural variation of submergence tolerance among Arabidopsis thaliana accessions. New Phytologist 190(2):299-310. 120. Vervuren, P. J. A., C. W. P. M. Blom, and H. De Kroon. 2003. Extreme flooding events on the Rhine and the survival and distribution of riparian plant species. Journal of Ecology 91(1):135-146. 121. Visser, E. J. W., T. D. Colmer, C. W. P. M. Blom, and L. A. C. J. Voesenek. 2008. Changes in growth, porosity, and radial oxygen loss from adventitious roots of selected mono‐ and dicotyledonous wetland species with contrasting types of aerenchyma. Plant, Cell and Environment 23(11):1237-1245. 122. Voesenek Laurentius, A. C. J. and J. Bailey‐Serres. 2015. Flood adaptive traits and processes: an overview. New Phytologist 206(1):57-73. 123. Wang, C., L. Fan, H. Gao, X. Wu, J. Li, G. Lv, and B. Gong. 2014. Polyamine biosynthesis and degradation are modulated by exogenous gamma-aminobutyric acid in root-zone hypoxia-stressed melon roots. Plant Physiology and Biochemistry 82:17-26. 124. Wang, Y., W. Gu, Y. Meng, T. Xie, L. Li, J. Li, and S. Wei. 2017. γ-Aminobutyric Acid Imparts Partial Protection from Salt Stress Injury to Maize Seedlings by Improving Photosynthesis and Upregulating Osmoprotectants and Antioxidants. Scientific Reports 7:43609. 125. Wang, Y., Z. Luo, L. Mao, and T. Ying. 2016. Contribution of polyamines metabolism and GABA shunt to chilling tolerance induced by nitric oxide in cold-stored banana fruit. Food Chemistry 197, Part A:333-339. 126. Xing, S. G., Y. B. Jun, Z. W. Hau, and L. Y. Liang. 2007. Higher accumulation of γ-aminobutyric acid induced by salt stress through stimulating the activity of diamine oxidases in Glycine max (L.) Merr. roots. Plant Physiology and Biochemistry 45(8):560-566. 127. Xu, K. and D. J. Mackill. 1996. A major locus for submergence tolerance mapped on rice chromosome 9. Molecular Breeding 2(3):219-224. 128. Xu, K., X. Xu, T. Fukao, P. Canlas, R. Maghirang-Rodriguez, S. Heuer, A. M. Ismail, J. Bailey-Serres, P. C. Ronald, and D. J. Mackill. 2006. Sub1A is an ethylene-response-factor-like gene that confers submergence tolerance to rice. Nature 442:705. 129. Yang, R., Q. Guo, and Z. Gu. 2013a. GABA shunt and polyamine degradation pathway on γ-aminobutyric acid accumulation in germinating fava bean (Vicia faba L.) under hypoxia. Food Chemistry 136(1):152-159. 130. Yang, R., Q. Hui, and Z. Gu. 2016. Effects of ABA and CaCl2 on GABA accumulation in fava bean germinating under hypoxia-NaCl stress. Bioscience, Biotechnology, and Biochemistry 80(3):540-546. 131. Yang, R., Y. Yin, Q. Guo, and Z. Gu. 2013b. Purification, properties and cDNA cloning of glutamate decarboxylase in germinated faba bean (Vicia faba L.). Food Chemistry 138(2):1945-1951. 132. Yang, Y., H. Luo, L.-X. Cheng, and K. Liu. 2013c. Inhibitory role for GABA in atherosclerosis. Medical Hypotheses 81(5):803-804. 