Unique Photochemistry Observed in a New Microbial Rhodopsin

FTIR study of light-induced proton transfer and Ca2+ binding in T82D mutant of TAT rhodopsin

Proton transfer reactions play important functional roles in many proteins, such as enzymes and transporters, which is also the case in rhodopsins. In fact, functional expression of rhodopsins accompanies intramolecular proton transfer reactions in many cases. One of the exceptional cases can be seen in the protonated form of marine bacterial TAT rhodopsin, which isomerizes the retinal by light but returns to the original state within 10-5 s. Thus, light energy is converted into heat without any function. In contrast, the T82D mutant of TAT rhodopsin conducts the light-induced deprotonation of the Schiff base at high pH. In this article, we report the structural analysis of T82D by means of difference Fourier transform infrared (FTIR) spectroscopy. In the light-induced difference FTIR spectra at 77 K, we observed little hydrogen out-of-plane vibrations for T82D as well as the wild-type (WT), suggesting that the planar chromophore structure itself is not the origin of the reversion from the K intermediate in WT TAT rhodopsin. Upon relaxation of the K intermediate, T82D forms the following intermediate, such as M, whereas K of WT returns to the original state. Present FTIR analysis revealed the proton transfer from the Schiff base to D82 in T82D upon formation of the M intermediate. It is accompanied by the second proton transfer from E54 to the Schiff base, forming the N intermediate, particularly in membranes. The equilibrium between the M and N intermediates corresponds to the protonation equilibrium between E54 and the Schiff base. We also found that Ca2+ binding takes place in T82D as well as WT but with 6 times lower affinity. An altered hydrogen-bonding network would be the origin of low affinity in T82D, where deprotonation of E54 is involved in the Ca2+ binding.

Hydrogen-Bonding and Hydrophobic Interaction Networks as Structural Determinants of Microbial Rhodopsin Function

Microbial pump rhodopsins are highly versatile light-driven membrane proteins that couple protein conformational dynamics with ion translocation across the cell membranes. Understanding how microbial pump rhodopsins use specific amino acid residues at key functional sites to control ion selectivity and ion pumping direction is of general interest for membrane transporters, and could guide site-directed mutagenesis for optogenetics applications. To enable direct comparisons between proteins with different sequences we implement, for the first time, a unique numbering scheme for the microbial pump rhodopsin residues, NS-mrho. We use NS-mrho to show that distinct microbial pump rhodopsins typically have hydrogen-bond networks that are less conserved than anticipated from the amino acid residue conservation, whereas their hydrophobic interaction networks are largely conserved. To illustrate the role of the hydrogen-bond networks as structural elements that determine the functionality of microbial pump rhodopsins, we performed experiments, atomic-level simulations, and hydrogen bond network analyses on GR, the outward proton pump from Gloeobacter violaceus, and KR2, the outward sodium pump from Krokinobacter eikastus. The experiments indicate that multiple mutations that recover KR2 amino acid residues in GR not only fail to convert it into a sodium pump, but completely inactivate GR by abolishing photoisomerization of the retinal chromophore. This observation could be attributed to the drastically altered hydrogen-bond interaction network identified with simulations and network analyses. Taken together, our findings suggest that functional specificity could be encoded in the collective hydrogen-bond network of microbial pump rhodopsins.

Calcium Binding Mechanism in TAT Rhodopsin

TAT rhodopsin binds Ca2+ near the Schiff base region, which accompanies deprotonation of the Schiff base. This paper reports the Ca2+-free and Ca2+-bound structures of TAT rhodopsin by molecular dynamics (MD) simulation launched from AlphaFold structures. In the Ca2+-bound TAT rhodopsin, Ca2+ is directly coordinated by eight oxygen atoms, four oxygens of the side chains of E54 and D227, and four oxygens of water molecules. E54 is not involved in the hydrogen-bonding network of the Ca2+-free TAT rhodopsin, while flipping motion of E54 allows Ca2+ binding to TAT rhodopsin with deformation of helices observed by FTIR spectroscopy. The hydrogen-bonding network plays a crucial role in maintaining the Ca2+ binding, as mutations of E54, Y55, R79, Y200, E220, and D227 abolished the binding. Only T82V exhibited the Ca2+ binding like the wild type among the mutants in this study. The molecular mechanism of Ca2+ binding is discussed based on the present computational and experimental analysis.

