Your search keyword '"Needleman R"' showing total 14 results

1. Conformational changes of bacteriorhodopsin along the proton-conduction chain as studied with (13)C NMR of [3-(13)C]Ala-labeled protein: arg(82) may function as an information mediator.

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Author

Tanio M, Tuzi S, Yamaguchi S, Kawaminami R, Naito A, Needleman R, Lanyi JK, and Saitô H

Subjects

Alanine, Amino Acid Sequence, Amino Acid Substitution, Arginine, Carbon Isotopes, Halobacterium salinarum, Kinetics, Mutagenesis, Site-Directed, Nuclear Magnetic Resonance, Biomolecular methods, Protein Conformation, Protein Structure, Secondary, Recombinant Proteins chemistry, Bacteriorhodopsins chemistry

Abstract

We have recorded (13)C NMR spectra of [3-(13)C]Ala-labeled wild-type bacteriorhodopsin (bR) and its mutants at Arg(82), Asp(85), Glu(194), and Glu(204) along the extracellular proton transfer chain. The upfield and downfield displacements of the single carbon signals of Ala(196) (in the F-G loop) and Ala(126) (at the extracellular end of helix D), respectively, revealed conformational differences in E194D, E194Q, and E204Q from the wild type. The same kind of conformational change at Ala(126) was noted also in the Y83F mutant, which lacks the van der Waals contact between Tyr(83) and Ala(126) present in the wild type. The absence of a negative charge at Asp(85) in the site-directed mutant D85N induced global conformational changes, as manifested in displacements or suppression of peaks from the transmembrane helices, cytoplasmic loops, etc., as well as the local changes at Ala(126) and Ala(196) seen in the other mutants. Unexpectedly, no conformational change at Ala(126) was observed in R82Q (even though Asp(85) is protonated at pH 6) or in D85N/R82Q. The changes induced in the Ala(126) signal when Asp(85) is uncharged could be interpreted therefore in terms of displacement of the positive charge of Arg(82) toward Tyr(83), where Ala(126) is located. It is possible that disruption of the proton transfer chain after protonation of Asp(85) in the photocycle could cause the same kind of conformational change we detect at Ala(196) and Ala(126). If so, the latter change would be also the result of rearrangement of the side chain of Arg(82). more...

Published

1999

2. Long-distance effects of site-directed mutations on backbone conformation in bacteriorhodopsin from solid state NMR of [1-13C]Val-labeled proteins.

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Author

Tanio M, Inoue S, Yokota K, Seki T, Tuzi S, Needleman R, Lanyi JK, Naito A, and Saitô H

Subjects

Bacteriorhodopsins chemistry, Carbon Isotopes, Chymotrypsin, Magnetic Resonance Spectroscopy, Models, Molecular, Mutagenesis, Site-Directed, Protein Structure, Secondary, Spectrophotometry, Temperature, Bacteriorhodopsins genetics, Halobacterium salinarum genetics, Protein Conformation

Abstract

We have recorded 13C cross-polarization-magic angle spinning and dipolar decoupled-magic angle spinning NMR spectra of [1-13C]Val-labeled wild-type bacteriorhodopsin (bR), and the V49A, V199A, T46V, T46V/V49A, D96N, and D85N mutants, in order to study conformational changes of the backbone caused by site-directed mutations along the extracellular surface and the cytoplasmic half channel. On the basis of spectral changes in the V49A and V199A mutants, and upon specific cleavage by chymotrypsin, we assigned the three well-resolved 13C signals observed at 172.93, 172.00, and 171. 11 ppm to [1-13C]Val 69, Val 49, and Val 199, respectively. The local conformations of the backbone at these residues are revealed by the conformation-dependent 13C chemical shifts. We find that at the ambient temperature of these measurements Val 69 is not in a beta-sheet, in spite of previous observations by electron microscopy and x-ray diffraction at cryogenic temperatures, but in a flexible turn structure that undergoes conformational fluctuation. Results with the T46V mutant suggest that there is a long-distance effect on backbone conformation between Thr 46 and Val 49. From the spectra of the D85N and E204Q mutants there also appears to be coupling between Val 49 and Asp 85 and between Asp 85 and Glu 204, respectively. In addition, the T2 measurement indicates conformational interaction between Asp 96 and extracellular surface. The protonation of Asp 85 in the photocycle therefore might induce changes in conformation or dynamics, or both, throughout the protein, from the extracellular surface to the side chain of Asp 96. more...

