Absorption spectral properties of purified halorhodopsin

The photochemical cycle of halorhodopsin: absolute spectra of intermediates obtained by flash photolysis and fast difference spectra measurements

Results of experiments using flash photolysis and fast difference spectroscopy suggest an extended version of the earlier published scheme of the photochemical cycle of halorhodopsin. Detailed experimental verification of the suggested photocycle is given. Due to the high resolution of the time-resolved difference spectra, absolute spectra of the intermediates in the photocycle were derived, allowing the interpretation of complex kinetic absorbance changes.

Role of Putative Anion-Binding Sites in Cytoplasmic and Extracellular Channels ofNatronomonas pharaonisHalorhodopsin†

Natronomonas (Natronobacterium) pharaonis halorhodopsin (NpHR) is an inward light-driven Cl(-) ion pump. For efficient Cl(-) transport, the existence of Cl(-)-binding or -interacting sites in both extracellular (EC) and cytoplasmic (CP) channels is postulated. Candidates include Arg123 and Thr126 in EC channels and Lys215 and Thr218 in CP channels. The roles played by these amino acid residues in anion binding and in the photocycle have been investigated by mutation of the amino acid residues at these positions. Anion binding was assayed by changes in circular dichroism and the shift in the absorption maximum upon addition of Cl(-) to anion-free NpHR. The binding affinity was affected in mutants in which certain EC residues had been replaced; this finding revealed the importance of Arg123. On the other hand, mutants in which certain residues in the CP channel were replaced (CP mutants) did not show changes in their dissociation constants. The photocycles of these mutants were also examined, and in the case of the EC mutants, the transition to the last step was greatly delayed; on the other hand, in the CP mutants, L2-photointermediate decay was significantly prolonged, except in the case of K215Q, which lacked the O-photointermediate. The importance of Thr218 for binding of Cl(-) to the CP channel was indicated by these results. On the basis of these observations, the possible anion transport mechanism of NpHR was discussed.

Stopped-flow analysis on anion binding to blue-form halorhodopsin from Natronobacterium pharaonis: comparison with the anion-uptake process during the photocycle

Pharaonis halorhodopsin (phR), the light-driven chloride ion pump from Natronobacterium pharaonis with C-terminal histidine tag, was expressed in Escherichia coli cells. The protein was solubilized with 0.1% n-dodecyl beta-D-maltopyranoside and purified with a nickel column. Removal of Cl- from the medium yields blue phR (phR(blue)) that has lost Cl- near the chromophore. Addition of Cl- converts phR(blue) to a red-shifted Cl--bound form (phR(Cl)). Circular dichroic spectra of phR(blue) and phR(Cl) exhibited a bilobe in the visual region, indicating specific oligomerization of the phR monomers. The order of anion concentration which induced a shift from phR(blue) to phR(X) was Br- < Cl- < NO3- < N3-, which was the same as in the case of phR purified from N. pharaonis membranes. Chloride binding kinetics was measured by time-resolved absorption changes with stopped-flow rapid mixing. Rates of Cl- binding consisted of fast and slow components, and the amplitude of the fast component was about 90% of the total changes. The rate constant of the fast component at 100 mM NaCl at 25 degrees C was 260 s(-1) with an apparent activation energy of 35 kJ/mol. These values are in good agreement with the process of Cl- uptake in the photocycle (O --> hR' reaction) reported previously [Váró et al. (1995) Biochemistry 34, 14500-14507]. In addition, the Cl- concentration dependence on both rates was similar to each other. These observations suggest that the O-intermediate is similar to phR(blue) and that Cl- uptake during the photocycle may be ruled by a passive process.

Newly isolated archaerhodopsin from a strain of Chinese halobacteria and its proton pumping behavior

A strain of extremely salt-loving halobacteria Halobacterium species xz515 from a salt lake in Tibet was isolated. SDS-polyacrylamide gel electrophoresis shows that there is only one protein on claret membrane, which is the same membrane fraction as purple membrane from Halobacterium salinarum, with a molecular weight close to bacteriorhodopsin (br). The purified retinal containing protein from xz515 has an absorption peak at around 550 nm. These facts indicate that it is a br-like protein. The partial sequence determination [H. Wang et al., Chin. Sci. Bull., 45 (2000)] shows that this br-like protein belongs to the archaerhodopsin family. The measurements of light-induced medium pH change in intact cells and cell envelope vesicles of xz515 suggest that this type of archaerhodopsin has a proton pumping function. However, the study about the dynamics of pumped protons across the membrane reveal that the proton release and proton uptake is in reverse order compared to br. The probable reason, attributing to regulating the rate of proton release is discussed.

