Depalmitylation with hydroxylamine alters the functional properties of rhodopsin

Rhodopsin, the photosensitive protein found in rod photoreceptors, has two covalently attached palmitates that are thought to anchor a portion of the C terminus to the disc membrane, forming a fourth cytoplasmic loop. Using hydroxylamine (NH2OH) to cleave the thioester linkage, we have characterized the effect of depalmitylation on certain functional properties of rhodopsin. Treatment of rod outer segment membranes (prepared from rat retinas previously labeled in vivo with [3H]palmitate) with 1 M NH2OH typically removed greater than or equal to 75% of the [3H]palmitate initially bound to rhodopsin. Spectrophotometry of rod outer segment membranes that had been treated with 1 M NH2OH indicated preservation of 85% of the native rhodopsin and no effect on the shape of the absorbance spectrum of rhodopsin. In vivo labeled rhodopsin that had been treated with 1 M NH2OH did not reincorporate free endogenous [3H] palmitate over a 2-h incubation period. Both NH2OH-treated and untreated rhodopsin incorporated [14C]palmitate from exogenously added [14C]palmitoyl-CoA. This incorporation was substantially greater in the NH2OH-treated sample. The removal of palmitate by NH2OH inhibited rhodopsin regeneration by 44% and increased the ability of rhodopsin to activate transducin's light-dependent GTPase activity by 61%. However, the removal of palmitate from rhodopsin did not affect the light-dependent binding of transducin (T alpha and T beta gamma).     

Light-induced binding of 48-kDa protein to photoreceptor membranes is highly enhanced by phosphorylation of rhodopsin

The 48-kDa protein, a major protein of rod photoreceptor cells, is soluble in the dark but associates with the disk membranes when some (5-10%) of their rhodopsin has absorbed light and if this rhodopsin is additionally phosphorylated by ATP and rhodopsin kinase. If rhodopsin has been phosphorylated and regenerated prior to the protein binding experiment, the binding of 48-kDa protein depends on light but no longer on the presence of ATP. Another photoreceptor protein, GTP-binding protein, associates with both phosphorylated and unphosphorylated rhodopsin upon illumination. Excess GTP-binding protein thereby displaces 48-kDa protein from phosphorylated disks; this indicates competition between these two proteins for binding sites on illuminated phosphorylated rhodopsin molecules.     

The influence of arrestin (48K protein) and rhodopsin kinase on visual transduction.

The shutoff of the phototransduction cascade in retinal rods requires the inactivation of light-activated rhodopsin. The underlying mechanisms were studied in functionally intact detached rod outer segments by testing the effect of either sangivamycin, an inhibitor of rhodopsin kinase, or phytic acid, an inhibitor of 48K protein binding to phosphorylated rhodopsin, on light responses recorded in whole-cell voltage clamp. The results suggest that isomerized rhodopsin is inactivated fully by multiple phosphorylation and that the binding of 48K protein accelerates recovery by quenching partially phosphorylated rhodopsin. Higher concentrations of sangivamycin cause changes in the light response that cannot be explained by selective inhibition of rhodopsin kinase and suggest that other protein kinases are needed for normal rod function.     

Light-induced interaction between rhodopsin and the GTP-binding protein. Metarhodopsin II is the major photoproduct involved

