Your search keyword '"Crouch RK"' showing total 24 results

1. Modulation of molecular interactions and function by rhodopsin palmitylation.

Author

Park PS, Sapra KT, Jastrzebska B, Maeda T, Maeda A, Pulawski W, Kono M, Lem J, Crouch RK, Filipek S, Müller DJ, and Palczewski K

Subjects

Animals, COS Cells, Chlorocebus aethiops, Cysteine chemistry, Light, Mice, Mice, Inbred C57BL, Models, Molecular, Molecular Conformation, Protein Binding, Protein Structure, Tertiary, Rod Cell Outer Segment metabolism, Transducin chemistry, Palmitic Acid chemistry, Rhodopsin chemistry, Rhodopsin physiology

Abstract

Rhodopsin is palmitylated at two cysteine residues in its carboxyl terminal region. We have looked at the effects of palmitylation on the molecular interactions formed by rhodopsin using single-molecule force spectroscopy and the function of rhodopsin using both in vitro and in vivo approaches. A knockin mouse model expressing palmitate-deficient rhodopsin was used for live animal in vivo studies and to obtain native tissue samples for in vitro assays. We specifically looked at the effects of palmitylation on the chromophore-binding pocket, interactions of rhodopsin with transducin, and molecular interactions stabilizing the receptor structure. The structure of rhodopsin is largely unperturbed by the absence of palmitate linkage. The binding pocket for the chromophore 11-cis-retinal is minimally altered as palmitate-deficient rhodopsin exhibited the same absorbance spectrum as wild-type rhodopsin. Similarly, the rate of release of all-trans-retinal after light activation was the same both in the presence and absence of palmitylation. Significant differences were observed in the rate of transducin activation by rhodopsin and in the force required to unfold the last stable structural segment in rhodopsin at its carboxyl terminal end. A 1.3-fold reduction in the rate of transducin activation by rhodopsin was observed in the absence of palmitylation. Single-molecule force spectroscopy revealed a 2.1-fold reduction in the normalized force required to unfold the carboxyl terminal end of rhodopsin. The absence of palmitylation in rhodopsin therefore destabilizes the molecular interactions formed in the carboxyl terminal end of the receptor, which appears to hinder the activation of transducin by light-activated rhodopsin.

Published

2009

2. 11-cis- and all-trans-retinols can activate rod opsin: rational design of the visual cycle.

Author

Kono M, Goletz PW, and Crouch RK

Subjects

Animals, COS Cells, Cattle, Chlorocebus aethiops, Haplorhini, Photoreceptor Cells physiology, Retinaldehyde chemistry, Retinaldehyde metabolism, Vitamin A chemistry, Retinal Rod Photoreceptor Cells physiology, Retinaldehyde pharmacology, Rhodopsin metabolism, Transducin physiology, Vision, Ocular physiology, Vitamin A pharmacology

Abstract

Rhodopsin is the photosensitive pigment in the rod photoreceptor cell. Upon absorption of a photon, the covalently bound 11- cis-retinal isomerizes to the all- trans form, enabling rhodopsin to activate transducin, its G protein. All -trans-retinal is then released from the protein and reduced to all -trans-retinol. It is subsequently transported to the retinal pigment epithelium where it is converted to 11- cis-retinol and oxidized to 11- cis-retinal before it is transported back to the photoreceptor to regenerate rhodopsin and complete the visual cycle. In this study, we have measured the effects of all -trans- and 11- cis-retinals and -retinols on the opsin's ability to activate transducin to ascertain their potentials for activating the signaling cascade. Only 11- cis-retinal acts as an inverse agonist to the opsin. All -trans-retinal, all -trans-retinol, and 11- cis-retinol are all agonists with all -trans-retinal being the most potent agonist and all -trans-retinol being the least potent. Taken as a whole, our study is consistent with the hypothesis that the steps in the visual cycle are optimized such that the rod can serve as a highly sensitive dim light receptor. All -trans-retinal is immediately reduced in the photoreceptor to prevent back reactions and to weaken its effectiveness as an agonist before it is transported out of the cell; oxidation of 11- cis-retinol occurs in the retinal pigment epithelium and not the rod photoreceptor cell because 11- cis-retinol can act as an agonist and activate the signaling cascade if it were to bind an opsin, effectively adapting the cell to light.

Published

2008

3. Interphotoreceptor retinoid-binding protein is the physiologically relevant carrier that removes retinol from rod photoreceptor outer segments.

Author

Wu Q, Blakeley LR, Cornwall MC, Crouch RK, Wiggert BN, and Koutalos Y

Subjects

Animals, Isomerism, Kinetics, Rana pipiens, Eye Proteins metabolism, Retinol-Binding Proteins metabolism, Rod Cell Outer Segment metabolism, Vitamin A metabolism

Abstract

Light detection by vertebrate rod photoreceptor outer segments results in the destruction of the visual pigment, rhodopsin, as its retinyl moiety is photoisomerized from 11-cis to all-trans. The regeneration of rhodopsin is necessary for vision and begins with the release of the all-trans retinal and its reduction to all-trans retinol. Retinol is then transported out of the rod outer segment for further processing. We used fluorescence imaging to monitor retinol fluorescence and quantify the kinetics of its formation and clearance after rhodopsin bleaching in the outer segments of living isolated frog (Rana pipiens) rod photoreceptors. We independently measured the release of all-trans retinal from bleached rhodopsin in frog rod outer segment membranes and the rate of all-trans retinol removal by the lipophilic carriers interphotoreceptor retinoid binding protein (IRBP) and serum albumin. We find that the kinetics of all-trans retinol formation in frog rod outer segments after rhodopsin bleaching are to a good first approximation determined by the kinetics of all-trans retinal release from the bleached pigment. For the physiological concentrations of carriers, the rate of retinol removal from the outer segment is determined by IRBP concentration, whereas the effect of serum albumin is negligible. The results indicate the presence of a specific interaction between IRBP and the rod outer segment, probably mediated by a receptor. The effect of different concentrations of IRBP on the rate of retinol removal shows no cooperativity and has an EC50 of 40 micromol/L.

