INVESTIGATIONS ON THE ROOT FORMATION IN THE TISSUES OF HELIANTHUS TUBEROSUS CULTURED IN VITRO

Abstract

Excised rhizome fragments of Helianthus tuberosus ‘Violet de Rennes’ produce roots in vitro; the sequence of morphogenetic phenomena is as follows: proliferation, differentiation of phloem and tracheids, organization of cambiums, and formation of root primordia from cambiums. This rhizogenesis is conditioned by five limiting factors: mineral salts, sugar, auxin, temperature, and light. The optimum level of each of these factors was determined and in certain cases also the threshold of action. For white light the beginning was about 1/1000 lux. These five limiting factors do not represent the same site of action. The mineral salts, especially nitrogen and calcium, have their effect when the cambiums have been organized. The sugars act before the formation of cambiums. Light operates principally upon cambium and this action is independent of photosynthesis. It was not possible to determine whether the auxin has a preferential site of action. A temperature higher than 15 C is essential to obtain the formation of cambiums but further production of roots is possible at 15 C or even less. The variations in temperature more or less around the optimum stimulate rhizogenesis. The supra‐optimal temperatures mainly have their effect before the formation of cambiums and infra‐optimal temperatures after. The effect of light can be exhibited at low temperature. Gibberellic acid in association with auxin favors root formation in the dark whereas in light it exhibits inhibiting properties. Rhizogenetic potentialities of tissues are reduced when these are cultured in the dark in presence of auxin. On the other hand, if auxin is applied after the isolation of explants, rhizogenesis is stimulated and the tissues are able to produce roots even in the dark. The action of light and of auxin can be dissociated; when the explants having absorbed a small quantity of auxin are transferred to a medium without auxin for 60 days in the dark, they conserve the rhizogenetic potential which is expressible on transferring them to light. Finally, grafting experiments suggested that light could induce the formation of a rhizogenetic factor in the tissues which is transmittable from cell to cell. These experiments have definitely established that the induction of root formation is governed by several factors which have complex interactions.