We have previously described [H, Kühn et al. (1981) Proc. Natl Acad. Sci. USA, 78, 6873-6877] a light-induced scattering change ('binding signal') associated with a stoichiometric binding between photoexcited rhodopsin and a peripheral membrane protein, the GTP-binding protein, in bovine rod outer segment suspensions. We have attempted here to identify the rhodopsin intermediate R* which is responsible for this interaction, by studying its dependence on pH, temperature and ionic strength. The results strongly suggest that the active state is metarhodopsin II (M II). 1. The initial phase of the binding signal is slightly slower than the formation of metarhodopsin II (2-37 degrees C, pH 5.5-9). 2. The kinetics of the decay of the active rhodopsin state are similar to those of the metarhodopsin II leads to metarhodopsin III transition (37 degrees C, pH 7.3). 3. All conditions which lead to light-induced binding of the GTP-binding protein to R* also lead to the formation of M II. At 2 degrees C, pH 8.3, in particular where no M II is formed in the absence of GTP-binding protein, binding signals and light-induced attachment of the GTP-binding protein to the membrane are still observed. Consistently, addition of GTP-binding protein to a suspension of extracted membranes bleached at 2 degrees C (pH 8.3) shifts the metarhodopsin I in equilibrium metarhodopsin II equilibrium towards metarhodopsin II. The shift is reversed by GTP, which dissociates the rhodopsin--GTP-binding protein complex. 4. At low ionic strength, where the GTP-binding protein is soluble in the dark (instead of being associated to the membrane as in the above experiments) M II still induces the binding whereas M I does not, indicating a much lower affinity of the GTP-binding protein for MI.     

A kinetic model of the interaction of stable GTP analogs with a system of opioid receptors

The effect of a stable GTP analog, GppNp, on the agonist binding to rat brain opioid receptors was studied. It was shown that the nucleotide used at low concentrations activates, and at high concentrations inhibits the ligand interaction with the mu-, delta- and kappa-receptors. The inhibiting effect of GppNp on the formation of the morphine and D-Ala2, D-Leu5-enkephalin complexes with high affinity opioid receptor binding sites is due to the decrease of the ligand affinity for the corresponding sites. A kinetic model of the GppNp effect on high affinity binding sites stipulating that in the course of nucleotide binding the GTP-binding protein dissociates and that the N-protein alpha-subunits thereby formed are liberated into the surrounding solution, was proposed. It was demonstrated that GppNp can modulate the properties of opioid receptors in the absence of the ligand in a system and the inhibiting effect of GppNp depends on the concentration of membrane preparation.     

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

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.     

Effect of calmodulin on the structural state of photoreceptor membranes and rhodopsin-containing phospholipid vesicles

The effect of calmodulin on the order of lipids in rhodopsin-free and rhodopsin-containing membranes has been studied using spin-label electron spin resonance methods. Calmodulin, up to 10(-6)M, did not change the measured order of lipids in bilayer membranes containing only rhodopsin. However, for bovine rod outer segment disc membranes, which contain rhodopsin and other proteins, calmodulin induced a significant concentration and temperature dependent increase in the order of the membrane lipids. This suggests that the site of calmodulin binding is remote from rhodopsin itself, and the nature of the binding appears to be a membrane surface phenomenon.     

Production of antibodies against rhodopsin after immunization with beta gamma-subunits of transducin: evidence for interaction of beta gamma-subunits of guanosine 5'-triphosphate binding proteins with receptor

The light-detecting system of retinal rod outer segments is regulated by a guanyl nucleotide binding (G) protein, transducin, which is composed of alpha-, beta-, and gamma-subunits. Transducin couples rhodopsin to the intracellular effector enzyme, a cGMP phosphodiesterase. The beta gamma complex (T beta gamma) is required for the alpha-subunit (T alpha) to interact effectively with the photon receptor rhodopsin. It is not clear, however, whether T beta gamma binds directly to rhodopsin or promotes T alpha binding to rhodopsin only by binding to T alpha. We have found that serum from rabbits immunized with T beta gamma contained a population of antibodies that were reactive against rhodopsin. These antibodies could be separated from T beta gamma antibodies by absorbing the latter on immobilized transducin. Binding of purified rhodopsin antibodies was inhibited by T beta gamma, suggesting that the rhodopsin antibodies and T beta gamma bound to the same site on rhodopsin. We propose that the rhodopsin antibodies act both as antiidiotypic antibodies against the idiotypic T beta gamma antibodies and as antibodies against rhodopsin. This hypothesis is consistent with the conclusion that T beta gamma interacts directly with the receptor. It is probable that in an analogous way, G beta gamma interacts directly with receptors of the adenylate cyclase system.     