Published

2007

4. A dark and constitutively active mutant of the tiger salamander UV pigment.

Author

Kono M, Crouch RK, and Oprian DD

Subjects

Amino Acid Substitution genetics, Animals, Cattle, Humans, Mutagenesis, Insertional, Pigments, Biological isolation & purification, Protein Conformation, Retinal Cone Photoreceptor Cells chemistry, Retinaldehyde genetics, Retinaldehyde metabolism, Rod Opsins metabolism, Spectrophotometry, Ultraviolet, Transducin metabolism, Ambystoma genetics, Ambystoma metabolism, Darkness, Pigments, Biological genetics, Pigments, Biological metabolism, Retinal Cone Photoreceptor Cells metabolism, Retinaldehyde analogs & derivatives, Ultraviolet Rays

Abstract

A triple mutant (F86L/T93P/S118T; bovine rhodopsin numbering) of the tiger salamander UV cone pigment appears to be trapped in an open conformation that is metarhodopsin-II-like. The pigment is able to activate transducin in the dark, and the ligand-free apoprotein is also able to activate transducin constitutively. The pigment permits protons and chloride ions from solution access to the active site as it displays a pH- and NaCl-dependent absorption spectrum not observed with the wild-type pigment. However, the wild-type properties of light-dependent activity and a pH-independent absorption spectrum are recovered upon reconstitution of the triple mutant with 11-cis-9-demethyl retinal. These results suggest that binding the native chromophore cannot deactivate the protein because of steric interactions between the protein, possibly residue 118, and the 9-methyl group of the chromophore. Furthermore, the absorption spectrum of the 9-demethyl retinal regenerated pigment exhibits a band broader and with lower extinction at the absorption maximum than either the human blue or salamander UV wild-type pigments generated with the same retinal analogue. The broad spectrum appears to be comprised of two or more species and can be well-fit by a sum of scaled spectra of the two wild-type pigments. Binding the chromophore appears to trap the pigment in two or more conformations. The triple mutant reported here represents the first example of a dark-active cone pigment and constitutively active cone opsin.

Published

2005

5. Probing rhodopsin-transducin interactions by surface modification and mass spectrometry.

Author

Wang X, Kim SH, Ablonczy Z, Crouch RK, and Knapp DR

Subjects

Acetylation, Amino Acid Sequence, Animals, Cattle, Chromatography, Liquid, Cytoplasm metabolism, Light, Lysine metabolism, Molecular Sequence Data, Peptide Fragments chemistry, Peptide Fragments metabolism, Protein Binding, Protein Conformation, Protein Subunits chemistry, Protein Subunits metabolism, Rhodopsin antagonists & inhibitors, Rod Cell Outer Segment chemistry, Rod Cell Outer Segment metabolism, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Surface Properties, Rhodopsin chemistry, Rhodopsin metabolism, Transducin chemistry, Transducin metabolism

Abstract

The interactions of rhodopsin and the alpha-subunit of transducin (G(t)) have been mapped using a surface modification "footprinting" approach in conjunction with mass spectrometric analysis employing a synthetic peptide corresponding to C-terminal residues 340-350 of the alpha-subunit of G(t), G(t)alpha(340-350). Membrane preparations of unactivated (Rh) and light-activated rhodopsin (Rh*), each in the presence or absence of G(t)alpha(340-350), were acetylated with the water-soluble reagent sulfosuccinimidyl acetate, and the extent of the acetylation was determined by mass spectrometry. By comparing the differences in acetylation among Rh, Rh*, and the Rh-G(t)alpha(340-350) and Rh*-G(t)alpha(340-350) complexes, we demonstrate that the surface exposure of the acetylation sites was reduced by the conformational change associated with light activation, and that binding of G(t)alpha(340-350) blocks acetylation sites on cytoplasmic loops 1, 2, and 4 of Rh*. In addition, we show evidence of interaction between the end of the C-terminal tail of rhodopsin and G(t)alpha in the unactivated state of rhodopsin.

Published

2004

6. Post-translational modifications of aquaporin 0 (AQP0) in the normal human lens: spatial and temporal occurrence.

Author

Ball LE, Garland DL, Crouch RK, and Schey KL

Subjects

Adult, Amino Acid Sequence, Aquaporins, Asparagine metabolism, Chromatography, Liquid, Eye Proteins isolation & purification, Humans, Hydrolysis, Lens, Crystalline cytology, Male, Membrane Glycoproteins isolation & purification, Molecular Sequence Data, Peptide Fragments chemical synthesis, Peptide Fragments metabolism, Phosphorylation, Protein Conformation, Sequence Deletion, Spectrometry, Mass, Electrospray Ionization, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Trypsin metabolism, Cellular Senescence physiology, Eye Proteins chemistry, Eye Proteins metabolism, Lens, Crystalline chemistry, Lens, Crystalline metabolism, Membrane Glycoproteins chemistry, Membrane Glycoproteins metabolism, Protein Processing, Post-Translational

Abstract

Because of the lack of protein turnover in fiber cells of the ocular lens, Aquaporin 0 (AQP0), the most abundant membrane protein in the lens, undergoes extensive post-translational modification with fiber cell age. To map the distribution of modified forms of AQP0 within the lens, normal human lenses ranging in age from 34 to 38 were concentrically dissected into several cortical and nuclear sections. Membrane proteins still embedded in the membranes were digested with trypsin, and the resulting C-terminal peptides of AQP0 were analyzed by HPLC tandem mass spectrometry, permitting the identification of modifications and estimation of their abundance. Consistent with earlier reports, the major phosphorylation site was Ser 235, and the major sites of backbone cleavage occurred at residues 246 and 259. New findings suggest that cleavage at these sites may be a result of nonenzymatic truncation at asparagine residues. In addition, this approach revealed previously undetected sites of truncation at residues 249, 260, 261, and 262; phosphorylation at Ser 231 and to a lower extent at Ser 229; and racemization/isomerization of l-Asp 243 to d-Asp and d-iso-Asp. The spatial distribution of C-terminally modified AQP0 within the lens indicated an increase in truncation and racemization/isomerization with fiber cell age, whereas the level of Ser 235 phosphorylation increased from the outer to inner cortex but decreased in the nucleus. Furthermore, the remarkably similar pattern and distribution of truncation products from lenses from three donors suggest specific temporal mechanisms for the modification of AQP0.

