The partial primary structure of bovine rhodopsin and its topography in the retinal rod cell disc membrane

The Role of Reversible Phosphorylation of Drosophila Rhodopsin

Vertebrate and fly rhodopsins are prototypical GPCRs that have served for a long time as model systems for understanding GPCR signaling. Although all rhodopsins seem to become phosphorylated at their C-terminal region following activation by light, the role of this phosphorylation is not uniform. Two major functions of rhodopsin phosphorylation have been described: (1) inactivation of the activated rhodopsin either directly or by facilitating binding of arrestins in order to shut down the visual signaling cascade and thus eventually enabling a high-temporal resolution of the visual system. (2) Facilitating endocytosis of activated receptors via arrestin binding that in turn recruits clathrin to the membrane for clathrin-mediated endocytosis. In vertebrate rhodopsins the shutdown of the signaling cascade may be the main function of rhodopsin phosphorylation, as phosphorylation alone already quenches transducin activation and, in addition, strongly enhances arrestin binding. In the Drosophila visual system rhodopsin phosphorylation is not needed for receptor inactivation. Its role here may rather lie in the recruitment of arrestin 1 and subsequent endocytosis of the activated receptor. In this review, we summarize investigations of fly rhodopsin phosphorylation spanning four decades and contextualize them with regard to the most recent insights from vertebrate phosphorylation barcode theory.

Ca2+-dependent control of rhodopsin phosphorylation: recoverin and rhodopsin kinase

Over many years until the middle of the 1980s, the main problem in vision research had been the mechanism of transducing the visual signal from photobleached rhodopsin to the cationic channels in the plasma membrane of a photoreceptor to trigger the electrophysiological response of the cell. After cGMP was proven to be the secondary messenger, the main intriguing question has become the mechanisms of negative feedback in photoreceptors to modulate their response to varying conditions of illumination. Although the mechanisms of light-adaptation are not completely understood, it is obvious that Ca2+ plays a crucial role in these mechanisms and that the effects of Ca2+ can be mediated by several Ca2+-binding proteins. One of them is recoverin. The leading candidate for the role of an intracellular target for recoverin is believed to be rhodopsin kinase, a member of a family of G-protein-coupled receptor kinases. The present review considers recoverin, rhodopsin kinase and their interrelationships in the in vitro as well as in vivo contexts.

Retinal photoreceptor dystrophies LI. Edward Jackson Memorial Lecture

PURPOSE

To assess the state of knowledge of photoreceptor dystrophies.

METHODS

The current literature concerning photoreceptor dystrophies is reviewed, and their potential impact on concepts of pathogenesis of disease and clinical practice is assessed.

RESULTS

As a result of cooperative investigative work between researchers in various disciplines, major advances in the classification of retinal photoreceptor dystrophies have been made. Until recently, classification of retinal dystrophies was based on clinical observation alone, and it was evident that this method was imprecise and of limited value. Largely through the work of molecular biologists, it has been shown that diseases clinically indistinguishable from one another may be a result of mutations on a variety of genes; conversely, different mutations on a single gene may give rise to a variety of phenotypes. It is reassuring that it is possible to generate concepts as to potential pathogenetic mechanisms that exist in retinal dystrophies in light of this new knowledge. More important for the clinician is the potential impact on clinical practice. There is as yet no therapy by which the course of most of these disorders can be modified. However, there is a considerable body of work in which therapeutic intervention is being explored, and many researchers now see treatment as a justifiable objective of their work.

CONCLUSIONS

Knowledge of the causative mutation is of value to the clinician in that it provides a precise diagnosis and allows the distribution of the abnormal gene to be documented fully within a family. To take full advantage of the opportunities provided by current research, clinical practice will have to be modified, particularly if therapy can be justified.

The gastrin-releasing peptide receptor is rapidly phosphorylated by a kinase other than protein kinase C after exposure to agonist

Several guanine nucleotide-binding protein-coupled receptors are known to be rapidly phosphorylated after agonist exposure. In this study we show that the gastrin-releasing peptide receptor (GRP-R) is rapidly phosphorylated in response to agonist exposure. When [32P]orthophosphate-labeled cells were exposed to bombesin, the receptor was maximally phosphorylated on serine and threonine residues within 1 min. Although addition of 12-O-tetradecanoylphorbol 13-acetate also resulted in phosphorylation of the GRP-R, elimination of protein kinase C activity using the inhibitor 7-hydroxystaurosporine did not prevent bombesin-induced GRP-R phosphorylation. We conclude that a kinase other than protein kinase C is principally responsible for the rapid, agonist-induced phosphorylation of the GRP-R.

Rhodopsin kinase: studies on the sequence of and the recognition motif for multiphosphorylations

Peptides of 10-12 amino acids in length, which overlapped with the sequence of the last 20 amino acids in the C-terminal tail of rhodopsin, were synthesized and used as substrates for rhodopsin kinase. In all cases the phosphorylation of the peptides was found to be greatly stimulated (> 20-fold) by the presence of light-activated rhodopsin (Rho*). The incorporation of 32P at seven Ser/Thr residues that are the potential sites of phosphorylation was quantified, and the results were analyzed in terms of two parameters. First, a global comparison of phosphorylation at each site was made when the propensity for the modification was found to be in the order: Ser 343 > Ser 338 > Thr 336 > Ser 334, Thr 342 > Thr 335, Thr 340. Second, the peptides were aligned on a hypothetical template with the residue to be phosphorylated occupying the P-position, and the manner in which the nature of the surrounding residues effected the phosphorylation was assessed. It was found that the optimal phosphorylation of the P-site Ser/Thr occurs if it has at least one residue on the amino side and five on the acyl side and also contains a neutral residue, preferably small (A, P, S, T) at the P+4 position.(ABSTRACT TRUNCATED AT 250 WORDS)