Interaction between photoexcited rhodopsin and peripheral enzymes in frog retinal rods. Influence on the postmetarhodopsin II decay and phosphorylation rate of rhodopsin

The major peripheral and soluble proteins in frog rod outer segment preparations, and their interactions with photoexcited rhodopsin, have been compared to those in cattle rod outer segments and found to be similar in both systems. In particular the GTP-binding protein (G) has the same subunit composition, the same abundance relative to rhodopsin (1/10) and it undergoes the same light and nucleotide-dependent interactions with rhodopsin in both preparations. Previous work on cattle rod outer segments has shown that photoexcited rhodopsin (R*), in a state identified with metarhodopsin II, associates with the G protein as a first step to the light-activated GDP/GTP exchange on G. The complex R*-G is stable in absence of GTP, but is rapidly dissociated by GTP owing to the GDP/GTP exchange reaction. Low bleaching extents (less than 10% R*) in absence of GTP therefore create predominantly R*-G complexes, whereas bleaching in presence of GTP creates free R*. We report here that, under conditions of complexed R*, two reactions of R* in frog rod outer segments are highly perturbed as compared to free R*: (a) the spectral decay of metarhodopsin II (MII) into later photoproducts, and (b) the phosphorylation of R* by an ATP-dependent protein kinase. a) The spectral measurements have been performed using linear dichroism on oriented frog rod outer segments; this technique allows discrimination between MII and later photoproducts absorbing at the same wavelength. Association of R* with G leads to a strong reduction of the amount of MIII formed and to an acceleration of the decay of MIII. Furthermore, MII is significantly stabilized, in agreement with the hypothesis that MII is the intermediate which binds to G. b) The phosphorylation of R* is strongly inhibited under conditions of R*-G complex formation as compared to free R*. Interferences between reactions at the three sites involved in R* are discussed: the retinal binding site in the hydrophobic core is sensitive to the presence of GTP-binding protein at its binding site on the cytoplasmic surface of R*; the kinase and the GTP-binding protein compete for access to their respective binding sites, both located on the surface of R*. We also observed a slow and nucleotide-dependent light-induced binding of a protein of molecular weight 50 000, which we consider as the equivalent of the 48 000 Mr light-dependent protein previously identified in cattle rod outer segments.     

Chemical modification of transducin with dansyl chloride hinders its binding to light-activated rhodopsin

Transducin (T), the heterotrimeric guanine nucleotide binding protein in rod outer segments, serves as an intermediary between the receptor protein, rhodopsin, and the effector protein, cGMP phosphodiesterase. Labeling of T with dansyl chloride (DnsCl) inhibited its light-dependent guanine nucleotide binding activity. Conversely, DnsCl had no effect on the functionality of rhodopsin. Approximately 2-3 mol of DnsCl were incorporated per mole of T. Since fluoroaluminate was capable of activating DnsCl-modified T, this lysine-specific labeling compound did not affect the guanine nucleotide-binding pocket of T. However, the labeling of T with DnsCl hindered its binding to photoexcited rhodopsin, as shown by sedimentation experiments. Additionally, rhodopsin completely protected against the DnsCl inactivation of T. These results demonstrated the existence of functional lysines on T that are located in the proximity of the interaction site with the photoreceptor protein.     

Biochemical aspects of the visual process,XXXV. Calcium binding by cattle rod outer segment membranes studied by means of equilibrium dialysis