Published

2004

7. Role of the 9-methyl group of retinal in cone visual pigments.

Author

Das J, Crouch RK, Ma JX, Oprian DD, and Kono M

Subjects

Ambystoma, Animals, COS Cells, Cattle, Chlorocebus aethiops, Light, Photoreceptor Cells chemistry, Rhodopsin chemistry, Rod Opsins chemistry, Spectrophotometry, Ultraviolet, Transducin metabolism, Retinal Cone Photoreceptor Cells chemistry, Retinaldehyde analogs & derivatives, Retinaldehyde chemistry

Abstract

In rhodopsin, the 9-methyl group of retinal has previously been identified as being critical in linking the ligand isomerization with the subsequent protein conformational changes that result in the activation of its G protein, transducin. Here, we report studies on the role of this methyl group in the salamander rod and cone pigments. Pigments were generated by combining proteins expressed in COS cells with 11-cis 9-demethyl retinal, where the 9-methyl group on the polyene chain has been deleted. The absorption spectra of all pigments were blue-shifted. The red cone and blue cone/green rod pigments were unstable to hydroxylamine; whereas, the rhodopsin and UV cone pigments were stable. The lack of the 9-methyl group of the chromophore did not affect the ability of the red cone and blue cone/green rod pigments to activate transducin. On the other hand, with the rhodopsin and UV cone pigments, activation was diminished. Interestingly, the red cone pigment containing the retinal analogue remained active longer than the native pigment. Thus, the 9-methyl group of retinal is not important in the activation pathway of the red cone and blue cone/green rod pigments. However, for the red cone pigment, the 9-methyl group of retinal appears to be critical in the deactivation pathway.

Published

2004

8. Retinyl esters are the substrate for isomerohydrolase.

Author

Moiseyev G, Crouch RK, Goletz P, Oatis J Jr, Redmond TM, and Ma JX

Subjects

Acyltransferases antagonists & inhibitors, Acyltransferases metabolism, Animals, Apoproteins chemistry, Carrier Proteins, Cattle, Cystine pharmacology, Diterpenes, Dose-Response Relationship, Drug, Enzyme Inhibitors chemistry, Esters, Eye Proteins genetics, Eye Proteins metabolism, Fatty Acids analysis, Ketones pharmacology, Mice, Mice, Inbred BALB C, Mice, Inbred C57BL, Mice, Knockout, Microsomes enzymology, Microsomes metabolism, Pigment Epithelium of Eye enzymology, Pigment Epithelium of Eye metabolism, Proteins genetics, Proteins metabolism, Retinol-Binding Proteins chemistry, Retinol-Binding Proteins, Cellular, Retinyl Esters, Substrate Specificity, Vitamin A analysis, Vitamin A antagonists & inhibitors, cis-trans-Isomerases antagonists & inhibitors, Cystine analogs & derivatives, Vitamin A analogs & derivatives, Vitamin A chemistry, Vitamin A metabolism, cis-trans-Isomerases chemistry, cis-trans-Isomerases metabolism

Abstract

Regeneration of 11-cis retinal from all-trans retinol in the retinal pigment epithelium (RPE) is a critical step in the visual cycle. The enzyme(s) involved in this isomerization process has not been identified and both all-trans retinol and all-trans retinyl esters have been proposed as the substrate. This study is to determine the substrate of the isomerase enzyme or enzymatic complex. Incubation of bovine RPE microsomes with all-trans [(3)H]-retinol generated both retinyl esters and 11-cis retinol. Inhibition of lecithin retinol acyltransferase (LRAT) with 10-N-acetamidodecyl chloromethyl ketone (AcDCMK) or cellular retinol-binding protein I (CRBP) diminished the generation of both retinyl esters and 11-cis retinol from all-trans retinol. The 11-cis retinol production correlated with the retinyl ester levels, but not with the all-trans retinol levels in the reaction mixture. When retinyl esters were allowed to form prior to the addition of the LRAT inhibitors, a significant amount of isomerization product was generated. Incubation of all-trans [(3)H]-retinyl palmitate with RPE microsomes generated 11-cis retinol without any detectable production of all-trans retinol. The RPE65 knockout (Rpe65(-/-)) mouse eyecup lacks the isomerase activity, but LRAT activity remains the same as that in the wild-type (WT) mice. Retinyl esters in WT mice plateau at 8 weeks-of-age, but Rpe65(-/-) mice continue to accumulate retinyl esters with age (e.g., at 36 weeks, the levels are 20x that of WT). Our data indicate that the retinyl esters are the substrate of the isomerization reaction.

Published

2003

9. Exploring the function of Tyr83 in bacteriorhodopsin: features of the Y83F and Y83N mutants.

Author

Imasheva ES, Lu M, Balashov SP, Ebrey TG, Chen Y, Ablonczy Z, Menick DR, and Crouch RK

Subjects

Bacteriorhodopsins genetics, Halobacterium salinarum chemistry, Halobacterium salinarum genetics, Hydrogen-Ion Concentration, Kinetics, Light, Mutagenesis, Site-Directed, Mutation, Photolysis, Plasmids, Protons, Tyrosine chemistry, Bacteriorhodopsins metabolism, Tyrosine physiology

Abstract

Tyrosine-83, a residue which is conserved in all halobacterial retinal proteins, is located at the extracellular side in helix C of bacteriorhodopsin. Structural studies indicate that its hydroxyl group is hydrogen bonded to Trp189 and possibly to Glu194, a residue which is part of the proton release complex (PRC) in bacteriorhodopsin. To elucidate the role of Tyr83 in proton transport, we studied the Y83F and Y83N mutants. The Y83F mutation causes an 11 nm blue shift of the absorption spectrum and decreases the size of the absorption changes seen upon dark adaptation. The light-induced fast proton release, which accompanies formation of the M intermediate, is observed only at pH above 7 in Y83F. The pK(a) of the PRC in M is elevated in Y83F to about 7.3 (compared to 5.8 in WT). The rate of the recovery of the initial state (the rate of the O --> BR transition) and light-induced proton release at pH below 7 is very slow in Y83F (ca. 30 ms at pH 6). The amount of the O intermediate is decreased in Y83F despite the longer lifetime of O. The Y83N mutant shows a similar phenotype in respect to proton release. As in Y83F, the recovery of the initial state is slowed several fold in Y83N. The O intermediate is not seen in this mutant. The data indicate that the PRC is functional in Y83F and Y83N but its pK(a) in M is increased by about 1.5 pK units compared to the WT. This suggests that Tyr83 is not the main source for the proton released upon M formation in the WT; however, Tyr83 is involved in the proton release affecting the pK(a) of the PRC in M and the rate of proton transport from Asp85 to PRC during the O --> bR transition. Both the Y83F and the Y83N mutations lead to a greatly decreased functionality of the pigment at high pH because most of the pigment is converted into the inactive P480 species, with a pK(a) 8-9.

