Wild-type bR Research Articles

Single molecule kinetics of bacteriorhodopsin by HS-AFM

Bacteriorhodopsin (bR) is a seven-helix light-driven proton-pump that has been extensively studied structurally and functionally. However, the single molecule kinetics of the reaction cycle remain unknown. Here, we use HS-AFM methods to characterize the single molecule kinetics of wild-type bR exposed to continuous light and short light pulses. We monitored bR conformational changes with millisecond temporal resolution and determined that the cytoplasmic gate opens 2.9ms after photon absorption, and stays open for proton capture for 13.2 ms.

Single molecule kinetics of bacteriorhodopsin by HS-AFM

Bacteriorhodopsin is a seven-helix light-driven proton-pump that was structurally and functionally extensively studied. Despite a wealth of data, the single molecule kinetics of the reaction cycle remain unknown. Here, we use high-speed atomic force microscopy methods to characterize the single molecule kinetics of wild-type bR exposed to continuous light and short pulses. Monitoring bR conformational changes with millisecond temporal resolution, we determine that the cytoplasmic gate opens 2.9 ms after photon absorption, and stays open for proton capture for 13.2 ms. Surprisingly, a previously active protomer cannot be reactivated for another 37.6 ms, even under excess continuous light, giving a single molecule reaction cycle of ~20 s−1. The reaction cycle slows at low light where the closed state is prolonged, and at basic or acidic pH where the open state is extended.

TceSR two-component regulatory system of Brucella melitensis 16M is involved in invasion, intracellular survival and regulated cytotoxicity for macrophages.

The mechanisms of invasion and intracellular survival of Brucella are still poorly understood. Previous studies showed that the two-component regulatory systems (TCSs) play an important role in the intracellular survival of Brucella. To investigate if TCSs involve in the virulence and cytotoxicity of Brucella melitensis, we introduced a mutation into one of the TCSs in chromosome II in Br. melitensis 16M strain, and generated 16MΔTceSR, a mutant of Br. melitensis 16M strain. In vitro infection experiments using murine macrophage cell line (RAW 264.7) showed that the survival of 16MΔTceSR mutant in macrophages decreased 0·91-log compared with that of wild type Br. melitensis 16M strain at 2 h postinfection, replication of 16MΔTceSR mutant in macrophages was 5·65-log, which was much lower than that wild type strain. Results of lactate dehydrogenase cytotoxicity assays in macrophages demonstrated high dose infection with wide type strain produced high level cytotoxicity to macrophages, but 16MΔTceSR mutant had very low level cytotoxicity, indicating mutation of TCSs impaired the cytotoxicity of Br. melitensis to macrophages. Animal experiments showed that the spleen colonization of 16MΔTceSR was significantly reduced compared with its wild type strains. The lower levels of survival of 16MΔTceSR in various stress conditions suggested that the mutation of the TCSs of Br. melitensis was the causative factor of its reduced resistance to stress conditions. Taken together, our results demonstrated TCS TceSR involves in the intracellular survival, virulence and cytotoxicity of Br. melitensis during its infection. Significance and impact of the study: Two-component systems (TCSs) are predominant bacterial signal transduction mechanisms. The pathogenicity of Brucella is due to its ability to adapt to the intracellular environment including low levels of acidic pH, high-salt and heat shock. TCSs are designed to sense diverse stimuli, transfer signals and enact an appropriate adaptive physiological response. Here, we show that Br. meilitensis TCS TceSR is not only involved in regulation of Br. meilitensis virulence and adaptation of environmental stresses, but also can regulate cytotoxicity in macrophages.

Light-controlled spin filtering in bacteriorhodopsin.