Influence exercised by histidine-95 on chloride transport and the photocycle in halorhodopsin

The anion pumping mechanism of halorhodopsin was studied using site-directed mutagenesis. Comparison of the amino acid sequence revealed that the B-C interhelix loop segment was highly homologous in all known halorhodopsins. Especially a basic residue, histidine-95, was conserved in all halorhodopsins. Using the expression-vector plasmid carrying the bop promoter, two His-95 mutants (H95R, H95A) were successfully expressed in Halobacterium salinarium. The expression levels of these halorhodopsin mutants were slightly lower than that for the wild-type halorhodopsin. In addition, these mutants were unstable under illumination compared with the wild-type. It suggested that His-95 is probably important for stabilizing the structure of halorhodopsin. The absorption maxima of these mutants are approximately 15 nm blue-shifted compared with the wild-type, suggesting that His-95 interacts with the retinal Schiff base. At low chloride concentrations, the light-induced chloride pumping activity of these mutants was more than 20 times lower than that for the wild-type. Only under physiological conditions, the chloride pumping activity was detected. Even at a high chloride concentration (1 M NaCl), the HR520 intermediate could not be detected for these mutants. These results clearly indicate that His-95 has a crucial role in the chloride transport of halorhodopsin.

Over-expression of a new photo-active halorhodopsin in Halobacterium salinarium

The gene of haloopsin (hop) from halobacterial strain shark was cloned and its nucleotide sequence was determined. The deduced amino acid sequence of shark halorhodopsin (HR) showed that its homology with halobium HR was 62%. The gene product seems to be HR having several positively charged residues that are conserved in all known HRs. The gene encoding shark hop as well as that encoding halobium hop were successfully expressed in Halobacterium salinarium (halobium) by using a plasmid shuttle vector containing the bacterioopsin (bop) promoter. The expression level of shark HR is almost the same as that for halobium HR with the same shuttle vector containing the bop promoter. Under the physiological conditions, the anion pumping activity of the shark HR expressed in H. salinarium was almost the same as that for halobium HR; however, the anion selectivity and half-maximal anion transport were different. Furthermore, its absorption maximum in the absence of chloride shifted to approx. 596 nm in contrast to that for halobium HR. The half-lifetimes of HR520 formation for shark HR and halobium HR were almost the same; however, the half-lifetime of its decay was approx. 6-times faster for shark HR than it was for halobium HR at a high chloride concentration (1000 mM). Even at a low chloride concentration (50 mM), HR520 and HR640 intermediates could be detected for shark HR, and the half-lifetime of HR640 decay was found to be approx. 25 ms. In the presence of nitrate, the half-lifetime of HR565 recovery for shark HR was approx. 10-times slower than that for halobium HR. Some of amino acid substitutions between shark HR and halobium HR may affect the anion selectivity and the photoreaction of HR.

Conversion of bacteriorhodopsin into a chloride ion pump

In the light-driven proton pump bacteriorhodopsin, proton transfer from the retinal Schiff base to aspartate-85 is the crucial reaction of the transport cycle. In halorhodopsin, a light-driven chloride ion pump, the equivalent of residue 85 is threonine. When aspartate-85 was replaced with threonine, the mutated bacteriorhodopsin became a chloride ion pump when expressed in Halobacterium salinarium and, like halorhodopsin, actively transported chloride ions in the direction opposite from the proton pump. Chloride was bound to it, as revealed by large shifts of the absorption maximum of the chromophore, and its photointermediates included a red-shifted state in the millisecond time domain, with its amplitude and decay rate dependent on chloride concentration. Bacteriorhodopsin and halorhodopsin thus share a common transport mechanism, and the interaction of residue 85 with the retinal Schiff base determines the ionic specificity.