Published

1999

3. Binding of calcium ions to bacteriorhodopsin.

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Author

Váró G, Brown LS, Needleman R, and Lanyi JK

Subjects

Aspartic Acid chemistry, Bacteriorhodopsins genetics, Binding Sites, Biophysical Phenomena, Biophysics, Calorimetry, Cysteine chemistry, Halobacterium salinarum genetics, Halobacterium salinarum metabolism, Hydrogen-Ion Concentration, Mutation, Protein Binding, Protons, Surface Properties, Bacteriorhodopsins chemistry, Bacteriorhodopsins metabolism, Calcium metabolism

Abstract

Adding Ca2+ or other cations to deionized bacteriorhodopsin causes a blue to purple color shift, a result of deprotonation of Asp85. It has been proposed by different groups that the protonation state of Asp85 responds to the binding of Ca2+ either 1) directly at a specific site in the protein or 2) indirectly through the rise of the surface pH. We tested the idea of specific binding of Ca2+ and found that the surface pH, as determined from the ionization state of eosin covalently linked to engineered cysteine residues, rises about equally at both extracellular and cytoplasmic surfaces when only one Ca2+ is added. This precludes binding to a specific site and suggests that rather than decreasing the pKa of Asp85 by direct interaction, Ca2+ increases the surface pH by binding to anionic lipid groups. As Ca2+ is added the surface pH rises, but deprotonation of Asp85 occurs only when the surface pH approaches its pKa. The nonlinear relationship between Ca2+ binding and deprotonation of Asp85 from this effect is different in the wild-type protein and in various mutants and explains the observed complex and varied spectral titration curves. more...

Published

1999

4. Location of a cation-binding site in the loop between helices F and G of bacteriorhodopsin as studied by 13C NMR.

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Author

Tuzi S, Yamaguchi S, Tanio M, Konishi H, Inoue S, Naito A, Needleman R, Lanyi JK, and Saitô H

Subjects

Binding Sites, Biophysical Phenomena, Biophysics, Cations metabolism, Halobacterium salinarum chemistry, Hydrogen-Ion Concentration, Magnetic Resonance Spectroscopy, Models, Molecular, Protein Conformation, Protein Structure, Secondary, Bacteriorhodopsins chemistry, Bacteriorhodopsins metabolism

Abstract

The high-affinity cation-binding sites of bacteriorhodopsin (bR) were examined by solid-state 13C NMR of samples labeled with [3-13C]Ala and [1-13C]Val. We found that the 13C NMR spectra of two kinds of blue membranes, deionized (pH 4) and acid blue at pH 1.2, were very similar and different from that of the native purple membrane. This suggested that when the surface pH is lowered, either by removal of cations or by lowering the bulk pH, substantial change is induced in the secondary structure of the protein. Partial replacement of the bound cations with Na+, Ca2+, or Mn2+ produced additional spectral changes in the 13C NMR spectra. The following conclusions were made. First, there are high-affinity cation-binding sites in both the extracellular and the cytoplasmic regions, presumably near the surface, and one of the preferred cation-binding sites is located at the loop between the helix F and G (F-G loop) near Ala196, consistent with the 3D structure of bR from x-ray diffraction and cryoelectron microscopy. Second, the bound cations undergo rather rapid exchange (with a lifetime shorter than 3 ms) among various types of cation-binding sites. As expected from the location of one of the binding sites, cation binding induced conformational alteration of the F-G interhelical loop. more...

Published

1999

5. Conformational change of helix G in the bacteriorhodopsin photocycle: investigation with heavy atom labeling and x-ray diffraction.

