Energetic driving force for LHCII clustering in plant membranes

Plants protect themselves against photodamage from excess energy using a process known as non-photochemical quenching (NPQ). A significant fraction of NPQ is induced by a ΔpH across the membrane, which changes the conformation, composition, and organization of the antenna complexes. In particular, clustering of the major light-harvesting complex (LHCII) has been observed, yet the thermodynamic driving force behind this reorganization has not been determined, largely because measurements of membrane protein interaction energies have not been possible. Here, we introduce a method to quantify membrane protein interaction energies and its application to the thermodynamics of LHCII clusters. By combining single-molecule measurements of LHCII-proteoliposomes at different protein densities and a rigorous analysis of LHCII clusters and photophysics, we quantified the LHCII-LHCII interaction energy to be approximately -5kBTat neutral pH and at least -7kBTat acidic pH. From these values, we found the thermodynamic driving force for LHCII clustering was dominated by these enthalpic contributions. Collectively, this work captures the membrane protein-protein interactions responsible for LHCII clustering from the perspective of equilibrium statistical thermodynamics, which has a long and rich tradition in biology.