The Promotive Effect of Brassinolide on Lamina Joint-Cell Elongation, Germination and Seedling Growth under Low-Temperature Stress in Rice (Oryza sativa L.)

References

• Gregory, L.E. and Mandava, N.B. 1982. The activity and interaction of brassinolide and gibberellic acid in mung bean epicotyls. Physiol. Plant. 54 : 239–243.
   Google Scholar
• He, R., wang, G. and Wang, X. 1991. Effects of brassinolide on growth and chilling resistance of maize seedlings. In Gulter, H.
   Google Scholar
• G.G., Yokota, T. and Adam, G. eds., Brassinosteroids : Chemistry, Bioactivity and Application (AGS symposium series 474). American Chemical Society, Washington D.G. 220–230.
   Google Scholar
• Hirai, K., Fujii, S. and Fujita, A. 1986. Effect of brassinolide on plant growth regulation IV. The XXI annual meeting of the Society for the Chemical Regulation of Plants. 42–43.
   Google Scholar
• Kamuro, Y. and Takatsuto, H. 1988. The current status and problems on practical uses of brassinosteroids. Chem. Regul. Plants. 23 : 142–150.
   Google Scholar
• Katsumi, M. 1991. Physiological modes of brassinolide action in cucumber hypocotyl growth. In Culter, H. G. G., Yokota, T. and Adam, G. eds., Brassinosteroids : Chemistry, Bioactivity and Application (ACS symposium series 474). American Chemical Society, Washington D. C. 246–254.
   Google Scholar
• Maeda, E. and Saka, H. 1968. Establishment of a new method for study of the inclination rate of lamina in the excised rice leaves. Proc. Crop Sci. Soc. Japan 37 : 37–44.
   Google Scholar
• Maeda, E. and Saka, H. 1970. Regulation of lamina-inclination rate by selective inhibitors in excited rice leaves. Proc. Crop Sci. Soc. Jpn. 39 : 279–286.
   Google Scholar
• Mandava, N. B. 1988. Plant growth-promoting brassinosteroids. Ann. Rev. Plant Physiol. Plant Mol. Biol. 39 : 23–52.
   Google Scholar
• Marumo, S. and Wada, H. 1981. Brassinolide, a new plant growth regulator. Chem. Regul. Plants 16: 1–10.
   Google Scholar
• Nishikawa, N., Toyama, S., Shida, A. and Futatsuya, F. 1994. The uptake and the transport of 14C-labeled epibrassinolide in intact seedlings of cucumber and wheat. J. Plant Res. 107 : 125–130.
   Google Scholar
• Roddick, J.G. and Guan, M. 1991. Brassinosteroids and root development. In Gulter, H. G. G., Yokota, T. and Adam, G. eds., Brassinosteroids : Chemistry, Bioactivity and Application (ACS symposium series 474). American Chemical Society, Washington D.G. 231–245.
   Google Scholar
• Sakurai, A. and Fujioka, S. 1993. The current status of physiology and biochemistry of brassinosteroids. Plant Growth Regul. 13 : 147–159.
   Google Scholar
• Sasse, J. M. 1990. Brassinolide-induced elongation and auxin. Physiol. Plant. 80:401–408.
   Google Scholar
• Sasse, J. 1999. Physiological actions of brassinosteroids. In Sakurai, A., Yokota, T. and Glouse, S.D. eds., Brassinosteroids – Steroidal Plant Hormones – . Springer, Tokyo. 137–161.
   Google Scholar
• Sathiyamoorthy, P. and Nakamura, S. 1990. In vitro root induction by 24-epibrassinolide on hypocotyl segments of soybean {Glycine max Merr). Plant Growth Regul. 9 : 73–76.
   Google Scholar
• Takeuchi, Y. 1992. Studies on physiology and application of brassinosteroids. Chem. Regul. Plants. 27 : 1–10.
   Google Scholar
• Takeuchi, Y. and Kamuro, Y. 1997. Physiology and present situation for practical use of brassinosteroid and jasmonoid compounds. Chem. Regul. Plants. 32 : 74–86.
   Google Scholar
• Wada, K., Marumo, S., Ikekawa, N., Morisaki, M. and Mori, M. 1981. Brassinolide and homobrassinolide promotion of lamina inclination of rice seedling. Plant Cell Physiol. 22 : 323–325.
   Google Scholar
• Yang, G. and Komatsu, S. 2000. Involvement of calcium-dependent protein kinase in rice {Oryza sativa L.) lamina inclination caused by brassinolide. Plant Cell Physiol. 41 : 1243–1250.
   Google Scholar
• Yokota, T., Higuchi, K., Kosaka, Y. and Takahashi, N. 1992. Transport and metabolism of brassinosteroids in rice. In : Carssen, G.M. eds., Plant Growth Substances. Kluwer Academic Publishers, Dordrecht. 298–305.
   Google Scholar