Abstract
Auxin (indole-3-acetic acid) controls the orientation of cortical microtubes (MT) at the outer wall of the outer epidermis of growing maize coleoptiles (Bergfeld, R., Speth, V., Schopfer, P., 1988, Bot. Acta101, 57–67). A detailed time course of MT reorientation, determined by labeling MT with fluorescent antibodies, revealed that the auxin-mediated movement of MT from the longitudinal to the transverse direction starts after less than 15 min and is completed after 60 min. This response was used for a critical test of the functional involvement of auxin in tropic curvature. It was found that phototropic (first phototropic curvature) as well as gravitropic bending are correlated with a change of MT orientation from transverse to longitudinal at the slowergrowing organ flank whereas the transverse MT orientation is maintained (or even augmented) at the faster-growing organ flank. These directional changes are confined to the MT subjacent to the outer epidermal wall. The same basic results were obtained with sunflower hypocotyls subjected to phototropic or gravitropic stimulation. It is concluded that auxin is, in fact, involved in asymmetric growth leading to tropic curvature. However, our results do not allow us to discriminate between an uneven distribution of endogenous auxin or an even distribution of auxin, the activity of which is modulated by an unevenly distributed inhibitor of auxin action.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Abbreviations
- IAA:
-
indole-3-acetic acid
- MT:
-
cortical microtubules
- OEW:
-
outer epidermal wall (outer epidermis of maize coleoptile)
References
Bergfeld, R., Speth, V., Schopfer, P. (1988) Reorientation of microfibrils and microtubules at the outer epidermal wall of maize coleoptiles during auxin-mediated growth. Bot. Acta101, 57–67
Briggs, W.R., Baskin, T.J. (1988) Phototropism in higher plants — controversies and caveats. Bot. Acta101, 133–138
Feyerabend, M., Weiler, E.W. (1988) Immunological estimation of growth regulator distribution in phototropically reacting sunflower seedlings. Physiol. Plant.74, 185–193
Firn, R.D., Digby, J. (1980) The establishment of tropic curvatures in plants. Annu. Rev. Plant Physiol.31, 131–148
Hasegawa, K., Sakoda, M., Bruinsma, J. (1989) Revision of the theory of phototropism in plants: a new interpretation of a classical experiment. Planta178, 540–544
Iwami, S., Masuda, Y. (1976) Distribution of labeled auxin in geotropically stimulated stems of cucumber and pea. Plant Cell Physiol.17, 227–237
Kutschera, U. (1987) Cooperation between outer and inner tissues in auxin-mediated plant organ growth. In: Physiology of cell expansion during plant growth, pp. 215–226, Cosgrove, D.J., Knievel, D.P., eds. American Society of Plant Physiologists, Rockville, Md., USA
Lang, J.M., Eisinger, W.R., Green, P.B. (1982) Effects of ethylene on the orientation of microtubules and cellulose microfibrils of pea epicotyl cells with polylamellate cell walls. Protoplasma110, 5–14
Lloyd, C.W. (1987) The plant cytoskeleton: the impact of fluorescence microscopy. Annu. Rev. Plant Physiol.38, 119–139
McClure, B.A., Guilfoyle, T. (1989) Rapid redistribution of auxinregulated RNAs during gravitropism. Science243, 91–93
McDonald, J.R., Hart, J.W. (1987) New light on the Cholodny-Went theory. Plant Physiol.84, 568–570
Nick, P., Schäfer, E. (1988) Interaction of gravi- and phototropic stimulation in the response of maize (Zea mays L.) coleoptiles. Planta173, 213–220
Pickard, B.G. (1985) Roles of hormones in phototropism. In: Encyclopedia of plant physiology, N.S., vol. 11: Hormonal regulation of development III, pp. 365–417, Pharis, R.P., Reid, D.M., eds. Springer, Berlin Heidelberg New York
Preston, R.D. (1988) Cellulose-microfibril-orienting mechanisms in plant cell walls. Planta174, 67–74
Quader, H., Deichgräber, G., Schnepf, E. (1986) The cytoskeleton ofCobaea seed hairs. Planta168, 1–10
Roberts, I.N., Lloyd, C.W., Roberts, K. (1985) Ethylene-induced microtubule reorientations: Mediation by helical arrays. Planta164, 439–447
Sawhney, V.K., Srivastava, L.M. (1975) Wall fibrils and microtubules in normal and gibberellic-acid-induced growth of lettuce hypocotyl cells. Can. J. Bot.53, 824–835
Shibaoka, H. (1974) Involvement of wall microtubules in gibberellin promotion and kinetin inhibition of stem elongation. Plant Cell Physiol.15, 255–263
Volfová, A., Chvojka, L., Haňkovská, J. (1972) The orientation of cell wall microtubules in wheat coleoptile segments subjected to phytohormone treatment. Biol. Plant. (Praha)19, 421–425
Went, F.W., Thimann, K.V. (1937) Phytohormones. MacMillan, New York
Author information
Authors and Affiliations
Additional information
The authors dedicate this paper to Professor Dr. Drs. h.c. Hans Mohr on the occasion of his 60th birthday.
Rights and permissions
About this article
Cite this article
Nick, P., Bergfeld, R., Schäfer, E. et al. Unilateral reorientation of microtubules at the outer epidermal wall during photo- and gravitropic curvature of maize coleoptiles and sunflower hypocotyls. Planta 181, 162–168 (1990). https://doi.org/10.1007/BF02411533
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF02411533