The role of the electron spin in chemistry and biology has received much attention recently owing to to the possible electromagnetic field effects on living organisms and the prospect of using molecules in the emerging field of spintronics. Recently the chiral-induced spin selectivity effect was observed by electron transmission through organic molecules. In the present study, we demonstrated the ability to control the spin filtering of electrons by light transmitted through purple membranes containing bacteriorhodopsin (bR) and its D96N mutant. The spin-dependent electrochemical cyclic voltammetry (CV) and chronoamperometric measurements were performed with the membranes deposited on nickel substrates. High spin-dependent electron transmission through the membranes was observed; however, after the samples were illuminated by 532 nm light, the spin filtering in the D96N mutant was dramatically reduced whereas the light did not have any effect on the wild-type bR. Beyond demonstrating spin-dependent electron transmission, this work also provides an interesting insight into the relationship between the structure of proteins and spin filtering by conducting electrons.

Full-Quantum chemical calculation of the absorption maximum of bacteriorhodopsin: a comprehensive analysis of the amino acid residues contributing to the opsin shift.

Herein, the absorption maximum of bacteriorhodopsin (bR) is calculated using our recently developed method in which the whole protein can be treated quantum mechanically at the level of INDO/S-CIS//ONIOM (B3LYP/6-31G(d,p): AMBER). The full quantum mechanical calculation is shown to reproduce the so-called opsin shift of bR with an error of less than 0.04 eV. We also apply the same calculation for 226 different bR mutants, each of which was constructed by replacing any one of the amino acid residues of the wild-type bR with Gly. This substitution makes it possible to elucidate the extent to which each amino acid contributes to the opsin shift and to estimate the inter-residue synergistic effect. It was found that one of the most important contributions to the opsin shift is the electron transfer from Tyr185 to the chromophore upon excitation. We also indicate that some aromatic (Trp86, Trp182) and polar (Ser141, Thr142) residues, located in the vicinity of the retinal polyene chain and the β-ionone ring, respectively, play an important role in compensating for the large blue-shift induced by both the counterion residues (Asp85, Asp212) and an internal water molecule (W402) located near the Schiff base linkage. In particular, the effect of Trp86 is comparable to that of Tyr185. In addition, Ser141 and Thr142 were found to contribute to an increase in the dipole moment of bR in the excited state. Finally, we provide a complete energy diagram for the opsin shift together with the contribution of the chromophore-protein steric interaction.

Ultrafast photo-induced reaction dynamics in bacteriorhodopsin and its Trp mutants

This review paper presents the recent advances made in observing and understanding theultrafast photo-reaction dynamics in retinal proteins, in particular bacteriorhodopsin (bR),with a special emphasis on the retinal–protein interactions and the mechanisms of proteinactivation on a sub-picosecond timescale.We review our latest results obtained on wild-type (wt) bR, and on two tryptophanmutants W86F and W182F, obtained by femtosecond pump–probe experiments. It wasshown that light-induced charge translocations and modifications of the proteinelectrostatics can be monitored by the near-UV differential absorption of Trp86, whichexperiences a linear intra-protein Stark effect. In the same spectral region, non-exponentialwavepacket-like dynamics was found for the formation of the 13-cis retinal isomer in wt-bR.The present paper highlights how this finding is underpinned by the experiments on themutants.New results are presented regarding the reaction dynamics in the Trp mutants, studied inthe vis/near-IR by transient absorption. Interestingly, W86F displays a faster excited statedecay and photoproduct formation than wt-bR. This is tentatively attributed to anall-trans/13-cis ground state mixture known to occur in the light-adapted state in thisspecial mutant, due to increased conformational flexibility of the retinal chromophore.