Published

2001

10. Mass spectrometric analysis of integral membrane proteins at the subnanomolar level: application to recombinant photopigments.

Author

Ablonczy Z, Kono M, Crouch RK, and Knapp DR

Subjects

Amino Acid Sequence, Animals, COS Cells, Cattle, Cyanogen Bromide chemistry, Molecular Sequence Data, Peptide Fragments analysis, Protein Conformation, Recombinant Proteins analysis, Membrane Proteins analysis, Rhodopsin analysis, Spectrometry, Mass, Electrospray Ionization methods

Abstract

Integral membrane proteins produced by eukaryotic expression systems are a subject of much current interest in biomedical investigation. Due to the low efficiency of their expression and the limited quantity of the expressed to the total amount of the membrane proteins, they have evaded mass spectrometric analysis. The methodology previously developed for mass spectrometric analysis of integral membrane proteins required proteins that were obtained relatively pure from their native membranes. The previously developed methodology has been modified and applied to the analysis of subnanomolar samples of rhodopsin. Bovine rhodopsin purified by affinity chromatography, from native membranes and from a eukaryotic expression system, was successfully analyzed, obtaining complete sequence coverage for the detection and localization of posttranslational modifications. The methodology presented here will enable mass spectrometric analysis of subnanomolar levels of photopigments or other integral membrane proteins either from their native membranes or as products of expression systems.

Published

2001

11. Intrahelical arrangement in the integral membrane protein rhodopsin investigated by site-specific chemical cleavage and mass spectrometry.

Author

Gelasco A, Crouch RK, and Knapp DR

Subjects

Amino Acid Sequence, Ascorbic Acid metabolism, Copper metabolism, Cyanogen Bromide metabolism, Cysteine metabolism, Molecular Sequence Data, Organometallic Compounds metabolism, Oxygen metabolism, Peptide Fragments analysis, Peptide Fragments chemistry, Peptide Fragments metabolism, Phenanthrolines metabolism, Protein Structure, Secondary, Membrane Proteins chemistry, Membrane Proteins metabolism, Mutagenesis, Site-Directed, Rhodopsin chemistry, Rhodopsin metabolism, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization

Abstract

Site-specific cleavage on the interhelical loop I on the cytoplasmic face of rhodopsin has been observed after activation of a Cu-phenanthroline tethered cleavage reagent attached on the cytoplasmic loop IV. The characterization of the reaction products by mass spectrometry, both of the membrane-bound protein and of the CNBr-cleaved peptides, allows the site of cleavage to be determined precisely. The specific cleavage of the peptide bond between Q64 and H65 on loop I leaves the N-terminal peptide (M1-Q64) intact, confirmed by MALDI-MS detection of the two N-linked glycosyl groups near the N-terminus of rhodopsin. The limited extension of the tether side chain requires a interresidue distance between the cleavage site, Q64, and the site of ligand attachment, C316, of less than 12 A. Upon photoactivation of the receptor, no change in the cleavage pattern is observed; however, a simulated Meta II intermediate activation state indicates a much more complex cleavage pattern. The development of this cleavage method, previously used primarily as a "chemical nuclease", in combination with mass spectrometry, may provide a powerful method on membrane protein conformation studies that can be used to complement other biophysical characterizations.

Published

2000

12. Evidence for the rate of the final step in the bacteriorhodopsin photocycle being controlled by the proton release group: R134H mutant.

Author

Lu M, Balashov SP, Ebrey TG, Chen N, Chen Y, Menick DR, and Crouch RK

Subjects

Arginine metabolism, Aspartic Acid genetics, Bacteriorhodopsins metabolism, Darkness, Halobacterium salinarum chemistry, Halobacterium salinarum genetics, Histidine metabolism, Hydrogen-Ion Concentration, Kinetics, Light, Photolysis, Purple Membrane chemistry, Purple Membrane metabolism, Arginine genetics, Bacteriorhodopsins chemistry, Bacteriorhodopsins genetics, Histidine genetics, Mutagenesis, Site-Directed, Protons

Abstract

Light absorbed by bacteriorhodopsin (bR) leads to a proton being released at the extracellular surface of the purple membrane. Structural studies as well as studies of mutants of bR indicate that several groups form a pathway for proton transfer from the Schiff base to the extracellular surface. These groups include D85, R82, E204, E194, and water molecules. Other residues may be important in tuning the initial state pK(a) values of these groups and in mediating light-induced changes of the pK(a) values. A potentially important residue is R134: it is located close to E194 and might interact electrostatically to affect the pK(a) of E194 and light-induced proton release. In this study we investigated effects of the substitution of R134 with a histidine on light-induced proton release and on the photocycle transitions associated with proton transfer. By measuring the light-induced absorption changes versus pH, we found that the R134H mutation results in an increase in the pK(a) of the proton release group in both the M (0.6 pK unit) and O (0.7 pK unit) intermediate states. This indicates the importance of R134 in tuning the pK(a) of the group that, at neutral and high pH, releases the proton upon M formation (fast proton release) and that, at low pH, releases the proton simultaneously with O decay (slow proton release). The higher pK(a) of the proton release group found in R134H correlates with the slowing of the rate of the O --> bR transition at low pH and probably is the cause of this slowing. The pH dependence of the fraction of the O intermediate is altered in R134H compared to the WT but is similar to that in the E194D mutant: a very small amount of O is present at neutral pH, but the fraction of O increases greatly upon decreasing the pH. These results provide further support for the hypothesis that the O --> bR transition is controlled by the rate of deprotonation of the proton release group. These data also provide further evidence for the importance of the R134-E194 interaction in modulating proton release from D85 after light has led to its being protonated.