Calcium-Sensitive Microbial Rhodopsin VirChR1: A Femtosecond to Second Photocycle Study

Viral rhodopsins are light-gated cation channels representing a novel class of microbial rhodopsins. For viral rhodopsin 1 subfamily members VirChR1 and OLPVR1, channel activity is abolished above a certain calcium concentration. Here we present a calcium-dependent spectroscopic analysis of VirChR1 on the femtosecond to second time scale. Unlike channelrhodopsin-2, VirChR1 possesses two intermediate states P1 and P2 on the ultrafast time scale, similar to J and K in ion-pumping rhodopsins. Subsequently, we observe multifaceted photocycle kinetics with up to seven intermediate states. Calcium predominantly affects the last photocycle steps, including the appearance of additional intermediates P6Ca and P7 representing the blocked channel. Furthermore, the photocycle of the counterion variant D80N is drastically altered, yielding intermediates with different spectra and kinetics compared to those of the wt. These findings demonstrate the central role of the counterion within the defined reaction sequence of microbial rhodopsins that ultimately defines the protein function.

Multiple Roles of a Conserved Glutamate Residue for Unique Biophysical Properties in a New Group of Microbial Rhodopsins Homologous to TAT Rhodopsin

TAT rhodopsin, a microbial rhodopsin found in the marine SAR11 bacterium HIMB114, uniquely possesses a Thr-Ala-Thr (TAT) motif in the third transmembrane helix. Because of a low pKa value of the retinal Schiff base (RSB), TAT rhodopsin exhibits both a visible light-absorbing state with the protonated RSB and a UV-absorbing state with the deprotonated RSB at a neutral pH. The UV-absorbing state, in contrast to the visible light-absorbing one, converts to a long-lived photointermediate upon light absorption, implying that TAT rhodopsin functions as a pH-dependent light sensor. Despite detailed biophysical characterization and mechanistic studies on the TAT rhodopsin, it has been unknown whether other proteins with similarly unusual features exist. Here, we identified several new rhodopsin genes homologous to the TAT rhodopsin of HIMB114 (TATHIMB) from metagenomic data. Based on the absorption spectra of expressed proteins from these genes with visible and UV peaks similar to that of TATHIMB, they were classified as Twin-peaked Rhodopsin (TwR) family. TwR genes form a gene cluster with a set of 13 ORFs conserved in subclade IIIa of SAR11 bacteria. A glutamic acid in the second transmembrane helix, Glu54, is conserved in all of the TwRs. We investigated E54Q mutants of two TwRs and revealed that Glu54 plays critical roles in regulating the RSB pKa, oligomer formation, and the efficient photoreaction of the UV-absorbing state. The discovery of novel TwRs enables us to study the universality and individuality of the characteristics revealed so far in the original TATHIMB and contributes to further studies on mechanisms of unique properties of TwRs.

Photochemistry of the Retinal Chromophore in Microbial Rhodopsins

Microbial rhodopsins are photoreceptive membrane proteins of microorganisms that express diverse photobiological functions. All-trans-retinylidene Schiff base, the so-called all-trans-retinal, is a chromophore of microbial rhodopsins, which captures photons. It isomerizes into the 13-cis form upon photoexcitation. Isomerization of retinal leads to sequential conformational changes in the protein, giving rise to active states that exhibit biological functions. Despite the rapidly expanding diversity of microbial rhodopsin functions, the photochemical behaviors of retinal were considered to be common among them. However, the retinal of many recently discovered rhodopsins was found to exhibit new photochemical characteristics, such as highly red-shifted absorption, isomerization to 7-cis and 11-cis forms, and energy transfer from a secondary carotenoid chromophore to the retinal, which is markedly different from that established in canonical microbial rhodopsins. Here, I review new aspects of retinal found in novel microbial rhodopsins and highlight the emerging problems that need to be addressed to understand noncanonical retinal photochemistry.

Solid-state NMR for the characterization of retinal chromophore and Schiff base in TAT rhodopsin embedded in membranes under weakly acidic conditions

TAT rhodopsin extracted from the marine bacterium SAR11 HIMB114 has a characteristic Thr-Ala-Thr motif and contains both protonated and deprotonated states of Schiff base at physiological pH conditions due to the low pKa. Here, using solid-state NMR spectroscopy, we investigated the 13C and 15N NMR signals of retinal in only the protonated state of TAT in the 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine/1-palmitoyl-2-oleoyl-sn-glycero-3-phospho (1'-rac-glycerol) (POPE/POPG) membrane at weakly acidic conditions. In the 13C NMR spectrum of 13C retinal-labeled TAT rhodopsin, the isolated 14-13C signals of 13-trans/15-anti and 13-cis/15-syn isomers were observed at a ratio of 7:3. 15N retinal protonated Schiff base (RPSB) had a significantly higher magnetic field resonance at 160 ppm. In 15N RPSB/λmax analysis, the plot of TAT largely deviated from the trend based on the retinylidene-halide model compounds and microbial rhodopsins. Our findings indicate that the RPSB of TAT forms a very weak interaction with the counterion.