The calcium binding capacity of cattle rod outer segment membranes has been studied by means of an equilibrium dialysis technique. The binding is not affected by prior lyophilization of the membranes or by the presence of ionophore A23187, indicating that only passive binding to membranes is involved without active translocation.The amount of calcium bound to the membranes is influenced by the ionic composition of the medium. Both Na⁺ and K⁺ decrease binding to about the same degree, but the size of the effects suggests a rather high specificity of the calcium binding sites on the membrane.From Scatchard plots for the amount of calcium bound as a function of the free calcium concentration, it appears that two types of binding sites exist: high affinity sites which can accommodate 5 nmol calcium per mg protein (0.3 mol. calcium/mol rhodopsin) and low affinity sites which can accommodate 195 nmol calcium per mg protein (13 mol calcium/mol rhodopsin). Depending on the medium composition, the high affinity sites show dissociation constants between 8 and 40 μM, and the low affinity sites between 0.3 and 1.6 mM.Illuminated rod outer segment membranes show a slight decrease of calcium binding as compared to dark-kept membranes, but the effect is independent of the amount of calcium bound and does not appear to be significant.From these findings and the assumption of a free calcium concentration of approx. 1 μM in the extrasaccular space in rod outer segments in vivo, it is concluded that mere passive binding to the rod sac membranes must be insufficient to explain the high calcium contents in rod outer segments.     

Phosphorylation of rhodopsin by protein kinase C in vitro

Calium/phospholipid-dependent protein kinase (protein kinase C) was purified from bovine retinae rod outer segments (ROS). In the presence of 0.1-2 microM calcium protein kinase C binds tightly to ROS and phosphorylates rhodopsin in the absence or presence of illumination. This property of protein kinase C contrasts with that of rhodopsin kinase, which in vitro phosphorylates only bleached rhodopsin. Peptide maps of rhodopsin phosphorylated by protein kinase C or rhodopsin kinase were compared using limited Staphylococcus aureus V8 protease digestion or complete tryptic digestion. Phosphorylation sites map to serine and threonine residues on the cytoplasmic carboxylterminal domain of rhodopsin for both kinases. The functional consequence of protein kinase C phosphorylation of rhodopsin was a reduced ability to stimulate the light-dependent rhodopsin activation of [35S]guanosine 5'-O-(thiotriphosphate) binding to transducin, the GTP-binding regulatory protein present in ROS. Properties of the calcium-stimulated interaction of protein kinase C with membranes and in vitro phosphorylation of intrinsic proteins are discussed based upon the findings.     

Regulation of rhodopsin dephosphorylation by arrestin

We have characterized the opsin phosphatase activities in extracts of rod outer segments and determined their relationship to known protein phosphatases. The opsin phosphatase activity in the extracts was not due to protein phosphatases 1, 2B, or 2C because it was neither stimulated by Mg2+ or Ca2+/calmodulin nor inhibited by protein phosphatase inhibitors-1 or -2. Opsin phosphatase activity in rod outer segment extracts was potently inhibited by okadaic acid (IC50 approximately 10 nM), a preferential inhibitor of protein phosphatase 2A. Moreover, during chromatography on DEAE-Sepharose, the opsin phosphatase activity co-eluted with three peaks of protein phosphatase 2A activity, termed protein phosphatases 2A0, 2A1, and 2A2. The opsin phosphatase activity of each peak was stimulated by polylysine, a known activator of protein phosphatase 2A. Finally, treatment of rod outer segment extracts with 80% ethanol at room temperature converted the activity from a high molecular weight form characteristic of the protein phosphatase 2A0, 2A1, and 2A2 species to a low molecular weight form characteristic of the protein phosphatase 2A catalytic subunit. We conclude that protein phosphatase 2A is likely to be the physiologically relevant rhodopsin phosphatase. The 48-kDa rod outer segment protein arrestin (S-antigen) was found to inhibit the dephosphorylation of freshly photolyzed rhodopsin by protein phosphatase 2A but did not inhibit the dephosphorylation of unbleached rhodopsin. Arrestin has no effect on the dephosphorylation of phorphorylase a, indicating that the effect was substrate-directed. It appears that dephosphorylation of the photoreceptor protein phosphorhodopsin occurs only after decay of the photoactivated protein and that this may be regulated in vivo by arrestin. The binding of arrestin to photolyzed phosphorylated rhodopsin, i.e. the binding of a regulatory protein to a protein phosphatase substrate to form a complex resistant to dephosphorylation represents a novel mechanism for the regulation of protein phosphatase 2A.     