Published

2000

13. Isomerization of all-trans-9- and 13-desmethylretinol by retinal pigment epithelial cells.

Author

Stecher H, Prezhdo O, Das J, Crouch RK, and Palczewski K

Subjects

Alcohol Oxidoreductases chemistry, Alcohol Oxidoreductases metabolism, Animals, Apoproteins chemistry, Apoproteins genetics, Apoproteins metabolism, Carrier Proteins chemistry, Carrier Proteins genetics, Carrier Proteins metabolism, Cattle, Diterpenes, Isomerism, Pigment Epithelium of Eye cytology, Pigment Epithelium of Eye metabolism, Protein Conformation, Quantum Theory, Retinaldehyde metabolism, Retinoids chemistry, Retinoids metabolism, Serum Albumin, Bovine physiology, Pigment Epithelium of Eye chemistry, Retinaldehyde chemistry

Abstract

Photoisomerization of 11-cis-retinal to all-trans-retinal triggers phototransduction in the retinal photoreceptor cells and causes ultimately the sensation of vision. 11-cis-Retinal is enzymatically regenerated through a complex set of reactions in adjacent retinal pigment epithelial cells (RPE). In this study using all-trans-9-desmethylretinol (lacking the C(19) methyl group) and all-trans-13-desmethylretinol (lacking the C(20) methyl group), we explored the effects of C(19) and C(20) methyl group removals on isomerization of these retinols in RPE microsomes. The C(19) methyl group may be involved in the substrate activation, whereas the C(20) methyl group causes steric hindrance with a proton in position C(10) of 11-cis-retinol; thus, removal of this group could accelerate isomerization. We found that all-trans-9-desmethylretinol and all-trans-13-desmethylretinol are isomerized to their corresponding 11-cis-alcohols, although with lower efficiencies than isomerization of all-trans-retinol to 11-cis-retinol. These findings make the mechanism of isomerization through the C(19) methyl group unlikely, because in the case of 9-desmethylretinol, the isomerization would have to progress by proton abstraction from electron-rich olefinic C(9). The differences between all-trans-retinol, all-trans-9-desmethylretinol, and all-trans-13-desmethylretinol appear to be a consequence of the enzymatic properties, and binding affinities of the isomerization system, rather than differences in the chemical or thermodynamic properties of these compounds. This observation is also supported by quantum chemical calculations. It appears that both methyl groups are not essential for the isomerization reaction and are not likely involved in formation of a transition stage during the isomerization process.

Published

1999

14. The proton release group of bacteriorhodopsin controls the rate of the final step of its photocycle at low pH.

Author

Balashov SP, Lu M, Imasheva ES, Govindjee R, Ebrey TG, Othersen B 3rd, Chen Y, Crouch RK, and Menick DR

Subjects

Aspartic Acid chemistry, Aspartic Acid genetics, Azides chemistry, Catalysis, Deuterium Oxide chemistry, Glutamic Acid chemistry, Glutamic Acid genetics, Glutamine chemistry, Glutamine genetics, Halobacterium salinarum, Hydrogen-Ion Concentration, Mathematical Computing, Models, Chemical, Mutagenesis, Site-Directed, Photochemistry, Titrimetry, Bacteriorhodopsins chemistry, Protons

Abstract

The factors determining the pH dependence of the formation and decay of the O photointermediate of the bacteriorhodopsin (bR) photocycle were investigated in the wild-type (WT) pigment and in the mutants of Glu-194 and Glu-204, key residues of the proton release group (PRG) in bR. We have found that in the WT the rate constant of O --> bR transition decreases 30-fold upon decreasing the pH from 6 to 3 with a pKa of about 4.3. D2O slows the rise and decay of the O intermediate in the WT at pH 3.5 by a factor of 5.5. We suggest that the rate of the O --> bR transition (which reflects the rate of deprotonation of the primary proton acceptor Asp-85) at low pH is controlled by the deprotonation of the PRG. To test this hypothesis, we studied the E194D mutant. We show that the pKa of the PRG in the ground state of the E194D mutant, when Asp-85 is protonated, is increased by 1.2 pK units compared to that of the WT. We found a similar increase in the pKa of the rate constant of the O --> bR transition in E194D. This provides further evidence that the rate of the O --> bR transition is controlled by the PRG. In a further test, the E194Q mutation, which disables the PRG and slows proton release, almost completely eliminates the pH dependence of O decay at pHs below 6. A second phenomenon we investigated was that in the WT at neutral and alkaline pH the fraction of the O intermediate decreases with pKa 7.5. A similar pH dependence is observed in the mutants in which the PRG is disabled, E194Q and E204Q, suggesting that the decrease in the fraction of the O intermediate with pKa ca. 7.5 is not controlled by the PRG. We propose that the group with pKa 7.5 is Asp-96. The slowing of the reprotonation of Asp-96 at high pH is the cause of the decrease in the rate of the N --> O transition, leading to the decrease in the fraction of O.

Published

1999

15. Glutamate-194 to cysteine mutation inhibits fast light-induced proton release in bacteriorhodopsin.

Author

Balashov SP, Imasheva ES, Ebrey TG, Chen N, Menick DR, and Crouch RK

Subjects

Dark Adaptation, Halobacterium, Hydrogen-Ion Concentration, Kinetics, Mutation, Spectrophotometry, Atomic, Bacteriorhodopsins metabolism, Cysteine genetics, Glutamic Acid genetics, Light, Protons

Abstract

Substitution of glutamic acid-194, a residue on the extracellular surface of bacteriorhodopsin, with a cysteine inhibits the fast light-induced proton release that normally is coupled with the deprotonation of the Schiff base during the L to M transition. Proton release in this mutant occurs at the very end of the photocycle and coincides with deprotonation of the primary proton acceptor, Asp-85, during the O to bR transition. the E194C mutation also results in a slowing down of the photocycle by about 1 order of magnitude as compared to the wild type and produces a strong effect on the pH dependence of dark adaptation that is interpreted as a drastic reduction or elimination of the coupling between the primary proton acceptor Asp-85 and the proton release group. These data indicate that Glu-194 is a critical component of the proton release complex in bacteriorhodopsin.

