Abstract
The light-driven rhodopsin KR2 transports Na+via the M- and O-states. However, the mechanisms by which the retinal regulates Na+ pumping is unknown, in part because KR2 adopts both pentamer and monomer forms in crystal structures and in part because these structures show differences in the protein conformation near the Schiff base, even when they are of the same intermediate state within the photocycle. A particular open question is the nature of the H-bond networks and protonation state in the active site, including Asp116. Here, we analyze the protonation state and the absorption wavelength for each crystal structure, using a quantum mechanical/molecular mechanical approach. In the pentamer ground state, the calculated absorption wavelength reproduces the experimentally measured absorption wavelength (530 nm). The analysis also shows that ionized Asp116 is stabilized by the H-bond donations of both Ser70 and a cluster of water molecules. The absorption wavelength of 400 nm in the M-state can be best reproduced when the two O atoms of Asp116 interact strongly with the Schiff base, as reported in one of the previous monomer ground state structures. The absorption wavelengths calculated for the two Na+-incorporated O-state structures are consistent with the measured absorption wavelength (∼600 nm), which suggests that two conformations represent the O-state. These results may provide a key to designing enhanced tools in optogenetics.
Highlights
Microbial rhodopsins, which are involved in lightdependent biological functions in microorganisms, contain a retinal Schiff base as a chromophore (1, 2)
The potential energy profile of the H-bond between the Schiff base and Asp[116] indicates that pKa(Schiff base) > pKa(Asp116) in the pentamer and Skopintsev monomer structures, whereas pKa(Schiff base) ≈ pKa(Asp116) in the Kato monomer structure (Figs. 3A and S1)
The absorption wavelength calculated using the X-ray free electron laser (XFEL) O-state structure (15) is 596 nm (Table 2), which is consistent with the experimentally measured value (602 nm (11)). These results suggest that both the X-ray diffraction (XRD) and XFEL structures are functionally relevant conformations because the experimentally measured absorption wavelength can be reproduced only when the geometry of the retinal Schiff base moiety is functionally relevant (12)
Summary
Microbial rhodopsins, which are involved in lightdependent biological functions in microorganisms, contain a retinal Schiff base as a chromophore (1, 2). The pentameric (11) and monomeric (4, 15) KR2 structures show remarkable structural differences, at the Schiff base moiety. In all ground state structures, the Schiff base forms an H-bond with Asp[116], while a water molecule (W1) forms an H-bond with Arg[109] and Asp[251] (Fig. 1, B–D). A cluster of four water molecules (W1–W4, Fig. 1B) exists at the Schiff base moiety in the pentamer structure (11), whereas the corresponding cluster does not exist in the two monomer structures (4, 15) because of the presence of the Asn[112] side chain (Fig. 1, C and D). How the structural difference at the Schiff base moiety between the pentameric and monomeric forms affects the KR2 function remains unclear. The proton migrates from the Schiff base to Asp[116] upon M-state formation (17). The proton returns to the Schiff base (17) and the uptake of Na+ occurs (3) upon O-state formation (M-state decay)
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