MILDEW RESISTANCE LOCUS O (MLO) proteins function as trimeric inward calcium channels

Calcium signalling and structural roles are fundamental for plant growth, development, and environmental adaptation. Recent studies have identified MILDEW RESISTANCE LOCUS O (MLO) proteins as novel calcium-permeable channels with roles in root growth, cell wall development, pollen tube growth, and perception. However, the molecular mechanisms underlying MLO function remain unknown. Here, we demonstrate that multimerisation is essential for MLO activity. Chemical crosslinking, split-ubiquitin interaction assays, and single-molecule photobleaching revealed that MLO proteins form stable dimeric and trimeric assemblies at the plasma membrane. Structural modelling uncovered a molecular architecture of the MLO trimer with a central ion-conducting pore, which was further examined by molecular dynamics simulations in a lipid membrane environment. Computational electrophysiology showed preferential inward Ca ²⁺ transport, confirming that MLO proteins function as calcium influx transporters, and identified a conserved set of pore-lining residues that coordinate ion translocation. Functional and structural analyses indicated that the mechanism of calcium permeation is evolutionarily conserved. Our findings provide mechanistic insight into MLO-mediated calcium influx across the plasma membrane and establish multimerisation as a critical determinant of this calcium channel’s activity.