Rhodopsin phosphorylation in rats exposed to intense light.

The damaging effects of intense light on the rat retina are known to vary depending on the time of day of exposure. The purpose of this study was to determine if rhodopsin phosphorylation patterns, a measure of the activity of the pigment, varied in a similar manner. After 10 min in strong light (1400 lux), all six threonine and serine sites in the rat rhodopsin C-terminus were phosphorylated, with mono- to tetraphosphorylation being substantially more prominent than penta- to hexaphosphorylation. The level and multiplicity of rhodopsin phosphorylations were reduced both with the duration of light exposure and the duration of subsequent darkness. Although showing vast differences in susceptibility to light damage, rats exposed at 5 P.M. or 1 A.M. showed similar rhodopsin phosphorylation levels and patterns. These data indicate that a process controlled by circadian rhythm other than rhodopsin phosphorylation is involved either in damaging or mediating the damage evoked by intense light exposure.

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

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.

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

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.

Expression, purification, and MALDI analysis of RPE65.

PURPOSE: RPE65 is preferentially expressed in the retinal pigment epithelium (RPE) and is essential for retinal function. The purpose of the study was to develop methods for the expression of the protein, determine the accurate molecular weight of this expressed protein, and quantitate the amount of RPE65 in the bovine RPE. METHODS: Human RPE65 was expressed in Sf9 cells using the baculovirus system. The subcellular localization was determined by Western blot analysis and immunocytochemistry. An ELISA was developed for RPE65 and used to measure levels in bovine RPE. Recombinant and native RPE65 were purified by affinity chromatography. Molecular mass was determined by matrix-assisted laser desorption/ionization (MALDI) mass spectrometry. RESULTS: Recombinant human (rH)RPE65 was expressed as a major protein associated with cell membrane in Sf9 cells. The recombinant protein was purified to apparent homogeneity from both the membrane and nonmembrane fractions. The identity of the purified protein was confirmed by Western blot analysis and by partial peptide sequencing. rHRPE65 from the nonmembrane fraction has a mass of 64,867 +/- 80 which is close to the calculated molecular weight from the amino acid sequence including the His-tag (64,663), whereas the membrane-associated rHRPE65 has a molecular mass of 65,380 +/- 150, which is significantly higher than that of the non-membrane-associated form and the calculated molecular weight, suggesting posttranslational modifications. Similarly, native RPE65 was detected in the cytosolic and microsomal fractions of the bovine RPE, with an average level of 3.8 +/- 1.3 and 7.2 +/- 0.4 microg RPE65 per eye, respectively. The cytosolic form had a molecular mass of 61,161 +/- 60, which is close to the calculated value (60,944), whereas that of the microsomal form was 61,961 +/- 170. CONCLUSIONS: RPE65 is expressed in two forms, one of which is membrane associated and contains significant posttranslational modifications, similar to the native membrane-associated form.

Mass spectrometric analysis of rhodopsin from light damaged rats.

PURPOSE: It is well established that the retina is damaged by intense visible light. Rhodopsin has been proposed to be involved in this process. We therefore undertook to examine whether rhodopsin isolated from light damaged animals is structurally altered at the molecular level. METHODS: Dark reared and dim cyclic light reared 8 week old Sprague-Dawley rats were exposed to intense visible light and sacrificed immediately or 24 h after exposure together with unexposed control animals reared under the same conditions. Rod outer segments were isolated by sucrose gradient ultracentrifugation, their membranes treated with urea, then washed with Tris buffer. The rhodopsin preparations were then reduced, pyridylethylated, delipidated, and cleaved with CNBr. Reversed phase HPLC was used to separate the fragments, and the effluent was analyzed online with a Finnigan LCQ ion trap mass spectrometer. C-terminal phosphorylation was investigated following Asp-N cleavage. MALDI-TOF mass spectrometry was used for the identification of glycosylation. RESULTS: The rat rhodopsin protein was mapped with the exception of two single amino acid fragments. The reported sequence was confirmed with the exception of the controversial T/S320 residue, which was found to be a threonine. Mono-, di-, tri-, and tetraphosphorylated forms of rhodopsin were found in the light damaged animals. Three sites of phosphorylation were confirmed with MS/MS (tandem mass spectral) data. Single or double phosphorylations were found among these three sites, in various combinations. Dark adaptation completely reversed the phosphorylation in all light damaged animals. Other posttranslational modifications were as previously reported. CONCLUSIONS: Our results indicate that intense visible light exposure of rats does not lead to oxidative or other primary structural alterations in the rhodopsin protein of rod outer segments. We also report that the mutated rhodopsin (P23H) is present in rat rod outer segments from heterozygous animals and that residue 320 in both normal and mutated rhodopsins is threonine, not serine.

Actinic light and pH effect on the proton pumping of bacteriorhodopsin.

The actinic light effect on the bacteriorhodopsin (BR) photocycle kinetics led to the assumption of a cooperative interaction between the photocycling BR molecules. In this paper we report the results of the actinic light effect and pH on the proton release and uptake kinetics. An electrical method is applied to detect proton release and uptake during the photocycle [E. Papp, G. Fricsovszky, J. Photochem. Photobiol. B: Biol. 5 (1990) 321]. The BR photocycle kinetics was also studied by absorption kinetics measurements at 410 nm and the data were analyzed by the local analysis of the M state kinetics [E. Papp, V.H. Ha, Biophys. Chem. 57 (1996) 155]. While at high pH and ionic strength, we found a similar behavior as reported earlier, at low ionic strength the light effect proved to be more complex. The main conclusions are the following: Though the number of BR excited to the photocycle (fraction cycling, fc) goes to saturation with increasing laser pulse energy, the absorbed energy by BR increases linearly with pulse energy. From the local analysis we conclude that the light effect changes the kinetics much earlier, already at the L intermediate state decay. The transient electric signal, caused by proton release and uptake, can be decomposed into two components similarly to the absorption kinetic data of the M intermediate state. The actinic light energy affects mainly the ratio of the two components and the proton movements inside BR while pH has an effect on the kinetics of the proton release and uptake groups at the membrane surface.