Bending of purple membranes in dependence on the pH analyzed by AFM and single molecule force spectroscopy

The first AFM images of strongly bent purple membranes as well as the first single molecule force spectra of bacteriorhodopsins embedded therein are presented. AFM images of purple membranes to date always showed a flat membrane topology. Bacteriorhodopsin variants like BR-D85N and BR-D85T resemble an intermediate state of wild-type BR which is slightly 'wedge'-shaped. Due to the strong interaction within the 2-D crystalline lattice of the purple membrane, the geometrical anisotropy of the individual bacteriorhodopsins adds up to a macroscopic change in the geometry of the purple membranes. Instead of being flat they appear like domes at physiological conditions. Single molecule force spectroscopy was employed to determine the absolute sign of the membrane curvature. As the bacteriorhodopsins in the center of the dome-like purple membranes are not supported by any solid state substrate, the presented force spectra are the first of non-supported bacteriorhodopsin, resembling the natural occurrence in the halobacterial cell.

Suppressed or recovered intensities analysis in site-directed 13C NMR: Assessment of low-frequency fluctuations in bacteriorhodopsin and D85N mutants revisited

The first proton transfer of bacteriorhodopsin (bR) occurs from the protonated Schiff base to the anionic Asp 85 at the central part of the protein in the L to M states. Low-frequency dynamics accompanied by this process can be revealed by suppressed or recovered intensities (SRI) analysis of site-directed 13C solid-state NMR spectra of 2D crystalline preparations. First of all, we examined a relationship of fluctuation frequencies available from [1- 13C]Val- and [3- 13C]Ala-labeled preparations, by taking the effective correlation time of internal methyl rotations into account. We analyzed the SRI data of [1- 13C]Val-labeled wild-type bR and D85N mutants, as a function of temperature and pH, respectively, based on so-far assigned peaks including newly assigned or revised ones. Global conformational change of the protein backbone, caused by neutralization of the anionic D85 by D85N, can be visualized by characteristic displacement of peaks due to the conformation-dependent 13C chemical shifts. Concomitant dynamics changes if any, with fluctuation frequencies in the order of 10 4 Hz, were evaluated by the decreased peak intensities in the B–C and D–E loops of D85N mutant. The resulting fluctuation frequencies, owing to subsequent, accelerated dynamics changes in the M-like state by deprotonation of the Schiff base at alkaline pH, were successfully evaluated based on the SRI plots as a function of pH, which were varied depending upon the extent of interference of induced fluctuation frequency with frequency of magic angle spinning or escape from such interference. Distinguishing fluctuation frequencies between the higher and lower than 10 4 Hz is now possible, instead of a simple description of the data around 10 4 Hz available from one-point data analysis previously reported.

Study on the Feasibility of Bacteriorhodopsin as Bio-Photosensitizer in Excitonic Solar Cell: A First Report

Bacteriorhodopsin (bR) is a membrane protein found in the archae Halobacterium salinarum. Here, we studied wild type bR and especially the triple mutant bR, 3Glu [E9Q/E194Q/E204Q], in combination with wide gap semiconductor TiO2 for their suitability as efficient light harvester in solar cell. Our differential scanning calorimetry data show thermal robustness of bR wild type and 3Glu mutant, which make them good candidates as photosensitizer in solar cells. Molecular modeling indicates that binding of bR to the exposed oxygen atoms of anatase TiO2 is favorable for electron transfer and directed by local, small distance interactions. A solar cell, based on bR wild type and bR triple mutant immobilized on nanocrystalline TiO2 film was successfully constructed. The photocurrent density-photo voltage (J-V) characteristics of bio-sensitized solar cell (BSSC), based on the wild type bR and 3Glu mutant adsorbed on nanocrystalline TiO2 film electrode were measured. The results show that the 3Glu mutant displays better photoelectric performance compared to the wild type bR, giving a short-circuit photocurrent density (J(sc)) of 0.09 mA/cm2 and the open-circuit photovoltage (V(oc)) 0.35 V, under an illumination intensity of 40 mW/cm2.