Published

1997

16. Proton uptake and release are rate-limiting steps in the photocycle of the bacteriorhodopsin mutant E204Q.

Author

Misra S, Govindjee R, Ebrey TG, Chen N, Ma JX, and Crouch RK

Subjects

Azides pharmacology, Bacteriorhodopsins genetics, Bacteriorhodopsins metabolism, Deuterium Oxide metabolism, Halobacterium metabolism, Hydrogen-Ion Concentration, Light, Mutagenesis, Site-Directed, Photochemistry, Protons, Purple Membrane metabolism, Temperature, Bacteriorhodopsins chemistry

Abstract

In the absence of the putative proton release group, E204, the second half of the photocycle of the E204Q mutant of bacteriorhodopsin is slowed down more than 10-fold compared to the wild type. The effects of pH and D2O on the M decay and O formation rates in E204Q suggest that proton uptake occurs concurrently with the N <--> O transition, possibly coupled with the thermal reisomerization of the retinal. Hence, one of the rate-limiting steps in the slow E204Q photocycle is proton uptake from the outside medium, coincident with the decay of the slow component of M (the N <--> O transition). The second rate-limiting step is the long lifetime of decay of the O state, due to a high activation barrier for the deprotonation of D85 in the O --> bR step of the E204Q photocycle. Addition of the weakly acidic anions azide, cyanate, or formate accelerates the decay of the O intermediate, and restores the total photocycling time to that observed in the wild-type pigment, by accelerating the deprotonation of D85. We also find that azide similarly accelerates the decay of O in the wild type under conditions in which E204 does not deprotonate during the photocycle (pH < 6). It has previously been shown that azide and other weak acids can influence proton transfers in the cytoplasmic half of the protein [Tittor, J., Soell, C., Oesterhelt, D., Butt, H.-J., & Bamberg, E. (1989) EMBO J. 8, 3477-3482]; we suggest that these weak acids can affect proton transfers in the extracellular half of the protein as well.

Published

1997

17. The two pKa's of aspartate-85 and control of thermal isomerization and proton release in the arginine-82 to lysine mutant of bacteriorhodopsin.

Author

Balashov SP, Govindjee R, Imasheva ES, Misra S, Ebrey TG, Feng Y, Crouch RK, and Menick DR

Subjects

Bacteriorhodopsins genetics, Base Sequence, DNA Primers, Darkness, Halobacterium chemistry, Hydrogen-Ion Concentration, Isomerism, Kinetics, Molecular Sequence Data, Mutagenesis, Site-Directed, Photochemistry, Spectrum Analysis, Arginine chemistry, Aspartic Acid chemistry, Bacteriorhodopsins chemistry, Lysine chemistry, Protons

Abstract

To explore the role of Arg82 in the catalysis of proton transfer in bacteriorhodopsin, we replaced Arg82 with Lys, which is also positively charged at neutral pH but has an intrinsic pKa of about 1.7 pH units lower than that of Arg. In the R82K mutant expressed in Halobacterium salinarium, we found the following: (1) The pKa of the purple-to-blue transition at low pH (which reflects the pKa of Asp85) is 3.6 +/- 0.1. At high pH a second inflection in the blue-to-purple transition with pKa = 8.0 is found. The complex titration behavior of Asp85 indicates that the pKa of Asp85 depends on the protonation state of another amino acid residue, X', which has a pKa = 8.0 in R82K. The fit of the experimental data to a model of two interacting residues shows that deprotonation of X' at high pH causes a shift in the pKa of Asp85 from 3.7 to 6.0. In turn, protonation of Asp85 decreases the pKa of X' by 2.3 pH units. This suggests that X' can release a proton upon formation of the M intermediate and the concomitant protonation of Asp85 in the photocycle. (2) The rate constant of dark adaptation, kda, is proportional to the fraction of blue membrane between pH 2 and 10, indicating that thermal isomerization proceeds through the transient protonation of Asp85. The pH dependence of kda shows that two groups with pKal = 3.9 and pKa2 = 8.0 control the rate of dark adaptation in R82K. The 1.7 pH unit shift in pKa2 in R82K compared to the wild type (WT) (pKa2 = 9.7) supports the hypothesis that X' is Arg82 in WT and Lys82 in R82K (or at least that these groups are the principal part of a cluster of residues that constitute X'). (3) Under steady state illumination, the efficiency of proton transport in R82K incorporated in phosphatidylcholine vesicles is at least 40% of that in the WT. A flash-induced transient signal of the pH-sensitive dye pyranine is similar to that in the WT (proton release precedes uptake), but the amplitude is small in R82K (about 15% of that found in the WT), indicating that only a small fraction of protons is released fast in R82K. This supports the suggestions that Arg82 is associated with the proton release pathway (acts as a proton release group or part of a proton release complex) and that Lys cannot efficiently substitute for Arg in this process.(ABSTRACT TRUNCATED AT 400 WORDS)

Published

1995

18. Rod outer segment retinol dehydrogenase: substrate specificity and role in phototransduction.

Author

Palczewski K, Jäger S, Buczyłko J, Crouch RK, Bredberg DL, Hofmann KP, Asson-Batres MA, and Saari JC

Subjects

Alcohol Oxidoreductases antagonists & inhibitors, Animals, Catalysis, Cattle, GTP-Binding Proteins metabolism, Kinetics, Membranes enzymology, Photochemistry, Retinaldehyde metabolism, Rhodopsin metabolism, Rod Opsins metabolism, Substrate Specificity, Terpenes pharmacology, Tretinoin metabolism, Alcohol Oxidoreductases metabolism, Norisoprenoids, Rod Cell Outer Segment enzymology

