Microbial Na+ -pumping rhodopsin (NaR) is a promising optogenetic tool due to its unique ability to transport Na+ . Like most rhodopsin-based tools, NaR is limited to light-based control. In this study, our objective was to develop a novel mode of modulation for NaR beyond light control. By introducing a potential Cl- binding site near the putative Na+ release cavity, we engineered Nonlabens dokdonensis rhodopsin 2 (NdR2) to be modulated by Cl- , an essential chemical in organisms. The engineered NdR2 demonstrated an approximately two-fold increase in Na+ pump activity in the presence of 100 mM Cl- compared to Cl- -free solution. Increasing Cl- concentration decreased the lifetimes of the M and O intermediates accordingly. The analysis of competitive ion uptake suggested the bound Cl- may increase the Na+ affinity and selectivity. This chemical modulation allows for more diverse and precise control over cellular processes, advancing the development of next-generation optogenetic tools. Notably, our Cl- -modulated NdR2 establishes an innovative mechanism for linking Cl- to Na+ -related processes, with potential applications in optogenetic therapies for related diseases.
Keywords: chloride modulation; kinetics; membrane proteins; sodium pumps.
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