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NTIS 바로가기한국환경농학회지 = Korean journal of environmental agriculture, v.37 no.3, 2018년, pp.197 - 206
조지영 (충남대학교 농업생명과학대학 생물환경화학과) , 성호영 (충남대학교 농업생명과학대학 생물환경화학과) , 천진혁 (충남대학교 농업생명과학대학 생물환경화학과) , 박종석 (충남대학교 농업생명과학대학 원예학과) , 박상언 (충남대학교 농업생명과학대학 식물자원학과) , 박영준 (한국농어촌공사 농어촌연구원) , 김선주 (충남대학교 농업생명과학대학 생물환경화학과)
BACKGROUND: The present study aimed to examine the crops capable of growing and adapting to the external environment and various stresses of reclaimed agriculture land for the development of high value-added agricultural utilization technology based on reclaimed land through standardization and empi...
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핵심어 | 질문 | 논문에서 추출한 답변 |
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토양이 염 스트레스를 받으면 어떤 현상이 나타나는 가? | 염 스트레스는 이온의 독성, 수분포텐셜의 저하, 이온의 흡수 및 수송의 억제에 의한 영양불균형을 일으킨다(Munns and Termaat, 1986). 토양에 염류가 심하게 집적되면 특정 이온에 의한 독성 또는 토양의 수분포텐셜 감소에 따른 수분흡수장애가 나 타나 물질 생산이 크게 저하된다(Lutts et al., 1995; Volkmar et al. | |
간척지는 무엇인가? | 우리나라는 국토 면적에 비해 상대적으로 경작지가 부족 하기에 이를 해결하기 위하여 간척지를 조성해왔다(Go, 2014). 간척지는 강이나 바다, 호수였던 둑을 쌓고 물을 빼내는 과정을 통해, 새롭게 탄생한 땅을 의미한다. 간척지는 지하수위가 지면 부위에 있고, 지표면의 수분이 증발됨에 따라 염이 모세관 현상으로 상승하게 되어 토양의 염 농도가 높아져 작물 재배에 어려움이 많다(Kim et al. | |
염 스트레스는 무엇을 일으키는 가? | 토양 중에 Na+ 과 Cl가 많이 존재하면 식물은 염 스트레스를 받는다. 염 스트레스는 이온의 독성, 수분포텐셜의 저하, 이온의 흡수 및 수송의 억제에 의한 영양불균형을 일으킨다(Munns and Termaat, 1986). 토양에 염류가 심하게 집적되면 특정 이온에 의한 독성 또는 토양의 수분포텐셜 감소에 따른 수분흡수장애가 나 타나 물질 생산이 크게 저하된다(Lutts et al. |
Ahn, Y., Lee, S. H., Ji, K. J., Hong, B. D., Noh, H. M., Ryu, S. H., Lee, S. M., Yoon, S. I., Choi, Y. D., & Noh, Y. D. (2003). Studies on changes of soil characteristics and utilization after tidal land reclamation. Korea Agricultural and Rural Infrastructure Corporation Rural Research Institute, 1-332.
Alonso-Blanco, C., Aars, M. G., Bentsink, L., Keurentjes, J. J. B., Reymond, M., Vreugdenhil, D., & Koornneef, M. (2009). What has natural variation taught us about plant development, physiology, and adaptation?. Plant Cell, 21(7), 1877-1896.
Bothe, H. (1976). Salzresistenz bei pflanzen. Biologie in unserer Zeit, 6(1), 3-10.
Brown, A. F., Yousef, G. G., Jeffery, E. H., Wallig, M. A., Kushad, M. M., & Juvik, J. A. (2002). Glucosinolate profiles in broccoli: Variation in levels and implications in breeding for caner chemoprotection. Journal of the American Society for Horticultural Science, 127(5), 807-813.
Cartea, M. E., Velasco, P., Obregon, S., Padilla, G., & de-Haro A. (2008). Seasonal variation in glucosinolate content in Brassica oleracea crops grown in northwestern Spain. Phytochemistry, 69(2), 403-410.
Choi, S. C., Kim, J. G., & Choo, Y. S. (2013). Effects of salt stress on inorganic ions and glycine betaine contents in leaves of Beta vulgaris var. cicla L. Korean Journal of Ecology and Environment, 46(3), 388-394.