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Author

Oka T, Kamikubo H, Tokunaga F, Lanyi JK, Needleman R, and Kataoka M

Subjects

Bacteriorhodopsins genetics, Cysteine genetics, Halobacterium salinarum metabolism, Mercury chemistry, Mutagenesis, Site-Directed, Spectroscopy, Fourier Transform Infrared, X-Ray Diffraction, p-Chloromercuribenzoic Acid metabolism, Bacteriorhodopsins chemistry, Protein Conformation, Protein Structure, Secondary

Abstract

According to the current structural model of bacteriorhodopsin, Ile222 is located at the cytoplasmic end of helix G. We labeled the single cysteine of the site-directed mutant Ile222 --> Cys with p-chloromercuribenzoic acid and determined the position of the labeled mercury by x-ray diffraction in the unphotolyzed state, and in the MN photointermediate accumulated in the presence of guanidine hydrochloride at pH 9.5. According to the difference Fourier maps between the MN intermediate and the unphotolyzed state, the structural change in the MN intermediate was not affected by mercury labeling. The difference Fourier map between the labeled and the unlabeled I222C gave the position of the mercury label. This information was obtained for both the unphotolyzed state and the MN intermediate. We found that the position of the mercury at residue 222 is shifted by 2.1 +/- 0.8 A in the MN intermediate. This agrees with earlier results that suggested a structural change in the G helix. The movement of the mercury label is so large that it must originate from a cooperative conformational change in the helix G at its cytoplasmic end, rather than from displacement of residue 222. Because Ile222 is located at the same level on the z coordinate as Asp96, the structural change in the G helix could have the functional role of perturbing the environment and therefore the pKa of this functionally important aspartate. more...

Published

1999

6. Connectivity of the retinal Schiff base to Asp85 and Asp96 during the bacteriorhodopsin photocycle: the local-access model.

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Author

Brown LS, Dioumaev AK, Needleman R, and Lanyi JK

Subjects

Aspartic Acid chemistry, Aspartic Acid radiation effects, Bacteriorhodopsins genetics, Biophysical Phenomena, Biophysics, Halobacterium salinarum chemistry, Halobacterium salinarum genetics, Halobacterium salinarum radiation effects, Hydrogen-Ion Concentration, Kinetics, Light, Models, Chemical, Mutagenesis, Site-Directed, Photochemistry, Protein Conformation radiation effects, Protons, Retinaldehyde chemistry, Retinaldehyde radiation effects, Schiff Bases chemistry, Schiff Bases radiation effects, Spectroscopy, Fourier Transform Infrared, Bacteriorhodopsins chemistry, Bacteriorhodopsins radiation effects

Abstract

In the recently proposed local-access model for proton transfers in the bacteriorhodopsin transport cycle (Brown et al. 1998. Biochemistry. 37:3982-3993), connection between the retinal Schiff base and Asp85 (in the extracellular direction) and Asp96 (in the cytoplasmic direction)is maintained as long as the retinal is in its photoisomerized state. The directionality of the proton translocation is determined by influences in the protein that make Asp85 a proton acceptor and, subsequently, Asp96 a proton donor. The idea of concurrent local access of the Schiff base in the two directions is now put to a test in the photocycle of the D115N/D96N mutant. The kinetics had suggested that there is a single sequence of intermediates, L<-->M1<-->M2<-->N, and the M2-->M1 reaction depends on whether a proton is released to the extracellular surface. This is now confirmed. We find that at pH 5, where proton release does not occur, but not at higher pH, the photostationary state created by illumination with yellow light contains not only the M1 and M2 states, but also the L and the N intermediates. Because the L and M1 states decay rapidly, they can be present only if they are in equilibrium with later intermediates of the photocycle. Perturbation of this mixture with a blue flash caused depletion of the M intermediate, followed by its partial recovery at the expense of the L state. The change in the amplitude of the C=O stretch band at 1759 cm-1 demonstrated protonation of Asp85 in this process. Thus, during the reequilibration the Schiff base lost its proton to Asp85. Because the N state, also present in the mixture, arises by protonation of the Schiff base from the cytoplasmic surface, these results fulfill the expectation that under the conditions tested the extracellular access of the Schiff base would not be lost at the time when there is access in the cytoplasmic direction. Instead, the connectivity of the Schiff base flickers rapidly (with the time constant of the M1<-->M2 equilibration) between the two directions during the entire L-to-N segment of the photocycle. more...