Photocycle of halorhodopsin from Halobacterium salinarium

The light-driven chloride pump, halorhodopsin, is a mixture containing all-trans and 13-cis retinal chromophores under both light and dark-adapted conditions and can exist in chloride-free and chloride-binding forms. To describe the photochemical cycle of the all-trans, chloride-binding state that is associated with the transport, and thereby initiate study of the chloride translocation mechanism, one must first dissect the contributions of these species to the measured spectral changes. We resolved the multiple photochemical reactions by determining flash-induced difference spectra and photocycle kinetics in halorhodopsin-containing membranes prepared from Halobacterium salinarium, with light- and dark-adapted samples at various chloride concentrations. The high expression of cloned halorhodopsin made it possible to do these measurements with unfractionated cell envelope membranes in which the chromophore is photostable not only in the presence of NaCl but also in the Na2SO4 solution used for reference. Careful examination of the flash-induced changes at selected wavelengths allowed separating the spectral changes into components and assigning them to the individual photocycles. According to the results, a substantial revision of the photocycle model for H. salinarium halorhodopsin, and its dependence on chloride, is required. The cycle of the all-trans chloride-binding form is described by the scheme, HR-hv-->K<==>L1<==>L2<==>N-->HR, where HR, K, L, and N designate halorhodopsin and its photointermediates. Unlike the earlier models, this is very similar to the photoreaction of bacteriorhodopsin when deprotonation of the Schiff base is prevented (e.g., at low pH or in the D85N mutant). Also unlike in the earlier models, no step in this photocycle was noticeably affected when the chloride concentration was varied between 20 mM and 2 M in an attempt to identify a chloride-binding reaction.

Artificial pigments of halorhodopsin and their chloride pumping activities

Halorhodopsin (HR), the light-driven chloride pump of Halobacterium halobium, was bleached with hydroxylamine and regenerated with all-trans-retinal under several different conditions. The largest recovery of the pigment was found with apoprotein obtained from detergent-free HR [HR(BB)]. To compare the chloride-pumping mechanism of HR with that of bacteriorhodopsin (BR; the light-driven proton pump of the same bacteria), HR pigment analogues were reconstituted with the bleached HR (BB) and retinal analogues. The corresponding BR pigment analogues have previously been shown to have little or no proton-pumping activity, except for retinal2 (3,4-dehydroretinal). Pigment analogues with 13-demethylretinal or retinal2 showed an "opsin shift" similar to that of the all-trans-retinal pigment of both HR and BR. Opsin shifts of the pigments of 9-12-phenylretinal and 3,7-dimethyl-2,4,6,8-decatetraenal and haloopsin are slightly different from those of the corresponding BR pigment analogues, presumably reflecting differences of the chromophoric structures in HR and BR. In addition to the spectral properties, the effect of chloride ion on deprotonation of the Schiff base was measured. These pigment analogues showed the "chloride effect" (a shift of the pK value for deprotonation of the Schiff base), but a smaller one than that seen in HR. For a measurement of the chloride-pumping activity, each retinal analogue was added to a culture of L07 cells (BOP-, HOP+, Ret-), and the activity was measured with the cell suspension. Only cultures with retinal or retinal2 showed chloride-pumping activity, as is true for proton pumping by BR. This suggests that a similar retinal-protein interaction is necessary for both ion pumps.

Low-temperature photoreactions of halorhodopsin. 1. Detection of conformational substates of the chromoprotein

Absorption spectra of halorhodopsin (HR), a retinal protein in the halobacterial membrane, and its photostationary states were determined at 80 K. The absorption lines appear to narrow upon cooling, thereby revealing complex spectral fine structure of the main absorption band in the visible region, characteristic of conformational substates of HR. Illumination causes (1) the redistribution of these substrates and consequent changing of the fine structure ("hole-burning") and (2) the appearance of a hypsoproduct of undefined nature, in addition to the previously described bathoproduct HR600. Bacteriorhodopsin, a related retinal pigment, gives rise only to the bathointermediate (i.e., K590) under these conditions. After warming of illuminated HR to 110 K, and recooling to 80 K, relaxation of the illumination-induced change in spectral fine structure, and decay of the hypsoproduct but not the bathoproduct, was observed. The results are explained with a model in which one ensemble of HR conformational substates at 80 K is converted to another in a photoequilibrium via the excited state, which also produces the batho- and hypsoproducts. The original ensemble can be regained through thermal pathways at a somewhat higher temperature, and only the bathoproduct will decay thermally into the next intermediate of the HR photocycle.

Photosensory behavior in procaryotes

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Mechanism of base-catalyzed Schiff base deprotonation in halorhodopsin