Direct observation of the complex formation of GDP-bound transducin with the rhodopsin intermediate having a visible absorption maximum in rod outer segment membranes

Rhodopsin is a photoreceptive protein that is present in rod photoreceptor cells, inducing a GDP-GTP exchange reaction on the retinal G-protein transducin (Gt) upon light absorption. This exchange reaction proceeds through at least three steps, which include the binding of photoactivated rhodopsin to GDP-bound Gt, the dissociation of GDP from the rhodopsin-Gt complex, and the binding of GTP to the nucleotide-unbound Gt. These steps have been thought to occur after the formation of the rhodopsin intermediate, meta-II; however, the extra formation of meta-II, which reflects the formation of a complex with Gt, was inhibited in the presence of excess GDP. Here, we use a newly developed CCD spectrophotometer to show that a meta-II precursor, meta-Ib, which has an absorption maximum at visible region, can bind to Gt in its GDP-bound form in urea-washed bovine rod outer segment membranes. The affinity of meta-Ib for GDP-bound Gt is about two times less than that of meta-II for GDP-unbound Gt, indicating that the extra formation of meta-II is observed at equilibrium even in the presence of the meta-Ib-Gt complex. This is the first identification of a complex that includes the GDP-bound form of G protein. Our results strongly suggest that the protein conformational change of the rhodopsin intermediate after binding to Gt is important for the induction of the nucleotide release from the alpha-subunit of Gt.     

Ca2+ binding capacity of cytoplasmic proteins from rod photoreceptors is mainly due to arrestin

Arrestin (also called S-antigen or 48-kDa protein) binds to photoexcited and phosphorylated rhodopsin and, thereby, blocks competitively the activation of transducin. Using Ca2+ titration in the presence of the indicator arsenazo III and 45Ca2+ autoradiography, we show that arrestin is a Ca2(+)-binding protein. The Ca2+ binding capacity of arresting-containing protein extracts from bovine rod outer segments is about twice as high as that of arrestin-depleted extracts. The difference in the Ca2+ binding of arrestin-containing and arrestin-depleted protein extracts was attributed to arrestin. Both, these difference-measurements of protein extracts and the measurements of purified arrestin yield dissociation constants for the Ca2+ binding of arrestin between 2 and 4 microM. The titration curves are consistent with a molar ratio of one Ca2+ binding site per arrestin. No Ca2+ binding in the micromolar range was found in extracts containing mainly transducin and cGMP-phosphodiesterase. Since arrestin is one of the most abundant proteins in rod photoreceptors occurring presumably up to millimolar concentrations in rod outer segments, we suggest that aside from its function to prevent the activation of transducin, arrestin acts probably as an intracellular Ca2+ buffer.     

Binding of more than one retinoid to visual opsins

Visual opsins bind 11-cis retinal at an orthosteric site to form rhodopsins but increasing evidence suggests that at least some are capable of binding an additional retinoid(s) at a separate, allosteric site(s). Microspectrophotometric measurements on isolated, dark-adapted, salamander photoreceptors indicated that the truncated retinal analog, β-ionone, partitioned into the membranes of green-sensitive rods; however, in blue-sensitive rod outer segments, there was an enhanced uptake of four or more β-ionones per rhodopsin. X-ray crystallography revealed binding of one β-ionone to bovine green-sensitive rod rhodopsin. Cocrystallization only succeeded with extremely high concentrations of β-ionone and binding did not alter the structure of rhodopsin from the inactive state. Salamander green-sensitive rod rhodopsin is also expected to bind β-ionone at sufficiently high concentrations because the binding site is present on its surface. Therefore, both blue- and green-sensitive rod rhodopsins have at least one allosteric binding site for retinoid, but β-ionone binds to the latter type of rhodopsin with low affinity and low efficacy.     