Chun, J. H., Kim, N. H., Seo, M. S., Jin, M., Park, S. U., Arasu, M. V., Kim, S. J., & Al-Dhabi, N. A. (2016). Molecular characterization of glucosinolates and carotenoid biosynthetic genes in Chinese cabbage (Brassica rapa L. ssp. pekinensis). Saudi Journal of Biological Sciences, 25, 71-82. 25, 71-82.
Clarke, D. B. (2010). Glucosinolates, structures and analysis in food. Analytical Methods, 2(4), 310-325.
Davies, K. J. (1995). Oxidative stress: the paradox of aerobic life. Biochemical Society Symposium, 61(1), 1-31.
Dixon, R. A., & Paiva, N. L. (1995). Stress-induced phenylpropanoid metabolism. The Plant Cell, 7(7), 1085-1097.
Elliott, D. C. (1979). Ionic regulation for cytokinindependent betacyanin synthesis in Amaranthus seedlings. Plant Physiology, 63(2), 264-268.
Fahey, J. W., Zalcmann, A. T., & Talalay, P. (2001). The chemical diversity and distribution of glucosinolates and isothiocyanates among plants. Phytochemistry, 56, 5-51.
Florian, C. S., & Reinhold, C. (2004). Functional properties of anthocyanins and betalains in plants, food, and in human nutrition. Food Science & Technology, 15(1), 19-38.
Gabrela, S. J., Patricia, R. B., Helena, P., & Mario, R. S. (2004). Betacyanin synthesis in red beet (Beta vulgaris) leaves induced by wounding and bacterial infiltration is preceded by an oxidative burst. Physiological and Molecular Plant Pathology, 64(3), 125-133.
Go, E. B., Kim, K. M., Lee, K. J., & Chae, J. C. (2014). Rhizomicrobes isolated from reclaimed land enhance growth and salt tolerance in plant. The Plant Resources Society of Korea, 4, 191-191.
Guo, R. F., Yuan, G. F., & Wang, Q. M. (2013). Effect of NaCl treatments on glucosinolate metabolism in broccoli sprouts. Journal of Zhejiang University: Science B, 14(2), 124-131.
Halkier, B. A., & Gershenzon, J. (2006). Biology and biochemistry of glucosinolates. Annual Review of Plant Biology, 57, 303-333.
Hasegawa, P. M., Bressa, R. A., Zhu, J. K., & Bohnert, H. J. (2000). Plant cellular and molecular responses to high salinity. Annual Review of Plant Physiology & Plant molecular Biology, 51, 463-499.
Hayakawa, K., & Agarie, S. (2010). Physiological roles of betacyanin in a halophyte, Suaeda japonica Makino. Plant Production Science, 13(4), 351-359.
Hong, S. H., Kim, J. S., Park, J. W., & Lee, E. Y. (2015). A study on the effect of the Rhizobacterium, Bacillus sp. SH1RP8 and potassium family polymers on the crop growth under saline. Korean Society for Biotechnology and Bioengineering Journal, 30(3), 97-102.
Jain, G., & Gould, K. S. (2015). Are betalain pigments the functional homologues of anthocyanins in plants?. Environmental and Experimental Botany, 119, 48-53.
Jain, G., & Gould, K. S. (2015). Functional significance of betalain biosynthesis in leaves of Disphyma australe under salinity stress. Environmental and Expeirmental Botany, 109, 131-140.
Jain, G., Schwinn, K. E., & Gould, K. S. (2015). Betalain induction by l-DOPA application confers photoprotection to saline-exposed leaves of Disphyma australe. New Phytologist, 207(4), 1075 -1083.
Jeong, R. H., Wu, Q., Cho, J. G., Lee, D. Y., Shrestha, S., Lee, M. H., Lee, K. T., Choi, M. S., Jeong, T. S., Ahn, E. M., Chung, H. G., Rho, Y. D., & Baek, N. I. (2013). Isolation and identification of flavonoids from the roots of Brassica rapa ssp. Journal of Applied Biological Chemistry, 56(1), 23-27.
Kim, C. R., Lim, Y. S., Lee, S. W., & Kim, S. J. (2011). Identification and quantification of glucosinolates in rocket salad (Eruca sativa). Korean Journal of Agricultural Science, 38(2), 285-294.