133. Yin, Y., R. Yang, Q. Guo, and Z. Gu. 2014. NaCl stress and supplemental CaCl2 regulating GABA metabolism pathways in germinating soybean. European Food Research and Technology 238(5):781-788. 134. Youn, Y., J. Park, H. Jang, and Y. Rhee. 2011. Sequential hydration with anaerobic and heat treatment increases GABA (γ-aminobutyric acid) content in wheat. Food Chemistry 129(4):1631-1635. 135. Yu, J., R. Li, N. Fan, Z. Yang, and B. Huang. 2017. Metabolic Pathways Involved in Carbon Dioxide Enhanced Heat Tolerance in Bermudagrass. Frontiers in Plant Science 8:1506. 136. Yu, M. and G.-Y. Chen. 2013. Conditional QTL mapping for waterlogging tolerance in two RILs populations of wheat. SpringerPlus 2(1):245. 137. Zaidi, P. H., Z. Rashid, M. T. Vinayan, G. D. Almeida, R. K. Phagna, and R. Babu. 2015. QTL Mapping of Agronomic Waterlogging Tolerance Using Recombinant Inbred Lines Derived from Tropical Maize (Zea mays L) Germplasm. PLoS ONE 10(4):e0124350. 138. Zeng, F., L. Shabala, M. Zhou, G. Zhang, and S. Shabala. 2013. Barley responses to combined waterlogging and salinity stress: separating effects of oxygen deprivation and elemental toxicity. Frontiers in Plant Science 4(313). 139. Zhang, W., X. Liu, F. Zheng, S. Zeng, K. Wu, J. A. Teixeira da Silva, and J. Duan. 2013. Induction of rice mutations by high hydrostatic pressure. Plant Physiology and Biochemistry 70:182-187. 140. Zhang, Y. J., J. P. Lynch, and K. M. Brown. 2003. Ethylene and phosphorus availability have interacting yet distinct effects on root hair development. Journal of Experimental Botany 54(391):2351-2361.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/70939	-
dc.description.abstract	γ-胺基丁酸 (γ-aminobutyric acid, GABA) 是一種非蛋白質胺基酸，普遍存在於生物體。在動物中，GABA是重要的抑制性神經傳導物質，具有降血壓、緩解憂鬱、調節腎功能等功效，因此備受關注，如何增加食物中的GABA含量成了熱門議題。毛豆是臺灣重要的外銷綠金產業，2017年外銷產量約3.8萬公噸，總金額超過新臺幣25億，含有豐富的營養價值，也是常見豆類中GABA含量較高者。本研究欲探討採收前1~4天之淹水逆境和200、300 MPa的高壓處理對毛豆‘高雄9號’中GABA含量之富化效果及其機轉。以兩階段震盪萃取法萃取GABA有94.05%回收率，且在異日操作間無顯著差異，而管柱前異硫氰酸苯酯 (phenylisothiocyanate, PITC) 衍生化之平均回收率為94.33%，精密度試驗RSD值分別為4.13%、1.80%和2.12%，標準曲線R²值為0.9999，顯示本試驗GABA檢測方式之良好回收率、精密度和穩定性。毛豆‘高雄9號’在不同生長階段中各部位的GABA含量約有50~450 mg/100 g，顯示毛豆的GABA含量確實較一般植物高，其中以毛豆仁的GABA含量最多，根和莖較少。淹水處理可以在不影響顏色、大小、合格莢率、豆仁飽滿度、豆仁硬度及消費者接受度的前提下，使毛豆仁GABA含量顯著增加，淹水1天可達到456.9± 43.4 mg/100g，約提升了90%；而淹水3天後於4℃儲藏3天可以增加153%，GABA含量達576.1± 53.8 mg/100g。高壓的部分，在200、300 MPa高壓處理下可以顯著提升毛豆‘高雄9號’的GABA含量，尤其是200 MPa效果更顯著，可使完整毛豆、毛豆莢、毛豆仁之GABA含量分別提升127%、208%和100%，毛豆仁含量最高，可達到 454.2± 42.4 mg/100g。結合淹水逆境、高壓處理及儲藏處理可得到本研究之最佳GABA富化條件，為毛豆仁淹水逆境3天輔以200 MPa高壓處理後儲藏3天，其富化含量可達696.6 ± 65.7 mg/100 g。機制部分是透過GABA相關酵素之mRNA電泳膠片分析和麩胺酸脫羧酶 (glutamate decarboxylase, GAD) 活性檢測，分別從基因調控和蛋白質活性兩層面去做探討。毛豆仁之GAD5、胺基醛脫氫酶 (aminoaldehyde dehydrogenase, AMADH)、GABA轉胺酶 (GABA transaminase, GABA-T)、琥珀酸半醛脫氫酶 (succinic semialdehyde dehydrogenase, SSADH) 酵素之mRNA表現量較其餘酵素高，而淹水1天會使毛豆仁GAD5、AMADH、GABA-T mRNA表現量提高，並使GAD3和SSADH表現量下降，顯示淹水1天可能透過改變GAD5、AMADH和SSADH基因表現量來使GABA含量提高。高壓處理後的GAD酵素活性顯著高於未高壓組，且300 MPa高壓處理提升之幅度顯著優於200 MPa。最佳的GAD酵素活性為300 MPa高壓處理後的完整毛豆，達84.62±0.75 U/mg protein，比對照組和200 MPa高壓處理組分別提升了和207.3% 和145.6%；而毛豆仁的部分，其300 MPa高壓處理組的GAD酵素活性為32.48±0.90 U/mg protein，比200 MPa高壓處理組多了32.9%，顯示高壓處理可透過增加GAD酵素活性來使GABA含量增加。總結而言，毛豆‘高雄9號’經過淹水逆境和高壓處理可以提高其內GABA含量，增加其機能性價值。	zh_TW