Abstract

The reaction catalyzed by all-trans-retinol dehydrogenase of rod outer segments completes the quenching of photoactivated rhodopsin and initiates the cycle of reactions leading to regeneration of visual pigment. The goal of this study was to determine the kinetic parameters of the dehydrogenase at physiological levels of bleaching, to investigate its specificity, and to determine its possible role in modulating phototransduction. Reduction of all-trans-retinal could be measured after bleaching < 0.15% rhodopsin. Kinetic parameters for the forward reaction determined with endogenous all-trans-retinal were Km = 1.1 microM; Vmax = 7 nmol/min/mg rhodopsin. The low enzymatic activity suggests that at high bleach rates, all-trans-retinal could accumulate, increasing the steady state level of bleaching intermediates or promoting formation of pseudophotoproducts. Active pseudophotoproducts, which stimulate Gt activation and opsin phosphorylation by rhodopsin kinase, are formed with opsin and all-trans-retinal as well as retinal analogues lacking the 13 methyl or the terminal two carbons of the polyene chain. Addition of all-trans-retinol, NADP, and [32P]ATP to rod outer segments increased rhodopsin phosphorylation. Kinetic parameters for the reverse reaction determined with exogenous all-trans-retinol were Km = 10 microM; Vmax = 11 nmol/min/mg rhodopsin. Our results support the hypothesis that all-trans-retinol dehydrogenase could influence the phototransduction cascade, including activities of Gt, rhodopsin kinase, and binding of arrestin, by impeding the recycling of rhodopsin at high bleach levels.

Published

1994

19. Probing of the retinal binding site of bacteriorhodopsin by affinity labeling.

Author

Feng Y, Menick DR, Katz BM, Beischel CJ, Hazard ES, Misra S, Ebrey TG, and Crouch RK

Subjects

Affinity Labels, Amino Acid Sequence, Bacteriorhodopsins chemistry, Bacteriorhodopsins genetics, Binding Sites genetics, Cross-Linking Reagents, Cysteine chemistry, Cysteine genetics, Escherichia coli genetics, Halobacterium salinarum genetics, Models, Molecular, Molecular Sequence Data, Mutagenesis, Site-Directed, Proton Pumps, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Retinaldehyde chemistry, Sequence Analysis, DNA, Bacteriorhodopsins metabolism, Halobacterium salinarum metabolism, Retinaldehyde analogs & derivatives, Retinaldehyde metabolism

Abstract

The position of the chromophore within bacteriorhodopsin has been identified by cross-linking a cysteine group, introduced by site-specific mutagenesis, with a chromophore suitably derivatized with an active leaving group. Since bacteriorhodopsin has no cysteines, a site-specific cysteine mutant will contain only one free sulfhydryl group capable of reacting with the retinal analog. Met118, Thr121, and Ser141 were selected to be mutated to cysteine. No pigment absorbing in the visible region was obtained for the Ser141Cys mutant. The Met118Cys and Thr121Cys mutants have similar absorption maxima, proton pumping efficiencies and photocycles to those of the wild-type pigment. 4-Bromoretinal, in which the reactive allylic halide readily undergoes nucleophilic displacement, was used as the reactive chromophore. Pigments were obtained on reaction of all-trans-4-bromoretinal with the apoproteins of Met118Cys, Thr121Cys, and wild-type bacteriorhodopsin (lambda max = 464-470 nm). Analysis of the denatured pigments on SDS-polyacrylamide gels showed incorporation of tritiated chromophore into the Met118Cys mutant but not into the wild-type or Th4121Cys pigments. Met118Cys apoprotein which was preincubated with the cysteine-specific reagent N-ethylmaleimide formed a pigment with 4-bromoretinal but no cross-linking was observed, providing evidence that the cross-linking of the chromophore is to the cysteine at 118. We conclude that Met118 is positioned in the chromophore binding pocket, proximal to the C-4 position of cyclohexyl ring of retinal.

Published

1994

20. Effect of the arginine-82 to alanine mutation in bacteriorhodopsin on dark adaptation, proton release, and the photochemical cycle.

Author

Balashov SP, Govindjee R, Kono M, Imasheva E, Lukashev E, Ebrey TG, Crouch RK, Menick DR, and Feng Y

Subjects

Bacteriorhodopsins genetics, Bacteriorhodopsins metabolism, Base Sequence, Blotting, Southern, Escherichia coli genetics, Halobacterium salinarum chemistry, Hydrogen-Ion Concentration, Kinetics, Light, Liposomes metabolism, Molecular Sequence Data, Photochemistry, Protein Denaturation, Spectrophotometry, Alanine, Arginine, Bacteriorhodopsins chemistry, Dark Adaptation, Mutagenesis, Site-Directed, Protons

Abstract

The pH dependence of the rate constant of dark adaptation (thermal isomerization from all-trans- to 13-cis-bR) drastically changes when Arg82 of bacteriorhodopsin is replaced by an alanine. In the wild type (WT) the rate decreases sharply between pH 2.5 and pH 5. In R82A the sharp decrease is shifted to pH > 7. This correlates with the shift in the pK of the purple-to-blue transition from pH 2.6 in the wild type to pH 7.2 in the mutant (in 150 mM KCl). We propose that the same group that controls the purple-to-blue transition, namely, Asp85, catalyzes dark adaptation. The rate of dark adaptation in the R82A mutant is proportional to the fraction of protonated Asp85, indicating that dark adaptation occurs when Asp85 is transiently protonated. Thermal isomerization is at least 2 x 10(3) times more likely when Asp85 is protonated (blue membrane) than when it is deprotonated (purple membrane). The pH dependence of dark adaptation in the WT can be explained by a model in which the rate of dark adaptation in the WT is also proportional to the fraction of protonated Asp85 and that the pK of Asp85 depends on some other group, X, which deprotonates (or moves away from Asp85) with pK9 and causes the shift in the pK of Asp85 from 2.6 to 7.2. The quantum yield of light adaptation is at least an order of magnitude less in R82A as compared to the WT. The rise time of M formation is very fast in R82A and, unlike the WT, pH independent (1 microsecond versus 85 and 6 microseconds in the WT at pH 7 and 10, respectively). The activation energy of the L to M transition is 6.9 kcal/mol versus 13.5 kcal/mol in the WT. Thus the loss of a positive charge in the active site greatly increases the rate of light-induced deprotonation of the Schiff base. In the R82A mutant, the M decay at pH > 8.8 is much faster than the recovery of initial bR, which suggests a decrease in the rate of back-reaction from N to M. In a suspension of R82A membranes the rate of proton release as measured by the pH-sensitive dye pyranine is delayed by at least 20-fold (in 2 M KCl), while the uptake of protons did not change much (12 ms in the WT versus 8 ms in R82A).(ABSTRACT TRUNCATED AT 400 WORDS)

