In plants， strict regulation of stomatal pores is critical for modulation of CO fixation and transpiration. Under certain abiotic and biotic stressors， pore closure is initiated through anionic flux， with calcium (Ca) playing a central role. The aluminum-activated malate transporter 12 (ALMT12) is a malate-activated， voltage-dependent member of the aluminum-activated malate transporter family that has been implicated in anionic flux from guard cells controlling the stomatal aperture. Herein， we report the characterization of the regulatory mechanisms mediating channel activities of an ALMT from the grass (BdALMT12) that has the highest sequence identity to ALMT12. Electrophysiological studies in a heterologous cell system confirmed that this channel is malate- and voltage-dependent. However， this was shown to be true only in the presence of Ca Although a general kinase inhibitor increased the current density of BdALMT12， a calmodulin (CaM) inhibitor reduced the Ca-dependent channel activation. We investigated the physiological relevance of the CaM-based regulation ， where stomatal closure， induced by exogenous Ca ionophore and malate， was shown to be inhibited by exogenous application of a CaM inhibitor. Subsequent analyses revealed that the double substitutions R335A/R338A and R335A/K342A， within a predicted BdALMT12 CaM-binding domain (CBD)， also decreased the channels' ability to activate. Using isothermal titration calorimetry and CBD-mimetic peptides， as well as CaM-agarose affinity pulldown of full-length recombinant BdALMT12， we confirmed the physical interaction between the CBD and CaM. Together， these findings support a co-regulatory mechanism of BdALMT12 activation by malate， and Ca/CaM， emphasizing that a complex regulatory network modulates BdALMT12 activity.