Mechanism of the Irreversible Transition from Pentamer to Monomer at pH 2 in a Blue Proteorhodopsin

Proteorhodopsin (PR) is a light-driven proton pump found in marine bacteria, and thousands of PRs are classified as blue-absorbing PRs (BPR; λ_max ∼ 490 nm) and green-absorbing PRs (GPR; λ_max ∼ 525 nm). We previously converted BPR into GPR using an anomalous pH effect, which was achieved by an irreversible process at around pH 2. Recent size-exclusion chromatography (SEC) and atomic force microscopy (AFM) analyses of BPR from Vibrio califitulae (VcBPR) revealed the anomalous pH effect owing to the irreversible transition from pentamer to monomer. Different pK_a values of the Schiff base counterion between pentamer and monomer lead to different colors at the same pH. Here, we incorporate systematic mutation into VcBPR and examine the anomalous pH effect. The anomalous pH effect was observed for the mutants of key residues near the retinal chromophore such as D76N, D206N, and Q84L, indicating that the Schiff base counterions and the L/Q switch do not affect the irreversible transition from pentamer to monomer at pH ∼ 2. We then focus on the two specific interactions at the intermonomer interface in a pentamer, E29/R30/D31 and W13/H54. Single mutants such as E29Q, R30A, W13A, and H54A and the wild type (WT) exhibited an anomalous pH effect. In contrast, the anomalous pH effect was lost for E29Q/H54A, R30A/H54A, and W13A/E29Q. Size-exclusion chromatography (SEC) and atomic force microscopy (AFM) measurements showed monomer forms in the original states of the double mutants, being a clear contrast to the pentamer forms of all single mutants in the original states. It was concluded that the pentamer structure of VcBPR was stabilized by an electrostatic interaction in the E29/R30/D31 region and a hydrogen-bonding interaction in the W13/H54 region, which was disrupted at pH 2 and converted into monomers.

Rhodopsins: An Excitingly Versatile Protein Species for Research, Development and Creative Engineering

The first member and eponym of the rhodopsin family was identified in the 1930s as the visual pigment of the rod photoreceptor cell in the animal retina. It was found to be a membrane protein, owing its photosensitivity to the presence of a covalently bound chromophoric group. This group, derived from vitamin A, was appropriately dubbed retinal. In the 1970s a microbial counterpart of this species was discovered in an archaeon, being a membrane protein also harbouring retinal as a chromophore, and named bacteriorhodopsin. Since their discovery a photogenic panorama unfolded, where up to date new members and subspecies with a variety of light-driven functionality have been added to this family. The animal branch, meanwhile categorized as type-2 rhodopsins, turned out to form a large subclass in the superfamily of G protein-coupled receptors and are essential to multiple elements of light-dependent animal sensory physiology. The microbial branch, the type-1 rhodopsins, largely function as light-driven ion pumps or channels, but also contain sensory-active and enzyme-sustaining subspecies. In this review we will follow the development of this exciting membrane protein panorama in a representative number of highlights and will present a prospect of their extraordinary future potential.

Calcium Binding to TAT Rhodopsin

Rhodopsin is a large family of retinal-binding photoreceptive proteins found in animals and microbes. The retinal chromophore is normally positively charged by protonation of the Schiff base linkage, which is stabilized by the negatively charged counterion(s) such as aspartates, glutamates, and chloride ions. In contrast, no cation binding was reported near the retinal chromophore under physiological pH, presumably because of the electrostatic repulsion. Sodium binding takes place in light-driven sodium pumps, but the binding near the retinal chromophore is a transient event. Here, we report Ca²⁺ binding to a wild-type microbial rhodopsin, which is achieved for the neutral retinal chromophore with a deprotonated Schiff base. TAT rhodopsin from marine bacteria contains protonated and deprotonated retinal Schiff bases at physiological pH (pH ∼ 8), which absorb visible and UV light, respectively. We observed that the equilibrium shifted toward the deprotonated state upon increasing Ca²⁺ concentration, and the K_d value was determined to be 0.17 mM. Site-directed mutagenesis study showed that E54 and D227 constitute the binding site of Ca²⁺. ATR-FTIR spectroscopy revealed secondary structural changes upon Ca²⁺ binding to E54 and D227, while they are negatively charged with or without Ca²⁺ binding.