Comparative studies on the late bleaching processes of four kinds of cone visual pigments and rod visual pigment

Visual pigments in rod and cone photoreceptor cells of vertebrate retinas are highly diversified photoreceptive proteins that consist of a protein moiety opsin and a light-absorbing chromophore 11-cis-retinal. There are four types of cone visual pigments and a single type of rod visual pigment. The reaction process of the rod visual pigment, rhodopsin, has been extensively investigated, whereas there have been few studies of cone visual pigments. Here we comprehensively investigated the reaction processes of cone visual pigments on a time scale of milliseconds to minutes, using flash photolysis equipment optimized for cone visual pigment photochemistry. We used chicken violet (L-group), chicken blue (M1-group), chicken green (M2-group), and monkey green (L-group) visual pigments as representatives of the respective groups of the phylogenetic tree of cone pigments. The S, M1, and M2 pigments showed the formation of a pH-dependent mixture of meta intermediates, similar to that formed from rhodopsin. Although monkey green (L-group) also formed a mixture of meta intermediates, pH dependency of meta intermediates was not observed. However, meta intermediates of monkey green became pH dependent when the chloride ion bound to the monkey green was replaced with a nitrate ion. These results strongly suggest that rhodopsin and S, M1, and M2 cone visual pigments share a molecular mechanism for activation, whereas the L-group pigment may have a special reaction mechanism involving the chloride-binding site.     

Chicken red-sensitive cone visual pigment retains a binding domain for transducin

Iodopsin (a red-sensitive cone visual pigment) and rhodopsin (a rod pigment) were isolated from chicken retina. They were separately reconstituted into phosphatidylcholine liposomes and then mixed with rod transducin (T alpha and T beta gamma) purified from bovine retina. Iodopsin enhanced, only when irradiated, the binding of GppNHp to T alpha to a similar extent to irradiated rhodopsin. Furthermore, the binding of GppNHp to T alpha in the presence of a photobleaching intermediate of iodopsin preferably required T beta gamma-2 rather than T beta gamma-1, which is very similar in profile to that in the presence of the intermediate of rhodopsin (J. Biol. Chem., in press). These results indicate that the binding domain for transducin in iodopsin should closely resemble that in rhodopsin.     

Phosphorylation of rhodopsin: Most rhodopsin molecules are not phosphorylated

Phosphorylation of rod membrane proteins is a light-dependent reaction. Most rhodopsin molecules, however, are not phosphorylated. The protein that is highly phosphorylated (>3 moles phosphate per mole phosphorylated protein) appears to be a rhodopsin species that is different from the rest or is located in different parts of the rod membrane system.     

Characterization of a truncated form of arrestin isolated from bovine rod outer segments.

The inactivation of photolyzed rhodopsin requires phosphorylation of the receptor and binding of a 48-kDa regulatory protein, arrestin. By binding to phosphorylated photolyzed rhodopsin, arrestin inhibits G protein (Gt) activation and blocks premature dephosphorylation, thereby preventing the reentry of photolyzed rhodopsin into the phototransduction pathway. In this study, we isolated a 44-kDa form of arrestin, called p44, from fresh bovine rod outer segments and characterized its structure and function. A partial primary structure of p44 was established by a combination of mass spectrometry and automated Edman degradation of proteolytic peptides. The amino acid sequence was found to be identical with arrestin, except that the C-terminal 35 residues (positions 370-404) are replaced by a single alanine. p44 appeared to be generated by alternative mRNA splicing, because intron 15 interrupts within the nucleotide codon for 369Ser in the arrestin gene. Functionally, p44 binds avidly to photolyzed or phosphorylated and photolyzed rhodopsin. As a consequence of its relatively high affinity for bleached rhodopsin, p44 blocks Gt activation. The binding characteristics of p44 set it apart from tryptic forms of arrestin (truncated at the N- and C-termini), which require phosphorylation of rhodopsin for tight binding. We propose that p44 is a novel splice variant of arrestin that could be involved in the regulation of Gt activation.