Participation of the BC Loop in the Correct Folding of Bacteriorhodopsin as Revealed by Solid‐state NMR†

Structural changes in bacteriorhodopsin (bR) in two different processes of retinal reconstitutions were investigated by observing the (13)C and (15)N solid-state NMR spectra of [1-(13)C]Val- and [(15)N]Pro-labeled bR. We found that NMR signals of the BC loop were sensitive to changes in protein structure and dynamics, from wild-type (WT) bR to bacterio-opsin (bO), regenerated bR and E1001 bR. Regenerated bR was prepared following the addition of retinal into bO obtained from photobleached WT-bR. E1001 bR was cultured from a retinal-deficient strain termed E1001 following the addition of retinal to growing cells. (15)N NMR signal at Pro70 in the BC loop in WT-bR was observed at 122.4 p.p.m., whereas signals were not apparent or partly suppressed in bO and regenerated bR, respectively. Similarly, the (13)C NMR signal at Val69 in the BC loop at 172.0 p.p.m. that was observed in WT-bR was significantly decreased in both regenerated bR and bO. These results suggest that the dynamic structure of the BC loop in bO was substantially altered following the removal of retinal. As a consequence, the correct protein structure failed to be recovered via the regenerating process of retinal to bO. On the other hand, (13)C and (15)N NMR signals at the BC loop in E1001 bR appeared at positions identical to those of WT-bR. The results of the current study indicate that the BC loop may not always fold correctly in the regenerated bR, which leads to different properties in the regenerated bR compared to that of WT-bR.

Evaluation of Blue and Green Absorbing Proteorhodopsins as Holographic Materials

Transient holographic diffraction is observed for the green (GPR) and blue (BPR) absorbing proteorhodopsins (BAC31A8 and HOT75M1, respectively), as well as the GPR E108Q and BPR E110Q variants. In contrast to bacteriorhodopsin, where the metastable bR-M pair is responsible for generating diffraction, the pR and red-shifted N-like states fulfill that role in both the green and blue wild-type proteorhodopsins. The GPR E108Q and BPR E110Q variants, however, behave more similarly to their bacteriorhodopsin analogue, D96N, with diffraction arising from the PR M-state (strongly enhanced in both GPR E108Q and BPR E110Q). Of the four proteins evaluated, wild type (WT) GPR and GPR E108Q produce the highest diffraction efficiencies, etamax, at approximately 1% for a 1.7 OD sample. GPR E108Q, however, requires 1-2 orders of magnitude less laser intensity to generate eta equivalent to WT GPR and BR D96N under similar conditions (as compared to literature values). WT BPR requires lower actinic powers than GPR but diffracts only about 30% as well. BPR E110Q performs the most poorly of the four, with etamax < 0.05% for a 1.4 OD film. The Kramers-Kronig transformation and Koglenik's coupled wave theory were used to predict the dispersion spectra and diffraction efficiency for the long M-state variants. To a first approximation, the gratings formed by all samples decay upon discontinuing the 520 nm actinic beams with a time constant characteristic of the appropriate intermediate: the N-like state for WT GPR and BPR and the M-state for GPR 108Q and BPR E110Q.

The photochemical reaction cycle of retinal reconstituted bacteriorhodopsin

The function of three types of bacteriorhodopsins was compared: the wild-type, the bleached and retinal reconstituted and retinal deficient bacteriorhodopsin after retinal addition. The apparent p K a of the proton acceptor group for the bleached BR and retinal deficient BR shifted toward higher pH values compared to the wild-type BR. Fitting the photocycle model to the absorption kinetic signals for all three proteins showed the existence of the same intermediates, but the time-dependent concentration of the intermediates was different. Although measurements were made at pH 7, the absorption kinetics and photoelectric signals in both retinal reconstituted samples acted as wild-type bacteriorhodopsin at significantly higher pH. Below pH 3 the retinal deficient and reconstituted sample bleached. These results suggested that the added retinal was not able to rebind in the same position in the protein as in native bacteriorhodopsin. This points out that care should be taken, when bleached bacteriorhodopsin is reconstituted with different retinal analogs.