Light-induced difference FTIR spectroscopy of primate blue-sensitive visual pigment at 163 K

Structural studies of color visual pigments lag far behind those of rhodopsin for scotopic vision. Using difference FTIR spectroscopy at 77 K, we report the first structural data of three primate color visual pig­ments, monkey red (MR), green (MG), and blue (MB), where the batho-intermediate (Batho) exhibits photo­equilibrium with the unphotolyzed state. This photo­chromic property is highly advantageous for limited samples since the signal-to-noise ratio is improved, but may not be applicable to late intermediates, because of large structural changes to proteins. Here we report the photochromic property of MB at 163 K, where the BL intermediate, formed by the relaxation of Batho, is in photoequilibrium with the initial MB state. A comparison of the difference FTIR spectra at 77 and 163 K provided information on what happens in the process of transition from Batho to BL in MB. The coupled C₁₁=C₁₂ HOOP vibration in the planer structure in MB is decoupled by distortion in Batho after retinal photoisomerization, but returns to the coupled C₁₁=C₁₂ HOOP vibration in the all-trans chromophore in BL. The Batho formation accompanies helical structural perturbation, which is relaxed in BL. Protein-bound water molecules that form an extended water cluster near the retinal chromophore change hydrogen bonds differently for Batho and BL, being stronger in the latter than in the initial state. In addition to structural dynamics, the present FTIR spectra show no signals of protonated carboxylic acids at 77 and 163 K, suggesting that E181 is deprotonated in MB, Batho and BL.

Role of Thr82 for the unique photochemistry of TAT rhodopsin

Marine bacterial TAT rhodopsin possesses the pKa of the retinal Schiff base, the chromophore, at neutral pH, and photoexcitation of the visible protonated state forms the isomerized 13-cis state, but reverts to the original state within 10^–5 sec. To understand the origin of these unique molecular properties of TAT rhodopsin, we mutated Thr82 into Asp, because many microbial rhodopsins contain Asp at the corresponding position as the Schiff base counterion. A pH titration study revealed that the pKa of the Schiff base increased considerably in T82D (>10.5), and that the pKa of the counterion, which is likely to be D82, is 8.1. It was thus concluded that T82 is the origin of the neutral pKa of the Schiff base in TAT rhodopsin. The photocycle of T82D TAT rhodopsin exhibited strong pH dependence. When pH is lower than the pKa of the counterion (pH <8.1), formation of the primary K intermediate was observed by low-temperature UV-visible spectroscopy, but flash photolysis failed to monitor photointermdiates at >10^–5 sec. The results were identical for the wild-type TAT rhodopsin. In contrast, when pH was higher than the pKa of the counterion, we observed the formation of the M intermediate, which decayed with the time constants of 3.75 ms and 12.2 sec. It is likely that the protonation state of D82 dramatically switches the photoreaction dynamics of T82D, whose duration lies between <10^–5 sec and >10 sec. It was thus concluded that T82 is one of the determinants of the unique photochemistry of TAT rhodopsin.

TAT Rhodopsin Is an Ultraviolet-Dependent Environmental pH Sensor

In many rhodopsins, the retinal Schiff base pKa remains very high, ensuring Schiff base protonation captures visible light. Nevertheless, recently we found that TAT rhodopsin contains protonated and unprotonated forms at physiological pH. The protonated form displays a unique photochemical behavior in which the primary K intermediate returns to the original state within 10-5 s, and the lack of photocycle completion poses questions about the functional role of TAT rhodopsin. Here we studied the molecular properties of the protonated and unprotonated forms of the Schiff base in TAT rhodopsin. We confirmed no photointermediate formation at >10-5 s for the protonated form of TAT rhodopsin in microenvironments such as detergents, nanodiscs, and liposomes. In contrast, the unprotonated form features a very long photocycle with a time constant of 15 s. A low-temperature study revealed that the primary reaction of the unprotonated form is all-trans to 13-cis photoisomerization, which is usual, but with a proton transfer reaction occurring at 77 K, which is unusual. The active intermediate contains the unprotonated Schiff base as well as the resting state. Electrophysiological measurements excluded ion-transport activity for TAT rhodopsin, while transient outward proton movement only at an alkaline extracellular pH indicates that TAT rhodopsin senses the extracellular pH. On the basis of the findings presented here, we propose that TAT rhodopsin is an ultraviolet (UV)-dependent environmental pH sensor in marine bacteria. At acidic pH, absorbed visible light energy is quickly dissipated into heat without any function. In contrast, when the environmental pH becomes high, absorption of UV/blue light yields formation of the long-lived intermediates, possibly driving the signal transduction cascade in marine bacteria.