A Model for the Development of the Rhizobial and Arbuscular Mycorrhizal Symbioses in Legumes and Its Use to Understand the Roles of Ethylene in the Establishment of these two Symbioses

We propose a model depicting the development of nodulation and arbuscular mycorrhizae. Both processes are dissected into many steps, using Pisum sativum L. nodulation mutants as a guideline. For nodulation, we distinguish two main developmental programs, one epidermal and one cortical. Whereas Nod factors alone affect the cortical program, bacteria are required to trigger the epidermal events. We propose that the two programs of the rhizobial symbiosis evolved separately and that, over time, they came to function together. The distinction between these two programs does not exist for arbuscular mycorrhizae development despite events occurring in both root tissues. Mutations that affect both symbioses are restricted to the epidermal program. We propose here sites of action and potential roles for ethylene during the formation of the two symbioses with a specific hypothesis for nodule organogenesis. Assuming the epidermis does not make ethylene, the microsymbionts probably first encounter a regulatory level of ethylene at the epidermis–outermost cortical cell layer interface. Depending on the hormone concentrations there, infection will either progress or be blocked. In the former case, ethylene affects the cortex cytoskeleton, allowing reorganization that facilitates infection; in the latter case, ethylene acts on several enzymes that interfere with infection thread growth, causing it to abort. Throughout this review, the difficulty of generalizing the roles of ethylene is emphasized and numerous examples are given to demonstrate the diversity that exists in plants

Transcriptional profiling of wheat and wheat-rye addition lines to identify candidate genes for aluminum tolerance

A large-scale expression profiling study was performed to investigate candidate genes associated with the two quantitative trait loci for aluminum (Al) tolerance (Alt1 and Alt2). They have been identified in rye and localized on chromosomes 6R and 3R, respectively. Materials employed were hexaploid wheat (cv. Chinese Spring), and two wheatrye addition lines (3R-AL and 6R-AL). Seedlings were treated with and without Al for 24 h to examine genes upregulated or down-regulated by Al. Measurements of root growth at different Al concentrations showed the Al tolerance was higher in 3R-AL than in 6R-AL and wheat. Initial transcriptomic results revealed that more genes changed expression (>10 fold) in the wheat and in the 6R-AL line (moderately tolerant) than in the 3R-AL line (highly tolerant). A method was developed to determine whether candidate genes are involved in Al tolerance or in responses to Al toxicity. Real-time quantitative PCRs were carried out in a subset of six genes with known function in near isogenic rye lines 389 (Al-sensitive) and 390 (Al tolerant). All six genes were up-regulated by Al in line 389 but not in line 390, indicating that they were involved in Al stress response but not in Al tolerance mechanisms. Subsequent analysis of Arabidopsis lines with knockout mutations in homologues of these six genes showed an Al sensitivity similar to the wild-type, providing more evidence towards their participation in the response to stress rather than to Al tolerance. Once the stress response genes were ruled out, the focus was turned to the identification of tolerance genes by studying transcripts up-regulated and down-regulated in the tolerant 3R line with respect to wheat and 6R line. Finally, a list of candidate genes that could be conferring increased tolerance was obtainedDepto. de Genética, Fisiología y MicrobiologíaFac. de Ciencias BiológicasTRUEpu