Abstract
Many microbial rhodopsins self-oligomerize, but the functional consequences of oligomerization have not been well clarified. We examined the effects of oligomerization of a H+ pump, Gloeobacter rhodopsin (GR), by using nanodisc containing trimeric and monomeric GR. The monomerization did not appear to affect the unphotolyzed GR. However, we found a significant impact on the photoreaction: The monomeric GR showed faint M intermediate formation and negligible H+ transfer reactions. These changes reflected the elevated pKa of the Asp121 residue, whose deprotonation is a prerequisite for the functional photoreaction. Here, we focused on His87, which is a neighboring residue of Asp121 and conserved among eubacterial H+ pumps but replaced by Met in an archaeal H+ pump. We found that the H87M mutation removes the “monomerization effects”: Even in the monomeric state, H87M contained the deprotonated Asp121 and showed both M formation and distinct H+ transfer reactions. Thus, for wild-type GR, monomerization probably strengthens the Asp121-His87 interaction and thereby elevates the pKa of Asp121 residue. This strong interaction might occur due to the loosened protein structure and/or the disruption of the interprotomer interaction of His87. Thus, the trimeric assembly of GR enables light-induced H+ transfer reactions through adjusting the positions of key residues.
Highlights
The cell membrane is a very thin film compared to the cell diameter but has a substantial capacity to execute various reactions, such as energy conversions, signal transductions, and the capture and expulsion of substances
We examined the effects of monomerization on the H+ pump Gloeobacter rhodopsin (GR) from the cyanobacterium Gloeobacter violaceus[24,25]
GR disrupts into monomers, which become dominant below pH 4
Summary
The cell membrane is a very thin film compared to the cell diameter but has a substantial capacity to execute various reactions, such as energy conversions, signal transductions, and the capture and expulsion of substances. Monomerization elevates the pKa of Asp[97], which acts as the “H+ acceptor” for the protonated Schiff base This primary H+ transfer is a prerequisite for pump activity and occurs only when the H+ acceptor is deprotonated in the dark state. We reported that detergent-solubilized GR shows a pH-dependent multiplicity of oligomeric states[39]: At neutral and alkaline pH, GR forms trimers and higher oligomers. This assembly disrupts into monomers upon acidification, probably reflecting the protonation of Asp[121], which is the H+ acceptor for GR. The experimental results indicated the crucial importance of oligomerization for the H+-pumping function
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