Published

1998

7. Perturbed interaction between residues 85 and 204 in Tyr-185-->Phe and Asp-85-->Glu bacteriorhodopsins.

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Author

Richter HT, Needleman R, and Lanyi JK

Subjects

Aspartic Acid, Darkness, Glutamic Acid, Halobacterium metabolism, Hydrogen-Ion Concentration, Kinetics, Light, Mutagenesis, Site-Directed, Phenylalanine, Point Mutation, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Spectrophotometry, Tyrosine, Bacteriorhodopsins chemistry, Bacteriorhodopsins metabolism

Abstract

According to earlier reports, residue 85 in the bacteriorhodopsin mutants D85E and Y185F deprotonates with two apparent pKa values. Additionally, in Y185F, Asp-85 becomes significantly more protonated during light adaptation. We provide a new explanation for these findings. It is based on the scheme that links the protonation state of residue 85 to the protonation state of residue 204 (S.P. Balashov, E.S. Imasheva, R. Govindjee, and T.G. Ebrey. 1996. Biophys. J. 70:473-481; H.T. Richter, L.S. Brown, R. Needleman, and J.K. Lanyi. 1996. Biochemistry. 35:4054-4062) and justified by the observation that the biphasic titration curves of D85E and Y185F are converted to monophasic when the E204Q residue change is introduced as a second mutation. Accordingly, the D85E and Y 185F mutations are not the cause of the biphasic titration, as that is a property of the wild-type protein. By perturbing the extracellular region of the protein, the mutations increase the pKa of residue 85. This increases the amplitude of the second titration component and makes the biphasic character of the curves more obvious. Likewise, a small rise in the pKa of Asp-85 when the retinal isomerizes from 13-cis, 15-syn to all-trans accounts for the changed titration behavior of Y185F after light adaptation. This mechanism simplifies and unites the interpretation of what had appeared to be complex and unrelated phenomena. more...

Published

1996

8. Reversal of the surface charge asymmetry in purple membrane due to single amino acid substitutions.

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Author

Hsu KC, Rayfield GW, and Needleman R

Subjects

Bacteriorhodopsins metabolism, Darkness, Electrochemistry, Halobacterium genetics, Halobacterium metabolism, Hydrogen-Ion Concentration, Kinetics, Light, Mutagenesis, Site-Directed, Photochemistry, Point Mutation, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Spectrophotometry, Surface Properties, Time Factors, Bacteriorhodopsins chemistry, Purple Membrane chemistry

Abstract

Twenty-seven mutant bacteriorhodopsin's were screened to determine the PKa for reversal of the permanent electric dipole moment. The photoelectric response of an aqueous purple-membrane suspension was used to determine the direction of the purple-membrane dipole moment as a function of pH. The pK(a) for the dipole reversal of wild-type bacteriorhodopsin is 4.5. Six of the 27 mutant bacteriorhodopsin's were found to have a pK(a) for dipole reversal larger than that of wild-type bacteriorhodopsin. Two of these mutants, L93T and L93W, involve a neutral amino acid substitution in the interior of the protein. The direction of the purple-membrane permanent electric dipole moment is determined by the purple-membrane surface charge asymmetry. We conclude that these two substitutions, which do not involve charge replacement, alter the pK(a) for the reversal of the purple-membrane surface charge asymmetry. We suggest that these changes to the pK(a) are due to altered protein folding at the surface of the purple-membrane induced by single-site substitutions in the protein interior. more...

Published

1996

9. Protein structural change at the cytoplasmic surface as the cause of cooperativity in the bacteriorhodopsin photocycle.

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Author

Váró G, Needleman R, and Lanyi JK

Subjects

Biophysical Phenomena, Biophysics, Cytoplasm chemistry, Halobacterium chemistry, Halobacterium radiation effects, Hydrogen-Ion Concentration, Kinetics, Molecular Structure, Photochemistry, Thermodynamics, Bacteriorhodopsins chemistry, Bacteriorhodopsins radiation effects

Abstract

The effects of excitation light intensity on the kinetics of the bacteriorhodopsin photocycle were investigated. The earlier reported intensity-dependent changes at 410 and 570 nm are explained by parallel increases in two of the rate constants, for proton transfers to D96 from the Schiff base and from the cytoplasmic surface, without changes in the others, as the photoexcited fraction is increased. Thus, it appears that the pKa of D96 is raised by a cooperative effect within the purple membrane. This interpretation of the wild-type kinetics was confirmed by results with several mutant proteins, where the rates are well separated in time and a model-dependent analysis is unnecessary. Based on earlier results that demonstrated a structural change of the protein after deprotonation of the Schiff base that increases the area of the cytoplasmic surface, and the effects of high hydrostatic pressure and lowered water activity on the photocycle steps in question, we suggest that the pKa of D96 is raised by a lateral pressure that develops when other bacteriorhodopsin molecules are photoexcited within the two-dimensional lattice of the purple membrane. Expulsion of no more than a few water molecules bound near D96 by this pressure would account for the calculated increase of 0.6 units in the pKa. more...