Membrane-protein stability in a phospholipid-based crystallization medium

Protein stability is a crucial factor to consider when attempting to crystallize integral membrane proteins. Cubic phase, or in meso, lipid-bilayer crystallization media are thought to provide native-like environments that should facilitate membrane protein crystallization by helping to stabilize the native protein conformation for the duration of the crystallization process. While excellent crystals of bacteriorhodopsin (bR) and other Halobacterial rhodopsins have been obtained in lipid-bilayer gels formed with monoglycerides, success remains elusive in the general application of such media to other membrane proteins. Additionally, we have noted that some mutants of bR are highly unstable in gels formed with monoolein. Phosphatidylethanolamines (PE) and derivatives of PE represent another class of lipids that can form connected-bilayer gels. When wildtype bR and a labile bR mutant were reconstituted into this phospholipid gel, spectroscopy showed that the protein is both more stable and has improved conformational homogeneity as compared to gels formed using monoolein. In addition, we demonstrate that well-diffracting crystals of bR can be grown from a PE-based crystallization medium. Since most proteins lack a stability-indicating chromophore and other structure-based analytical techniques are poorly compatible with the lipid gel, we developed a generally-applicable spectroscopic technique based on the intrinsic fluorescence of tryptophan residues. This fluorescence assay makes possible the rapid evaluation of lipid gels as media for the crystallization of membrane proteins.

Importance of Specific Hydrogen Bonds of Archaeal Rhodopsins for the Binding to the Transducer Protein

Four rhodopsins, bacteriorhodopsin (bR), halorhodopsin (hR), sensory rhodopsin (sR) and phoborhodopsin (pR) exist in archaeal membranes. bR and hR work as a light-driven ion pump. sR and pR work as a photo-sensor of phototaxis, and form signaling complexes in membranes with their respective cognate transducer proteins HtrI (with sR) and HtrII (with pR), through which light signals are transmitted to the cytoplasm. What is the determining factor(s) of the specific binding to form the complex? Binding of the wild-type or mutated rhodopsins with HtrII was measured by isothermal titration calorimetric analysis (ITC). bR and hR could not bind with HtrII. On the other hand, sR could bind to HtrII, although the dissociation constant (K(D)) was about 100 times larger than that of pR. An X-ray crystallographic structure of the pR/HtrII complex revealed formation of two specific hydrogen bonds whose pairs are Tyr199(pR)/Asn74(HtrII) and Thr189(pR)/Glu43(HtrII)/Ser62(HtrII). To investigate the importance of these hydrogen bonds, the K(D) value for the binding of various mutants of bR, hR, sR and pR with HtrII was estimated by ITC. The K(D) value of T189V(pR)/Y199F(pR), double mutant/HtrII complex, was about 100-fold larger than that of the wild-type pR, whose K(D) value was 0.16 microM. On the other hand, bR and hR double mutants, P200T(bR)/V210Y(bR) and P240T(hR)/F250Y(hR), were able to bind with HtrII. The K(D) value of these complexes was estimated to be 60.1(+/-10.7) microM for bR and to be 29.1(+/-6.1) microM for hR, while the wild-type bR and hR did not bind with HtrII. We concluded that these two specific hydrogen bonds play important roles in the binding between the rhodopsins and transducer protein.

Lack of Ghrelin Secretion in Response to Fasting in Cholecystokinin-A (-1), -B (-2) Receptor–Deficient Mice

