CO2 regulator SLAC1 and its homologues are essential for anion homeostasis in plant cells

Abstract

The continuing rise in atmospheric [CO₂] is predicted to have diverse and dramatic effects on the productivity of agriculture, plant ecosystems and gas exchange^1,2,3. Stomatal pores in the epidermis provide gates for the exchange of CO₂ and water between plants and the atmosphere, processes vital to plant life^4,5,6. Increased [CO₂] has been shown to enhance anion channel activity⁷ proposed to mediate efflux of osmoregulatory anions (Cl^– and malate^2–) from guard cells during stomatal closure^8,9. However, the genes encoding anion efflux channels in plant plasma membranes remain unknown. Here we report the isolation of an Arabidopsis gene, SLAC1 (SLOW ANION CHANNEL-ASSOCIATED 1, At1g12480), which mediates CO₂ sensitivity in regulation of plant gas exchange. The SLAC1 protein is a distant homologue of bacterial and fungal C4-dicarboxylate transporters, and is localized specifically to the plasma membrane of guard cells. It belongs to a protein family that in Arabidopsis consists of four structurally related members that are common in their plasma membrane localization, but show distinct tissue-specific expression patterns. The loss-of-function mutation in SLAC1 was accompanied by an over-accumulation of the osmoregulatory anions in guard cell protoplasts. Guard-cell-specific expression of SLAC1 or its family members resulted in restoration of the wild-type stomatal responses, including CO₂ sensitivity, and also in the dissipation of the over-accumulated anions. These results suggest that SLAC1-family proteins have an evolutionarily conserved function that is required for the maintenance of organic/inorganic anion homeostasis on the cellular level.