dc.description.provenance	Made available in DSpace on 2021-06-17T04:44:52Z (GMT). No. of bitstreams: 1 ntu-107-R05628204-1.pdf: 3818839 bytes, checksum: 834433ec066021bb952742cf22c88cd3 (MD5) Previous issue date: 2018	en
dc.description.tableofcontents	目錄謝誌 I 中文摘要 II Abstract IV 目錄 VII 圖目錄 X 表目錄 XII 第一章、前言 1 第二章、文獻回顧 2 第一節、毛豆 2 1. 介紹 2 2. 營養成分 4 3. 產量及外銷現況 8 第二節、γ-胺基丁酸 GABA 11 1. 簡介 11 2. 生理代謝角色與功能 12 3. 生化代謝合成 15 4. 農業現況應用 19 第三節、淹水逆境 25 1. 對植物的影響 25 2. 提高植物耐受性的做法 30 第四節、高壓處理技術 31 1. 介紹與原理 31 2. 對生物分子的作用機制與影響 32 3. 應用 34 第五節、研究動機與目的 36 第六節、試驗架構 37 第三章、材料與方法 38 第一節、試驗材料 38 第二節、試驗藥品 38 第三節、儀器與設備 39 第四節、高壓處理及儲藏方法 41 第五節、HPLC分析GABA方法 42 1. GABA檢測方法確立 42 2. GABA萃取方法建立 43 3. 樣品衍生化方法 44 4. 高效能液相層析分析 45 第六節、毛豆品質調查 46 第七節、毛豆品評調查 48 1. 品評法 48 2. 評量方式 48 3. 品評員篩選 48 4. 品評方法 48 第八節、GABA相關酵素之mRNA分析 49 1. 抽取total RNA 49 2. 反轉錄cDNA 49 3. 聚合酶連鎖反應與瓊脂膠體電泳分析 49 第九節、GAD酵素分析 52 1. 製備enzyme extracts 52 2. 定量enzyme extracts總可溶性蛋白質 52 3. 檢測GAD酵素活性 52 第十節、統計分析 53 第四章、結果與討論 54 第一節、 GABA檢測方法確立 54 1. GABA的定性 54 2. GABA的定量 54 第二節、 GABA萃取方法確立 58 1. 萃取法試驗 58 2. 萃取回收率試驗 58 3. 萃取精密度試驗 58 第三節、樣品衍生化方法確立 61 1. 衍生化回收率試驗 61 2. 衍生化精密度試驗 61 第四節、不同生長階段毛豆‘高雄9號’各部位之GABA含量 63 第五節、淹水逆境及儲藏對於毛豆‘高雄9號’各部位之GABA含量之影響. 65 第六節、淹水逆境對於毛豆‘高雄9號’品質之影響 68 第七節、淹水處理輔以高壓處理及儲藏對毛豆‘高雄9號’GABA含量之影響 80 第八節、淹水逆境下‘高雄9號’毛豆仁GABA相關酵素mRNA之表現量 86 第九節、高壓處理對於毛豆‘高雄9號’GAD酵素活性之影響 91 第五章、結論 93 參考資料 95
dc.language.iso	zh-TW
dc.subject	麩胺酸脫羧?	zh_TW
dc.subject	神經傳導物質	zh_TW
dc.subject	儲藏處理	zh_TW
dc.subject	琥珀酸半醛脫氫?	zh_TW
dc.subject	憂鬱	zh_TW
dc.subject	succinic semialdehyde dehydrogenase	en
dc.subject	glutamate decarboxylase	en
dc.subject	neurotransmitter	en
dc.subject	storage treatment	en
dc.subject	depression	en
dc.title	淹水逆境輔以高壓處理對提升毛豆γ-胺基丁酸含量之研究	zh_TW
dc.title	Study of flooding stress and high-pressure treatment on the increase of GABA content of vegetable soybean (Glycine max Merr.)	en
dc.type	Thesis
dc.date.schoolyear	106-2
dc.description.degree	碩士
dc.contributor.coadvisor	吳思節(Sz-Jie Wu)
dc.contributor.oralexamcommittee	羅筱鳳(Siao-Fong Lo),劉育姍(Yu-Shan Liu)
dc.subject.keyword	麩胺酸脫羧?,神經傳導物質,儲藏處理,琥珀酸半醛脫氫?,憂鬱,	zh_TW
dc.subject.keyword	glutamate decarboxylase,neurotransmitter,storage treatment,succinic semialdehyde dehydrogenase,depression,	en
dc.relation.page	110
dc.identifier.doi	10.6342/NTU201802418
dc.rights.note	有償授權
dc.date.accepted	2018-08-02
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	園藝暨景觀學系	zh_TW
顯示於系所單位：	園藝暨景觀學系

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