These low-molecular-weight organic

These low-molecular-weight organic acids are important in Al detoxification by forming Al-organic acid complexes in the cytosol or at the root-soil interface (see reviews, Kochian et al. 2004; 2005). Kidd et al. (2001) reported that silicon-treated maize plants release
fifteen times more phenolic compounds (i.e., catechin and quercetin) than untreated maize plants. These flavonoid-type phenols, which were produced in addition to oxalic secretion, also showed strong Al-chelating activity and could potentially detoxify Al.Tea plants (Camellia sinensis L.), which have been widely reported to accumulate Al, grow well in highly acidic soils (optimal pH is 4 to 5) containing high levels of Al3þ (Konishi et al. 1985). Tea plants take up Al during growth (Chenery 1955), and old leaves have been
found to contain up to 30,000 mg Al kg1 of mass on a dry weight basis (Matsumoto et al. 1976). Despite these high Al concentrations, tea plants do not exhibit Al toxicity, which suggests that the detoxification of Al in tea plants occurs internally and/or externally. Several studies examining the Al tolerance mechanisms employed by tea plants have been undertaken to date. Nagata et al. (1991, 1992) found that Al occurred primarily as Alcatechin complexes in tea leaves, and we previously reported the existence of Al-citrate (Morita et al. 2004) and Al-oxalate (Morita et al. 2008) complexes in the xylem sap and roots of tea plants, respectively. Nonetheless, the mechanisms of Al detoxification by
tea plants are still poorly understood. In this experiment,we examined the roles of organic acids and phenolics in these mechanisms by analyzing the secretion of organic
acids and phenolic compounds from roots under sterile conditions. Caffeine exudation from the tea plant roots was observed in the medium containing Al. Then we discussed several hypotheses for the caffeine exudation and the role of organic acids in Al tolerance of tea plants.