Abstract
Acid invertase plays an important role in plants by hydrolyzing sucrose. Compounds exhibiting cytokinin activity were examined for their effects on acid invertase activity at three tuberization stages of potato,Solanum tuberosum L. Single nodal segments from the cultivar Atlantic were cultured on Murashige and Skoog (MS) medium with 6% sucrose and maintained under a 16-hr photoperiod. Media were supplemented with either 2 mg kinetin/1, 0.1 mg thidiazuron/1,1.0 mg AC243, 654/1 (a benzyl nitroguanidine), or 0.1 mg AC239, 604/1 (a phenyl nitroguanidine). Basal acid invertase activity was measured in stolon segments at three morphologically distinct tuberization stages: (1) “hook,” (2) “swelling,” and (3) “initiation.” The onset of tuber initiation was significantly advanced by kinetin and thidiazuron compared to controls. Stolons elongated during the hook and swelling stages until tubers were initiated. Basal acid invertase activity in stolons cultured on control medium significantly increased from hook stage to swelling stage and then decreased slightly when tubers were initiated. At the hook stage, highest basal acid invertase activity occurred when the segments were treated with kinetin and thidiazuron. Kinetin and thidiazuron induced basal acid invertase activity significantly decreased following the hook stage to tuber initiation. Basal acid invertase activity were significantly lower in stolons treated with nitroguanidines than the control activity following the hook stage of development. During the swelling and tuber initiation stages, nitroguanidines-treated segments showed reduction in basal acid invertase activity similar to segments treated with kinetin and thidiazuron treatments. Tuber initiation was preceded by a stimulation of basal acid invertase activity followed by a decrease prior to tuber initiation. Kinetin and thidiazuron stimulated enzyme activity early in the growth of stolons which may have resulted in faster stolon growth and in earlier tuber initiation. The two nitroguanidines, although able to mimic many cytokinin effects in bioassays, did not seem to act in the same way as kinetin.
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Literature Cited
ap Rees, T. and S. Morrell. 1990. Carbohydrate metabolism in developing potatoes. Am Potato J 67:835–847.
Avigad, G. 1982. Sucrose and other dissaccharides.In: Encyclopedia of Plant Physiology, New Series (FA Loewus and W. Tanner, eds.) Springer-Verlag, Berlin. Vol. 13 A, pp:217–347.
Geigenberger, P. and M. Stitt. 1993. Sucrose synthase catalyzes a readily reversible reactionin vivo in developing potato tubers and other plant tissues. Planta 189:329–339.
Hatch, M.D. and K.T. Glasziou. 1963. Sugar accumulation cycle in sugar cane. n. Relationship of invertase activity to sugar content and growth rate in storage tissue of plants grown in controlled environment. Plant Physiol 38:344–348.
Kruger, N.J. 1990. Carbohydrate synthesis and degradation.In: Plant Physiology, Biochemistry and Molecular Biology. (D.T. Dennis and D.H. Turpin, eds.) John Wiley & Sons, NY (Longman Sci. & Tech., UK).
Leigh, R.A., T. ap Rees, W.A. Fuller, and J. Banfield. 1979. The location of acid invertase activity and sucrose in the vacuoles of storage roots of beetroot (Beta vulgaris). Biochem J 178:539–547.
Mares, D.J., J.R. Sowokinos, and J.S. Hawker. 1985. Carbohydrate metabolism in developing potato tubers.In: Potato Physiology (P.H. Li, ed.) Academic Press, Inc., Orlando. pp:279–327.
Mok, M.C., D. W.S. Mok, J.E. Turner, and C.V. Mujer. 1987. Biological and biochemical effects of cytokinin-active phenylurea derivatives in tissue culture systems. HortScience 22:1194–1197.
Morrell, S. and T. ap Rees. 1986. Sugar metabolism in developing tubers ofSolanum tuberosum. Phytochemistry 25 (7):1579–1585.
Murashige, T. and F. Skoog. 1962. A revised medium for rapid growth and bioassays with tobacco tissue cultures. Physiol Plant 15:473–496.
Obata-Sasamoto, H. and H. Suzuki. 1979. Activities of enzymes relating to starch synthesis and endogenous levels of growth regulators in potato stolon tips during tuberization. Physiol Plant 45:320–324.
Palmer, C.E. and W.G. Barker. 1972. Changes in enzyme activity during elongation and tuberization of stolons ofSolanum tuberosum L. culturedin vitro. Plant and Cell Physiol 13:681–688.
Palmer, C.E. and W.G. Barker. 1973. Influence of ethylene and kinetin on tuberization and enzyme activity inSolanum tuberosum L. stolons culturedin vitro. Ann Bot 37:85–93.
Pavlista, A.D. 1993. Morphological changes and yield enhancement of Superior potatoes by AC 243,654. Am Potato J 70:49–59.
Pavlista, AD. 1995. Potato production stages: Scheduling key practices. Univ. Nebraska Coop. Ext. Bull. #95-1279.
Pressey, R. 1966. Separation and properties of potato invertase and invertase inhibitor. Arch Biochem Biophys 113:667–674.
Richardson, D.L., H.V. Davies, H.A. Ross, and G.R. Mackay. 1990. Invertase activity and its relation to hexose accumulation in potato tubers. J Exp Bot 41:95–99.
Ross, HA and H.V. Davies. 1992. Sucrose metabolism in tubers of potato (Solanum tuberosum L.). Effects of sink removal and sucrose flux on sucrose-degrading enzymes. Plant Physiol 98:287–293.
Sonnewald, U., M-R. Hajirezaei, J. Kossmann, A Heyer, R.N. Trethewey, and L. Willmitzer. Increased potato tuber size resulting from apoplastic expression of a yeast invertase. Nature Biotech 15:794–797.
Speltz, L.M., B.L. Walworth, and A.D. Pavlista. 1990. Substituted nitro and cyano-guanidines and their uses of increasing crop yields. USA Patent #4, 594,092.
Spiro, R.G. 1966. Analysis of sugars found in glycoproteins. Methods in Enzymology (E.F. Neufeld and V. Ginsburg, eds.)Vol. viii. Complex Carbohydrates. Academic Press, N.Y. pp:3–25.
Stitt, M. and W.P. Quick. 1989. Photosynthetic carbon partitioning: its regulation and possibilities for manipulation. Physiol Plant 77: 633–641.
Zrenner, R., M. Salanoubat, L. Willmitzer, and U. Sonnewald. 1995. Evidence of the crucial role of sucrose synthase for sink strength using transgenic potato plants (Solanum tuberosum L.). The Plant Jour 7:97–107.
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Kefi, S., Pavlista, A.D., Meagher, M.M. et al. Invertase activity as affected by cytokinin-like compounds during potato tuberizationin vitro . Am. J. Pot Res 77, 57–61 (2000). https://doi.org/10.1007/BF02853662
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DOI: https://doi.org/10.1007/BF02853662