Published

1996

10. Functional significance of a protein conformation change at the cytoplasmic end of helix F during the bacteriorhodopsin photocycle.

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Author

Brown LS, Váró G, Needleman R, and Lanyi JK

Subjects

Bacteriorhodopsins genetics, Biophysical Phenomena, Biophysics, Cross-Linking Reagents, Cysteine chemistry, Cytoplasm chemistry, Halobacterium chemistry, Halobacterium genetics, Halobacterium radiation effects, Hydrostatic Pressure, Kinetics, Maleimides, Models, Molecular, Mutagenesis, Site-Directed, Photochemistry, Protein Conformation radiation effects, Proton Pumps chemistry, Proton Pumps genetics, Proton Pumps radiation effects, Retinaldehyde chemistry, Schiff Bases chemistry, Water chemistry, Bacteriorhodopsins chemistry, Bacteriorhodopsins radiation effects

Abstract

The second half of the photocycle of the light-driven proton pump bacteriorhodopsin includes proton transfers between D96 and the retinal Schiff base (the M to N reaction) and between the cytoplasmic surface and D96 (decay of the N intermediate). The inhibitory effects of decreased water activity and increased hydrostatic pressure have suggested that a conformational change resulting in greater hydration of the cytoplasmic region is required for proton transfer from D96 to the Schiff base, and have raised the possibility that the reversal of this process might be required for the subsequent reprotonation of D96 from the cytoplasmic surface. Tilt of the cytoplasmic end of helix F has been suggested by electron diffraction of the M intermediate. Introduction of bulky groups, such as various maleimide labels, to engineered cysteines at the cytoplasmic ends of helices A, B, C, E, and G produce only minor perturbation of the decays of M and N, but major changes in these reactions when the label is linked to helix F. In these samples the reprotonation of the Schiff base is accelerated and the reprotonation of D96 is strongly retarded. Cross-linking with benzophenone introduced at this location, but not at the others, causes the opposite change: the reprotonation of the Schiff base is greatly slowed while the reprotonation of D96 is accelerated. We conclude that, consistent with the structure from diffraction, the proton transfers in the second half of the photocycle are facilitated by motion of the cytoplasmic end of helix F, first away from the center of the protein and then back. more...

Published

1995

11. Photocycle of halorhodopsin from Halobacterium salinarium.

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Author

Váró G, Zimányi L, Fan X, Sun L, Needleman R, and Lanyi JK

Subjects

Bacteriorhodopsins chemistry, Bacteriorhodopsins radiation effects, Halorhodopsins, Kinetics, Light, Mathematics, Models, Theoretical, Retinaldehyde, Bacteriorhodopsins metabolism, Halobacterium metabolism

Abstract

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. more...

Published

1995

12. Relationship of proton release at the extracellular surface to deprotonation of the schiff base in the bacteriorhodopsin photocycle.

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Author

Cao Y, Brown LS, Sasaki J, Maeda A, Needleman R, and Lanyi JK

Subjects

Bacteriorhodopsins genetics, Biophysical Phenomena, Biophysics, Fluorescein, Fluoresceins, Halobacterium salinarum chemistry, Halobacterium salinarum genetics, Halobacterium salinarum radiation effects, Hydrogen-Ion Concentration, Kinetics, Membrane Potentials, Models, Chemical, Photochemistry, Point Mutation, Protons, Schiff Bases chemistry, Schiff Bases radiation effects, Bacteriorhodopsins chemistry, Bacteriorhodopsins radiation effects

Abstract

The surface potential of purple membranes and the release of protons during the bacteriorhodopsin photocycle have been studied with the covalently linked pH indicator dye, fluorescein. The titration of acidic lipids appears to cause the surface potential to be pH-dependent and causes other deviations from ideal behavior. If these anomalies are neglected, the appearance of protons can be followed by measuring the absorption change of fluorescein bound to various residues at the extracellular surface. Contrary to widely held assumption, the activation enthalpies of kinetic components, deuterium isotope effects in the time constants, and the consequences of the D85E, F208R, and D212N mutations demonstrate a lack of direct correlation between proton transfer from the buried retinal Schiff base to D85 and proton release at the surface. Depending on conditions and residue replacements, the proton release can occur at any time between the protonation of D85 and the recovery of the initial state. We conclude that once D85 is protonated the proton release at the extracellular protein surface is essentially independent of the chromophore reactions that follow. This finding is consistent with the recently suggested version of the alternating access mechanism of bacteriorhodopsin, in which the change of the accessibility of the Schiff base is to and away from D85 rather than to and away from the extracellular membrane surface. more...

