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Silicon Supply through Subirrigation System Alleviates High Temperature Stress in Poinsettia by Enhancing Photosynthetic Rate
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 Title & Authors
Silicon Supply through Subirrigation System Alleviates High Temperature Stress in Poinsettia by Enhancing Photosynthetic Rate
Son, Moon Sook; Park, Yoo Gyeong; Sivanesan, Iyyakkannu; Ko, Chung Ho; Jeong, Byoung Ryong;
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The effect of Si supplied during plant cultivation on tolerance to high temperature stress in Euphorbia pulcherrima Willd. 'Ichiban' was investigated. Rooted cuttings were transplanted into 10-cm pots and a complete nutrient solution, containing 0 or Si as either , , or , was supplied through subirrigation or weekly foliar applications. After two months of cultivation, plants were placed in an environment-controlled chamber and subjected to (high temperature) conditions for 18 days. Enhanced specific activities of enzymatic antioxidants (APX) and suppressed specific activities of non-enzymatic antioxidants (ELP) were observed in the high temperature-stressed plants with Si application. The Fv/Fm (maximum quantum yield of photosystem II), photosynthetic rate, and Si contents in the shoot increased in the treatments of and supplied through subirrigation. The Si-treated plants had more tolerance of high temperature stress than the control plants. Of the Si sources and application methods tested, and supplied through subirrigation were found to be the most effective in enhancing tolerance to high temperature stress.
calcium silicate;foliar application;heat stress;potassium silicate;sodium silicate;subirrigational supply;
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규산 함유 액상비료 시비에 따른 크리핑 벤트그래스의 생육과 품질 변화,김영선;이창은;이긍주;

Weed & Turfgrass Science, 2016. vol.5. 3, pp.170-176 crossref(new window)
Aebi, H. 1984. Catalase in vitro. Method. Enzymol. 105:121-126. crossref(new window)

Agarie, S., N. Hanaoka, O. Ueno, A. Miyazaki, F. Kubota, W. Agata, and P.B. Kaufman. 1998. Effects of silicon on tolerance to water deficit and heat stress in rice plants (Oryza sativa L.), monitored by electrolyte leakage. Plant Prod. Sci. 1:96-103. crossref(new window)

Bannister, J.V., W.H. Bannister, and G. Rotilio. 1987. Aspects of the structure, function, and applications of superoxide dismutase. Crit. Rev. Biochem. Mol. Biol. 22:111-180. crossref(new window)

Beauchamp, C. and I. Fridovich. 1971. Superoxide dismutase: Improved assay applicable to acrylamide gels. Anal. Biochem. 44:276-287. crossref(new window)

Bowler, C., M. van Montagu, and D. Inze. 1992. Superoxide dismutase and stress tolerance. Annu. Rev. Plant Biol. 43:83-116. crossref(new window)

Chen, G.X. and K. Asada. 1989. Ascorbate peroxidase in tea leaves: Occurrence of two isozymes and the differences in their enzymatic and molecular properties. Plant Cell Physiol. 30:987-998.

Choi, Y.H., J.S. Kang, J.K. Kwon, J.H. Lee, N.J. Kang, and M.W. Cho. 2004. Effect of night and daytime temperatures on growth and yield of paprika 'Fiesta' and 'Jubilee'. J Bio-Environ. Con. 13:226-232.

Chung, Y.M., H.J. Shin, S.Y. Park, D.C. An, B.G. Son, Y.C. Cho, and O.C. Kwon. 2007. Effect of plant growth regulations on production of good quality plant for Korean gerbera lines. J. Life Sci. 17:831-835. crossref(new window)

Cordi, B., M.H. Depledge, D.N. Price, L.F. Salter, and M.E. Donkin. 1997. Evaluation of chlorophyll fluorescence, in vivo spectrophotometric pigment absorption and ion leakage as biomarkers of UV-B exposure in marine macroalgae. Mar. Biol. 130:41-49. crossref(new window)

Epstein, E. 1999. Silicon. Annu. Rev. Plant Biol. 50:641-664.

Fridovich, I. 1991. Molecular oxygen: Friend and foe, p. 1-5. In: E.J. Pell and K.L. Steffen (eds.). Active oxygen/oxidative stress and plant metabolism. Amer. Soc. Plant Physiol. Rockville, MD, USA.

