A mechanism that confers increased Al resistance in the Arabidopsis thaliana mutantalr-104 was investigated. A modified vibrating microelectrode system was used to measure H⁺ fluxes generated along the surface of small Arabidopsis roots. In the absence of Al, no differences in root H⁺ fluxes between wild type and alr-104 were detected. However, Al exposure induced a 2-fold increase in net H⁺ influx inalr-104 localized to the root tip. The increased flux raised the root surface pH of alr-104 by 0.15 unit. A root growth assay was used to assess the Al resistance ofalr-104 and wild type in a strongly pH-buffered nutrient solution. Increasing the nutrient solution pH from 4.4 to 4.5 significantly increased Al resistance in wild type, which is consistent with the idea that the increased net H⁺ influx can account for greater Al resistance in alr-104. Differences in Al resistance between wild type and alr-104 disappeared when roots were grown in pH-buffered medium, suggesting that Al resistance in alr-104 is mediated only by pH changes in the rhizosphere. This mutant provides the first evidence, to our knowledge, for an Al-resistance mechanism based on an Al-induced increase in root surface pH.