Abstract
Legumes of the genus Medicago are agronomically important forage crops that also enhance soil fertility through biological nitrogen fixation. Beyond their agricultural value, Medicago species show promise for the ecological restoration of degraded soils, particularly through their symbiotic associations with soil microbial communities (rhizobacteria). However, in acidic soils-common in degraded environments-the presence of toxic metals such as aluminum (Al) poses a major constraint to plant establishment and microbial functioning. However, the specific impacts of Al stress on each symbiotic partner-and on the dynamics of their interaction-remain poorly understood. This review systematizes and describes recent advances in the effects of Al on Medicago legumes, which underlie increased tolerance to metal phytotoxicity, and aims to identify synergistic functions among plant and microbial partners. Al produces morphological and functional changes in Medicago species. Key strategies for metal tolerance involve detoxification mechanisms, such as organic acids production, that effectively mitigate the stress caused by metallic ions. Diverse plant growth-promoting rhizobacteria (PGPR) contribute significantly to each of these strategies, either by the direct production of metal-chelating compounds or by the induction of metal sequestration and/or transport functions in the host. These microorganisms, alone or in combination, display traits that can influence Al mobilization and removal for phytoremediation applications. Mechanisms underlying the effect of PGPR on Medicago gene expression during metal exposure have begun to be elucidated, as has the role of symbiotic interactions with arbuscular mycorrhizae. Additional studies employing transcriptomics, metabolomics, and genetic engineering are also necessary to fully understand their impact on common metal stress responses and tolerance mechanisms in the genus Medicago.