Published

1995

13. Estimated acid dissociation constants of the Schiff base, Asp-85, and Arg-82 during the bacteriorhodopsin photocycle.

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Author

Brown LS, Bonet L, Needleman R, and Lanyi JK

Subjects

Arginine chemistry, Aspartic Acid chemistry, Bacteriorhodopsins genetics, Biophysical Phenomena, Biophysics, Halobacterium salinarum chemistry, Halobacterium salinarum genetics, Halobacterium salinarum radiation effects, Hydrogen-Ion Concentration, Photochemistry, Proton Pumps physiology, Proton Pumps radiation effects, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins radiation effects, Schiff Bases chemistry, Spectrophotometry, Thermodynamics, Bacteriorhodopsins chemistry, Bacteriorhodopsins radiation effects

Abstract

The pK(a) values of D85 in the wild-type and R82Q, as well as R82A recombinant bacteriorhodopsins, and the Schiff base in the D85N, D85T, and D85N/R82Q proteins, have been determined by spectroscopic titrations in the dark. They are used to estimate the coulombic interaction energies and the pK(a) values of the Schiff base, D85, and R82 during proton transfer from the Schiff base to D85, and the subsequent proton release to the bulk in the initial part of the photocycle. The pK(a) of the Schiff base before photoexcitation is calculated to be in effect only 5.3-5.7 pH units higher than that of D85; overcoming this to allow proton transfer to D85 requires about two thirds of the estimated excess free energy retained after absorption of a photon. The proton release on the extracellular surface is from an unidentified residue whose pK(a) is lowered to about 6 after deprotonation of the Schiff base (Zimanyi, L., G. Varo, M. Chang, B. Ni, R. Needleman, and J.K. Lanyi, 1992. Biochemistry. 31:8535-8543). We calculate that the pK(a) of the R82 is 13.8 before photoexcitation, and it is lowered after proton exchange between the Schiff base and D85 only by 1.5-2.3 pH units. Therefore, coulombic interactions alone do not appear to change the pK(a) of R82 as much and D85 only by 1.5-2.3 pH units. Therefore, coulombic interactions alone do not appear to change the pK(a) of R82 as much as required if it were the proton release group. more...

Published

1993

14. A residue substitution near the beta-ionone ring of the retinal affects the M substates of bacteriorhodopsin.

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Author

Váró G, Zimányi L, Chang M, Ni B, Needleman R, and Lanyi JK

Subjects

Bacteriorhodopsins chemistry, Bacteriorhodopsins genetics, Binding Sites, Cloning, Molecular, Fourier Analysis, Genes, Bacterial, Halobacterium salinarum genetics, Halobacterium salinarum metabolism, Kinetics, Light, Models, Molecular, Mutagenesis, Site-Directed, Protein Conformation, Schiff Bases, Spectrophotometry, Bacteriorhodopsins metabolism, Retinaldehyde metabolism

Abstract

The switch in the bacteriorhodopsin photocycle, which reorients access of the retinal Schiff base from the extracellular to the cytoplasmic side, was suggested to be an M1----M2 reaction (Váró and Lanyi. 1991. Biochemistry. 30:5008-5015, 5016-5022). Thus, in this light-driven proton pump it is the interconversion of proposed M substates that gives direction to the transport. We find that in monomeric, although not purple membrane-lattice immobilized, D115N bacteriorhodopsin, the absorption maximum of M changes during the photocycle: in the time domain between its rise and decay it shifts 15 nm to the blue relative to the spectrum at earlier times. This large shift strongly supports the existence of two M substates. Since D115 is located near the beta-ionone ring of the retinal, the result raises questions about the possible involvement of the retinal chain or protein residues as far away as 10 A from the Schiff base in the mechanism of the switching reaction. more...

Published

1992