Guevel, M.H., J.G. Menzies, and R.R. Belanger. 2007. Effect of root and foliar applications of soluble silicon on powdery mildew control and growth of wheat plants. Eur. J. Plant Pathol. 119:429-436. crossref(new window)

Jones, L.H.P. and K.A. Handreck. 1967. Silica in soil, plants and animals. Adv. Agron. 19:107-149. crossref(new window)

Kang, K.S., C.J. Lim, T.J. Han, J.C. Kim, and C.D. Jin. 1998. Activation of ascorbate-glutathione cycle in Arabidopsis leaves in responses to aminotriazol. J. Plant Biol. 41:155-161.

Kim, S.G., K.W. Kim, E.W. Park, and D. Choi. 2002. Siliconinduced cell wall fortification of rice leaves: A possible cellular mechanism of enhanced host resistance to blast. Phytopathology 92:1095-1103. crossref(new window)

Kooten, O. and J.F.H. Snel. 1990. The use of chlorophyll fluorescence nomenclature in plant stress physiology. Photosynth. Res. 25:147-150. crossref(new window)

Lavorel, J. and A.L. Etienne. 1977. In vivo chlorophyll fluorescence, p. 203-268. In: J. Barber (ed.). Primary processes of photosynthesis. Elsevier Sci. Pub., Amsterdam.

Lutts, S., J.M. Kinet, and J. Bouharmont. 1995. Changes in plant response to NaCl during development of rice (Oryza sativa L.) varieties differing in salinity resistance. J. Expt. Bot. 46:1843-1852. crossref(new window)

Ma, J.F., K. Tamai, N. Yamaji, N. Mitani, S. Konishi, and M. Katsuhara. 2006. A silicon transporter in rice. Nature 440: 688-691. crossref(new window)

Marschner, H. 2003. Beneficial mineral elements, p. 405-435. In: H. Marschner (ed.). Mineral nutrition of higher plant. 2nd ed. Academic Press, Amsterdam.

Marschner, H., H. Oberle, I. Cakmak, and V. Romgeld. 1990. Growth enhancement by silicon in cucumber (Cucumis sativus) plants depends on imbalance in phosphorous and zinc supply. Plant Soil 124:211-219. crossref(new window)

Matoh, T., P. Kairusmee, and E. Takahashi. 1986. Salt induced damage to rice plants and alleviation effect of silicate. Soil Sci. Plant Nutr. 32:295-304. crossref(new window)

Monk, L.S., K.V. Fagerstedt, and R.M.M. Crawford. 1989. Oxygen toxicity and superoxide dismutase as an antioxidant in physiological stress. Physiol. Plant. 76:456-459. crossref(new window)

Muneer, S., Y.G. Park, A. Manivannan, P. Soundararajan, and B.R. Jeong. 2014. Physiological and proteomic analysis in chloroplasts of Solanum lycopersicum L. under silicon efficiency and salinity stress. Int. J. Mol. Sci. 15:21803-21824. crossref(new window)

Park, Y.G., I. Sivanesan, and B.R. Jeong. 2013. Effect of silicon source and application method on growth and development, and incidence of powdery mildew (Sphaerotheca pannosa var. rosae) in potted Rosa hybrida 'Apollo' and 'Remata'. Flowers Res. J. 21:56-62. crossref(new window)

Sadasivam, S. and A. Manickam. 1996. Enzymes, p. 121-124. In: S. Sadasivam and A. Manickam (eds.). Biochemical methods. New Age International Publishers, New Delhi.

Samuels, A.L., A.D.M. Glass, D.L. Ehret, and J.G. Menzies. 1991. Distribution of silicon in cucumber leaves during infection by powdery mildew fungus (Sphaerotheca fuliginea). Can. J. Bot. 69:140-146. crossref(new window)

Sangster, A.G., M.J. Hodson, and H.J. Tubb. 2001. Silicon deposition in higher plants, p. 85-114. In: L.E. Datnoff, G.H. Snyder, and G.H. Korndorfer (eds.). Silicon in agriculture. Elsevier Science, New York.

Sivanesan, I., J.Y. Song, S.J. Hwang, and B.R. Jeong. 2011. Micropropagation of Cotoneaster wilsonii Nakai - A rare endemic ornamental plant. Plant Cell Tiss. Organ Cult. 105:55-63. crossref(new window)

Son, M.S., H.J. Oh, J.Y. Song, M.Y.Lim, I. Sivanesan, and B.R. Jeong. 2012. Effect of silicon source and application method on growth of kalanchoe 'Peperu'. Korean J. Hortic. Sci. Technol. 30:250-255. crossref(new window)

Song, J.Y. 2012. Genetic transformation of chrysanthemum for enhanced silicon uptake. PhD. Diss., Gyeongsang Natl. Univ., Jinju, Korea.