Lateral roots are crucial for the plasticity of root responses to environmental conditions in soil. The bacterivorous microfauna has been shown to increase root branching and to foster auxin producing soil bacteria. However, information on modifications of plant internal auxin content by soil bacteria and bacterivores is missing. Therefore, the effects of a rhizosphere bacterial community and a common soil amoeba (Acanthamoeba castellanii) on root branching and on auxin (indole-3-acetic acid) metabolism in Lepidium sativum and Arabidopsis thaliana were investigated. In a first experimental series, bacteria increased conjugated auxin concentrations in L. sativum shoots, but did not alter free bioactive auxin content nor root branching. In contrast, in presence of soil bacteria plus amoebae free auxin concentrations in shoots and root branching increased, demonstrating that effects of bacteria on auxin metabolism in plants were strongly modified by the bacterivorous amoebae. In a second experiment, A. thaliana reporter plants for auxin (DR5) and cytokinin (ARR5) responded similarly with increased root branching in the presence of amoebae. Surprisingly, in reporter plants cytokinin but not auxin responses were detectable, accompanied by higher soil nitrate concentrations in the presence of amoebae. Likely, increased nitrate concentrations in the rhizosphere led to an accumulation of cytokinin and interactions with free auxin in plants and finally to increased root growth in the presence of amoebae. Altogether, the results show that mutual control mechanisms exist between plant hormone metabolism and microbial signalling, and that effects on hormonal concentrations of plants by free-living bacteria are strongly influenced by bacterial grazers like amoebae.
The development of Agrobacterium tumefaciens-induced plant tumors primarily depends on the excessive production of auxin and cytokinin by enzymes encoded on T-DNA genes integrated into the plant genome. The aim of the present study was to investigate the involvement of additional phytohormone signals in the vascularization required for rapid tumor proliferation. In stem tumors of Ricinus communis L., free auxin and zeatin riboside concentrations increased within 2 weeks to 15-fold the concentrations in control stem tissue. Auxin and cytokinin immunolocalization revealed the highest concentrations within and around tumor vascular bundles with concentration gradients. The time-course of changes in free auxin concentration in roots was inversely correlated with that in the tumors. The high ethylene emission induced by increased auxinand cytokinin correlated with a 36-fold accumulation of abscisic acid in tumors. Ethylene emitted from tumors and exogenously applied ethylene caused an increase in abscisic acid concentrations also in the host leaves, with a diminution in leaf water vapor conductance. Jasmonic acid concentration reached a maximum already within the first week of bacterial infection. A wound effect could be excluded. The results demonstrate the concerted interaction of a cascade of transiently induced, non-T-DNA-encoded phytohormones jasmonic acid, ethylene and abscisic acid with T-DNA-encoded auxin and zeatin riboside plus trans-zeatin, all of which are required for successful plant tumor vascularization and development together with inhibition of host plant growth. Electronic Supplementary Material is available if you access this article at http://dx.
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