Cholecystokinin receptors (CCK-Rs) have been classified into two subtypes: CCK-AR (1R) and -BR (2R). We generated CCK-AR(-/-), CCK-BR(-/-), and CCK-AR(-/-)BR(-/-) mice and found that the gastric emptying of a liquid meal was increased in CCK-BR(-/-) and AR(-/-)BR(-/-) mice, compared with wild-type and CCK-AR(-/-) mice. Given that enhanced gastric emptying leads to eating, food intake after overnight fasting was examined, as was the effect of CCK-8S on food intake. Male mice 6-8 months of age were deprived of food for 16 h with free access to water, after which they were injected intraperitoneally (0.1 ml/mouse) with either vehicle or CCK-8 (0.3, 1.0, or 3.0 nmol/mouse), and their food intake was monitored for 4 h. CCK-8S inhibited food intake in wild-type and CCK-BR(-/-) mice, but not in CCK-AR(-/-) or AR(-/-)BR(-/-) mice. Unexpectedly, we observed a lower food intake in CCK-AR(-/-)BR (-/-) mice treated with vehicle than in mice of the other genotypes. To examine the mechanism of decrease in food intake in CCK-AR(-/-)BR(-/-) mice, the involvement of ghrelin was determined in wild-type and CCK-AR(-/-)BR(-/-) mice. Fasting plasma ghrelin levels were significantly lower in CCK-AR (-/-)BR(-/-) mice than in wild-type mice, and no increase in response to fasting was observed in CCK-AR(-/-)BR(-/-) mice. An administration of acyl-ghrelin produced a small increase in food intake in CCK-AR(-/-)BR(-/-) mice, but not to the levels of wild-type mice. In conclusion, CCK-AR(-/-)BR(-/-) mice showed lower food intake as well as lower response to exogenous ghrelin, and a lower plasma ghrelin level after fasting, though which receptor is more important is unknown.

Photoelectric properties of a detector based on dried bacteriorhodopsin film

The photoelectric response of a detector using dried bacteriorhodopsin (bR) film as the light sensing material is mathematically modeled and experimentally verified in this paper. The photocycle and proton transfer kinetics of dried bR film differ dramatically from the more commonly studied aqueous bR material because of the dehydration process. The photoelectric response of the dried film is generated by charge displacement and recombination instead of transferring a proton from the cytoplasmic side to the extracellular side of the cell membrane. In this work, the wild-type bR samples are electrophoretically deposited onto an indium tin oxide (ITO) electrode to construct a simple multiple layered photo-detector with high sensitivity to small changes in incident illumination. The light absorption characteristics of the thin bR film are mathematically represented using the kinetics of the bR photocycle and the charge displacement theorem. An electrically equivalent RC circuit is used to describe the intrinsic photoelectric properties of the film and external measurement circuitry to analyze the detector's response characteristics. Simulated studies and experimental results show that the resistance of the dried bR film is in the order of 10(11) Omega. When the input impedance of the measurement circuitry is one order of magnitude smaller than the dried film, the detector exhibits a strong differential response to the original time-varying light signal. An analytical solution of the equivalent circuit also reveals that the resistance and capacitance values exhibited by the dried bR film, in the absence of incident light, are almost twice as large as the values obtained while the material is under direct illumination. Experimental observations and a predictive model both support the notion that dried bR film can be used in simple highly sensitive photo-detector designs.

Ultraviolet protection using intensity-dependent spectral shift in bacteriorhodopsin

The optical absorption properties of biological protein bacteriorhodopsin (bR) under the illumination of different intensity and pH environment were investigated. It is observed that the wild type bR film offers more than 30% effective UV protection. The UV protection effect can be further enhanced to 90% in some specific UV region by genetically or chemically modifying bR molecules or by the illumination of visible wavelengths ranging from green to red wavelengths. Preliminary results indicate that bR could be a promising material for UV protection.

