Abstract

Plant aluminum-activated malate transporters (ALMTs) are currently classified as anion channels; they are also known to be regulated by diverse signals, leading to a range of physiological responses. Gamma-aminobutyric acid (GABA) regulation of anion flux through ALMT proteins requires a specific amino acid motif in ALMTs that shares similarity with a GABA binding site in mammalian GABA_A receptors. Here, we explore why TaALMT1 activation leads to a negative correlation between malate efflux and endogenous GABA concentrations ([GABA]_i) in both wheat (<i>Triticum aestivum</i>) root tips and in heterologous expression systems. We show that TaALMT1 activation reduces [GABA]_i because TaALMT1 facilitates GABA efflux but GABA does not complex Al³⁺ TaALMT1 also leads to GABA transport into cells, demonstrated by a yeast complementation assay and via ¹⁴C-GABA uptake into <i>TaALMT1</i>-expressing <i>Xenopus laevis</i> oocytes; this was found to be a general feature of all ALMTs we examined. Mutation of the GABA motif (TaALMT1^F213C) prevented both GABA influx and efflux, and resulted in no correlation between malate efflux and [GABA]_i We conclude that ALMTs are likely to act as both GABA and anion transporters in planta. GABA and malate appear to interact with ALMTs in a complex manner to regulate each other's transport, suggestive of a role for ALMTs in communicating metabolic status.