Kim, D. W., Yun, S. K., Park, H. H., Hwang, J. J., Han, O. K., Park, T. I., Jung, G. H., Lee, J. E., Kim, S. L., & Chung, Y. H. (2011). Physiological and proteomic responses of barley seedlings to salt stress. The Korean Society of international Agriculture, 23(5), 537-545.
Kim, S. J., & Ishii, G. (2006). Glucosinolate profiles in the seeds, leaves and roots of rocket salad (Eruca sativa Mill.) and anti-oxidative activities of intact plant powder and purified 4-methoxyglucobrassicin. Soil Science and Plant Nutrition, 52(3), 394-400.
Kim, Y. J., Chun, J. H., & Kim, S. J. (2015). Influence of the lime on inorganic ion and glucosinolate contents in Chinese cabbage. Korean Journal of Agricultural Science, 42(4), 405-421.
Lee, G. R., Kim, Y. J., Chun, J. H., Lee, M. K., Ryu, D. K., Park, S. H..Y., Chung, S. O., Park, S. U., Lim, Y. P., & Kim, S. J. (2014). Variation of glucosinolate contents of 'Sinhongssam' grown under various light sources, periods, and light intensities. Korean Journal of Agricultural Science, 41(2), 125-133.
Lee, J. Y., Jang, B. C., Lee, S. Y., Park, J. H., Choi, G. H., Kim, S. C., & Kim, T. W. (2008). Growth response and changes of nitrate and sucrose content in tomato under salt stress condition. Korean Society of Soil Sciences and Fertilizer, 41(3), 164-169.
Lee, S. D. (2006). The study of the status quo into the production, utilization and efficacy of turnip. Journal of Health Science & Medical Technology, 32(1), 47-60.
Lutts, S., Kinet, J. M., & Bouharmont, J. (1995). Changes in plant response to NaCl during development of rice (Oryza sativa L.) varieties differing in salinity resistance. Journal of Experimental Botany, 46(293), 1843-1852.
Munns, R., & Termaat, A. (1986). Whole-plant responses to salinity. Australian Journal of Physiology, 3, 143-160.
Nakashima, T., Araki, T., & Ueno, O. (2011). Photoprotective function of betacyanin in leaves of Amaranthus cruentus L. under water stress. Photosynthetica, 49(4), 497-506.
Parida, A. K., & Das, A. B. (2005). Salt tolerance and salinity effects on plants: a review. Ecotoxicology and Environmental Safety, 60(3), 324-349.
Ribeiro, M. V., Deuner, S., Benitez, L. C., Einhardt, A. M., Peters, J. A., & Braga, E. J. B. (2014). Betacyanin and antioxidant system in tolerance to salt stress in Alternanthera philoxeroides. Agrociencia, 48(2), 199-210.
Rodrguez, M., Canales, E., & Borras-Hidalzo, O. (2005). Molecular aspects of abiotic stress in plants. Biotecnologia Aplicada, 22, 1-10.
Slawomir, W. (2005). Formation of decarboxylated betacyanins in heated purified betacyanin fractions from red beet root (Beta vulgaris L.) monitored by LC-MS/MS. Journal of Agricultural and Food Chemistry, 53(9), 3483-3487.
Sobhanian, H., Aghaei, K., & Komatsu, S. (2011). Changes in the plant proteome resulting from salt stress: Toward the creation of salt-tolerant crops?. Journal of Proteomics, 74(8), 1323-1337.
Talalay, P., & Zhang, Y. (1996). Chemoprotection against cancer by isothiocyanates and glucosinolates. Biochemical Society Transactions, 24(3), 806-810.
van Etten, C. H., Daxenbichler, M. E., & Wolff, I. A. (1969). Natural glucosinolates (thioglucosides) in foods and feeds. Journal of Agricultural and Food Chemistry, 17(3), 483-491.
Volkmar, K. M., Hu, Y., & Steppuhn, H. (1998). Physiological responses of plants to salinity: A review. Canadian Journal of Plant Science, 78, 19-27.
Wang, C. Q., Xu, C., Wei, J. G., Wang, H. B., & Wang, S. H. (2008). Enhanced tonoplast H+-ATPase activity and superoxide dismutase activity in the halophyte Suaeda salsa containing high level of betacyanin. Journal of Plant Growth Regulation, 27(1), 58-67.
Zhang, Y., & Talalay, P. (1994). Anticarcinogenic activities of organic isothiocyanates: chemistry and mechanisms. Cancer Research, 54(7), 1976-1981.
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