G‐protein‐coupled receptor domain overexpression in Halobacterium salinarum: Long‐range transmembrane interactions in heptahelical membrane proteins

The aminergic alpha(2b)-adrenergic receptor (alpha(2b)-AR) third intracellular loop (alpha(2b)-AR 3i) mediates receptor subcellular compartmentalization and signal transduction processes via ligand-dependent interaction with G(i)- and G(o)- proteins. To understand the structural origins of these processes we engineered several lengths of alpha(2b)-AR 3i into the third intracellular loop of the proton pump bacteriorhodopsin (bR) and produced the fusion proteins in quantities suitable for physical studies. The fusion proteins were expressed in the Archaeon Halobacterium salinarum and purified. A highly expressed fusion protein was crystallized from bicelles and diffracted to low resolution on an in-house diffractometer. The bR-alpha(2b)-AR 3i(203-292) protein possessed a photocycle slightly perturbed from that of the wild-type bR. The first half of the fusion protein photocycle, correlated with proton release, is accelerated by a factor of 3, whereas the second half, correlated with proton uptake, is slightly slower than wild-type bR. In addition, there is a large decrease in the pK(a), (from 9.6 to 8.3) of the terminal proton release group in the unphotolyzed state of bR-alpha(2b)-AR 3i as deduced from the pH-dependence of the M-formation. Perturbation of a cytoplasmic loop has thus resulted in the perturbation of proton release at the extracellular surface. The current work indicates that long-range and highly coupled intramolecular interactions exist that are capable of "transducing" structural perturbations (e.g., signals) across the cellular membrane. This gene fusion approach may have general applicability for physical studies of G-protein-coupled receptor domains in the context of the bR structural scaffold.

Proton binding within a membrane protein by a protonated water cluster

Proton transfer is crucial for many enzyme reactions. Here, we show that in addition to protonatable amino acid side chains, water networks could constitute proton-binding sites in proteins. A broad IR continuum absorbance change during the proton pumping photocycle of bacteriorhodopsin (bR) indicates most likely deprotonation of a protonated water cluster at the proton release site close to the surface. We investigate the influence of several mutations on the proton release network and the continuum change, to gain information about the location and extent of the protonated water network and to reveal the participating residues necessary for its stabilization. We identify a protonated water cluster consisting in total of one proton and about five water molecules surrounded by six side chains and three backbone groups (Tyr-57, Arg-82, Tyr-83, Glu-204, Glu-194, Ser-193, Pro-77, Tyr-79, and Thr-205). The observed perturbation of proton release by many single-residue mutations is now explained by the influence of numerous side chains on the protonated H bonded network. In situ hydrogen/deuterium exchange Fourier transform IR measurements of the bR ground state, show that the proton of the release group becomes localized on Glu-204 and Asp-204 in the ground state of the mutants E194D and E204D, respectively, even though it is delocalized in the ground state of wild-type bR. Thus, the release mechanism switches between the wild-type and mutated proteins from a delocalized to a localized proton-binding site.

The Assignment of the Different Infrared Continuum Absorbance Changes Observed in the 3000–1800-cm −1 Region during the Bacteriorhodopsin Photocycle

The bleach continuum in the 1900–1800-cm −1 region was reported during the photocycle of bacteriorhodopsin (bR) and was assigned to the dissociation of a polarizable proton chain during the proton release step. More recently, a broad band pass filter was used and additional infrared continua have been reported: a bleach at >2700 cm −1, a bleach in the 2500–2150-cm −1 region, and an absorptive behavior in the 2100–1800-cm −1 region. To fully understand the importance of the hydrogen-bonded chains in the mechanism of the proton transport in bR, a detailed study is carried out here. Comparisons are made between the time-resolved Fourier transform infrared spectroscopy experiments on wild-type bR and its E204Q mutant (which has no early proton release), and between the changes in the continua observed in thermally or photothermally heated water (using visible light-absorbing dye) and those observed during the photocycle. The results strongly suggest that, except for the weak bleach in the 1900–1800-cm −1 region and >2500 cm −1, there are other infrared continua observed during the bR photocycle, which are inseparable from the changes in the absorption of the solvent water molecules that are photothermally excited via the nonradiative relaxation of the photoexcited retinal chromophore. A possible structure of the hydrogen-bonded system, giving rise to the observed bleach in the 1900–1800-cm −1 region and the role of the polarizable proton in the proton transport is discussed.