Published

1993

21. Mass spectrometric identification of phosphorylation sites in bleached bovine rhodopsin.

Author

Papac DI, Oatis JE Jr, Crouch RK, and Knapp DR

Subjects

Amino Acid Sequence, Animals, Cattle, Chromatography, High Pressure Liquid, Mass Spectrometry, Molecular Sequence Data, Peptide Fragments chemistry, Phosphorylation, Reference Standards, Rhodopsin chemistry

Abstract

Deactivation of the visual cascade is initiated by the phosphorylation of rhodopsin. We report here identification of the two major sites of phosphorylation in bleached bovine rhodopsin using tandem mass spectrometry in conjunction with synthetic phosphopeptide standards. Both bleached and unbleached rod outer segments were cleaved with endoproteinase Asp-N to release the C-terminal fragment, residues 330-348, containing seven potential sites of phosphorylation. High-performance liquid chromatographic separation of soluble cleavage products from both unbleached and bleached rod outer segments gave a peak which was identified by tandem mass spectrometry and comparison to synthetic standards as monophosphorylated (serine 338) DDEASTTVSKTETSQVAPA. Present only in the chromatogram of bleached ROS were two peaks identified as monophosphorylated (serine 343) and diphosphorylated (serines 338 and 343) derivatives of DDEASTTVSKTETSQVAPA. These results identify serines 338 and 343 as the major sites of phosphorylation within the C-terminal region of bleached bovine rhodopsin and constitute the first example of mass spectrometric characterization of phosphorylation sites in a G-protein coupled receptor.

Published

1993

22. Letter: Allenic retinals and visual pigment analogues.

Author

Nakanishi K, Yudd AP, Crouch RK, Olson GL, Cheung HC, Govindjee R, Ebrey TG, and Patel DJ

Subjects

Rhodopsin analogs & derivatives, Spectrum Analysis, Stereoisomerism, Retinal Pigments chemical synthesis

Published

1976

23. Effect of variation of retinal polyene side-chain length on formation and function of bacteriorhodopsin analogue pigments.

Author

Zingoni J, Or YS, Crouch RK, Chang CH, Govindjee R, and Ebrey TG

Subjects

Halobacterium metabolism, Retinaldehyde analogs & derivatives, Retinaldehyde chemical synthesis, Structure-Activity Relationship, Bacteriorhodopsins metabolism, Carotenoids metabolism, Retinaldehyde metabolism, Retinoids metabolism

Abstract

The effect of the length of the retinal polyene side chain on bacterioopsin pigment formation and function has been investigated with two series of synthetic retinal analogues. Cyclohexyl derivatives with polyene chains one carbon longer and one or more carbons shorter than retinal and linear polyenes with no ring have been synthesized and characterized. Compounds of six carbons or less in the polyene chain form pigments very poorly or not at all with bacterioopsin. Compounds containing at least seven carbons in the chain are found to form reasonably stable bacterioopsin pigments that show a small shift in absorbance on irradiation. However, photocycling and proton photorelease are not detected. The analogue with nine carbons in the polyene chain (one less than retinal) forms a stable pigment with an M-type intermediate but demonstrates reduced amounts of photocycling and light-activated proton release. The analogue with a polyene chain identical with that of retinal, but containing no ring, forms a pigment that shows both an efficient light-activated proton photocycle and release. The pigment containing the chromophore with the polyene chain one carbon longer than retinal is likewise fully active. We thus conclude that the length of the polyene chain must be at least 9 carbons for the formation of a stable pigment that photocycles and must be 10 carbons for both the photocycle and light-activated proton release to have a high quantum efficiency.

Published

1986

24. Analogue pigment studies of chromophore-protein interactions in metarhodopsins.

Author

Renk G and Crouch RK

Subjects

Animals, Cattle, Electron Spin Resonance Spectroscopy, Hydrogen-Ion Concentration, Protein Binding, Retinaldehyde analogs & derivatives, Retinaldehyde chemical synthesis, Rhodopsin analogs & derivatives, Rod Cell Outer Segment metabolism, Spectrophotometry, Structure-Activity Relationship, Retinal Pigments metabolism, Retinaldehyde metabolism, Retinoids metabolism, Rhodopsin metabolism

Abstract

Several analogue pigments have been prepared containing retinals altered at the cyclohexyl ring or proximal to the aldehyde group in order to examine the role of the chromophore in the formation of the metarhodopsin I and II states of visual pigments. Deletion of the 13-methyl group on the isoprenoid chain did not affect metarhodopsin formation. However, analogue pigments containing chromophores with modified rings did not show the typical absorption changes associated with the metarhodopsin transitions of native or regenerated rhodopsins. In particular, 4-hydroxyretinal pigments did not show clear transitions between the metarhodopsin I and metarhodopsin II states. Pigment formed with an acyclic retinal showed no evidence by absorption spectroscopy of metarhodopsin formation. A retinal altered by substitution of a five-membered ring containing a nitroxide required a more acidic pH than the native pigment for formation of the metarhodopsin II state. ESR data suggest that the ring remains buried within the protein through the metarhodopsin II state. However, the Schiff base linkage is susceptible to hydrolysis of hydroxylamine in the metarhodopsin II state. These data indicate that (1), in the transition from rhodopsin to metarhodopsin II, major protein conformational changes are occurring near the lysine-retinal linkage whereas the ring portion of the chromophore remains deeply buried within the protein and (2) pigment absorptions characteristic of the metarhodopsin I and II states may be due to specific protein-chromophore interactions near the region of the chromophore ring.

Published

1989