It has been shown earlier that the deprotonation of the Schiff base of illuminated halorhodopsin proceeds with a much lower pKa than that of the unilluminated pigment and the reversible protonation change is catalyzed by azide and cyanate [Hegemann, P., Oesterhelt, D., & Steiner, M. (1985) EMBO J. 4, 2347-2350]. We have studied the kinetics of the proton-transfer events with flash spectroscopy and compared a variety of anionic bases with different pKa with regard to their apparent binding constants and their catalytic activities. The results suggest a general base catalysis mechanism in which the anionic bases bind with apparently low affinity to halorhodopsin, although with some degree of size- and/or shape-dependent specificity. The locus of the catalysis is accessible from the cytoplasmic side of the membrane and is not at site I, where various anions bind and shift the pKa of the deprotonation. Neither is it at site II, where a few specific anions (like chloride) bind to the all-trans pigment. It may be concluded that while the all-trans pigment loses its Schiff base proton very rapidly at its pKa, there is a kinetic barrier to this deprotonation in the 13-cis photointermediate that can be partially overcome by the reversible protonation of an extrinsic anionic base, which shuttles protons between the interior of the protein and the aqueous medium. The need for an extrinsic proton acceptor for efficient deprotonation of the Schiff base of halorhodopsin is one of the main differences between this pigment and the analogous retinal protein, bacteriorhodopsin.

The opsin family of proteins

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Effects of arginine modification on the photocycle of halorhodopsin

Exhaustive reaction with phenylglyoxal removed 9 of the 12 arginine and 1 of the 2 lysine residues in detergent-solubilized halorhodopsin, without affecting the chromophore. The consequences of this extensive removal of positive charges on various chloride-binding equilibria and the photochemistry were evaluated. No significant effects were seen on the affinity of Site I to chloride and on the increase in the pKa of Schiff-base deprotonation, which is caused by the chloride binding at this site. No significant effects were seen on the affinity of Site II to chloride, either. However, the photocycle of the pigment was affected. Kinetic modeling of the observed changes in flash-induced absorption changes suggests that the modification increases the affinity of the main halorhodopsin photointermediate to chloride by about fourfold. If chloride translocation involves release of chloride from this intermediate during the transport cycle, the result might explain the observed partial inhibitory effects on chloride transport. Plausible models of chloride translocation include reversible binding of the anion by positively charged groups, strategically arranged in the protein. The results indicate that two of the three spectroscopically observable chloride-dependent equilibria do not depend on a large number of positively charged residues in the protein. To the extent that the unaffected equilibria represent association and dissociation which occur during chloride translocation, at least part of the chloride translocation might be accomplished with the participation of only a few positively charged residues.

Light-dependent trans to cis isomerization of the retinal in halorhodopsin

Flash-induced absorption changes in the near UV were determined for bacteriorhodopsin and halorhodopsin on a millisecond time scale. The difference spectrum obtained for bacteriorhodopsin was comparable to model difference spectra of tyrosine (aromatic OH deprotonated vs protonated), as found by others. The flash-induced difference spectrum for halorhodopsin, in contrast, resembled a model spectrum obtained for trans to 13-cis isomerization of retinal in bacteriorhodopsin. A model for chloride translocation by halorhodopsin is presented, in which the retinal isomerization moves positive charges, which in turn modulate the affinity of a site to chloride.

Reconstitution of purified halorhodopsin

Asolectin lipid vesicles containing halorhodopsin show light-induced acidification in the presence of proton ionophores. This effect is abolished by triphenyltin chloride, a chloride/hydroxyl antiporter, and is greatly diminished by valinomycin in the presence of potassium ions, which collapse the membrane potential. This indicates that halorhodopsin orients in the lipid vesicles preferentially inside out, pumping chloride into the extravesicular compartment. The absorption maximum of halorhodopsin in asolectin vesicles in 3 M NaCl is at 567 nm, and the action spectrum for the light-induced pH changes followed closely the absorption spectrum. Replacement of chloride by acetate or sulfate causes a shift in the absorption maximum to approximately equal to 559 nm and renders the pump inactive. The different photocycles of the two forms were used to show that 80% of the molecules have the extracellular side exposed to the vesicle interior and that the halide-binding site(s) associated with the spectral transition is accessible from the extracellular side of the molecule. The data presented demonstrate that the purified chromoprotein is the light-driven chloride pump in Halobacterium halobium.

Nature of the principal photointermediate of halorhodopsin

Two alternative hypotheses have been presented as to the nature of the principal halorhodopsin photointermediate: a) it is a form whose its absorption band is shifted from the 575 nm position to 500 or 520 nm, and b) it is a form whose absorption band is shifted to only about 565 nm, but with an altered band shape so it exhibits a fortuitous difference peak near 500 nm. Such a shift with a maximum near 500 nm is also obtained in the dark when chloride is removed from the sample, suggesting the hypothesis that the spectral changes reflect the transient detachment of chloride from a binding site (Ogurusu et al, J. Biochem. Tokyo 95, 1073-1082, 1984). Comparison of the quantum yields of flash-induced absorption changes in halorhodopsin and bacteriorhodopsin strongly suggests, however, that hypothesis b) is untenable.