A segment corresponding to amino acids Val170-Arg182 of bovine arrestin is capable of binding to phosphorylated rhodopsin

In retinal rods, photoexcited rhodopsin (R*) is inactivated upon phosphorylation by rhodopsin kinase and the subsequent binding of arrestin. We have studied the structural role of a cationic region of bovine arrestin (Val170-Arg182) using anti-peptide IgGs specifically recognizing this segment and the corresponding oligopeptide. Our results clearly indicate that amino acids Val170-Arg182 are shielded within the arrestin-rhodopsin-complex and very likely belong to a binding domain of arrestin for phosphorylated R*. The purified anti-peptide IgGs strongly reacted with isolated arrestin but did not recognize arrestin when bound to phosphorylated R*. In agreement with these experiments, the oligopeptide Val170-Arg182 was found to compete with arrestin for binding to phosphorylated R*. Increasing concentrations of this peptide caused an oligomerization of phosphorylated rhodopsin when illuminated by white light as well as in the dark. Unphosphorylated rhodopsin did not oligomerize up to a 400-fold molar ratio of peptide/rhodopsin. Limited proteolysis of the phosphorylated carboxy-terminus of rhodopsin with endoproteinase Asp-N caused a significant decrease in the peptide-induced formation of oligomers. Therefore, Val170-Arg182 of bovine arrestin probably interacts with the phosphorylated carboxy-terminus of rhodopsin. The data presented support the proposal of Palczewski et al. (1991c) considering the region Lys163-Arg182 in bovine arrestin to be a possible binding domain for phosphorylated R*.

Phosphorylation sites in bovine rhodopsin

Bovine rhodopsin has been phosphorylated in rod outer segments by ATP and endogenous rhodopsin kinase. Mono-, di-, and triphosphorylated rhodopsins have been prepared by chromatofocusing. Nearly all of the phosphate is found in peptide 330-348, formed by digestion of phosphorhodopsins with endoproteinase Asp-N. Sequence analysis of the phosphopeptides shows that monophosphorylated rhodopsin consists of a mixture containing rhodopsins phosphorylated at 338Ser and 343Ser. Diphosphorylated rhodopsin is phosphorylated at both 338Ser and 343Ser. When rhodopsin becomes triphosphorylated it does not become phosphorylated on 334Ser but appears to become phosphorylated on one or more of the four threonine residues: 335Thr, 336Thr, 340Thr, and 342Thr.

Cooperativity during multiple phosphorylations catalyzed by rhodopsin kinase: supporting evidence using synthetic phosphopeptides

Rhodopsin kinase is a key component in the shutdown of visual transduction. The phosphorylation of rhodopsin's C-terminus was evaluated using synthetic peptides derived from the last 12 amino acids (337-348) as substrates and their phosphorylated counterparts as inhibitors. It was found that synthetic peptides were phosphorylated at the serine residue corresponding to Ser-343 in the primary sequence of bovine rhodopsin. The phosphopeptides were prepared by incorporating into the peptide chain a trityl-protected serine derivative at the site destined to contain the phosphoryl group. The trityl group was selectively released with 20% (v/v) dichloroacetic acid; the free hydroxyl group was then phosphitylated with di-tert-butyl N,N-diethylphosphoramidite, and the resulting phosphite derivative was oxidized with m-chloroperoxybenzoic acid. The phosphopeptides were found to have a greater affinity for the kinase compared with their nonphosphorylated counterparts; for the peptides corresponding to residues 337-348 of rhodopsin the affinity increased in the order VSKTETSQVAPA < VSKTETS[PO3H2]QVAPA < VS[PO3H2]KTETS[PO3H2]QVAPA. The results are interpreted to support the cooperativity hypotheses proposed previously [Wilden, U., & Kühn, H. (1982) Biochemistry 21, 3014-3022; Aton, B. R., Litman, B. J., & Jackson, M. L. (1984) Biochemistry 23, 1737-1741].

Early opsin expression in Xenopus embryos precedes photoreceptor differentiation

The visual pigment which serves as the first step in the phototransduction cycle in vertebrate rod cells consists of a retinal chromophore which is linked to the transmembrane protein, opsin. Opsin genes have been isolated from a number of different organisms and studies have shown opsin to be developmentally regulated with both mRNA and protein expression associated with the morphological differentiation of photoreceptor cells. Due to its potential utility as a marker for rod photoreceptor determination in studies of retinal tissue interactions, and because no amphibian opsin genes have as yet been cloned, we isolated cDNA clones of the Xenopus laevis opsin gene. Sequence analysis shows that within the coding region Xenopus opsin shares a high degree of identity with other rod opsin genes, except at the C-terminal where it more closely resembles the mammalian color opsins. A developmental analysis, on the other hand, reveals that Xenopus opsin transcripts are detectable in a retina-specific fashion early in retinal development. Using in situ hybridization we find that Xenopus opsin mRNA is initially restricted to a few isolated cells in the presumptive photoreceptor layer which express the gene at relatively high levels. This suggests that rod photoreceptor determination occurs in single cells, and that the mechanisms controlling opsin expression in Xenopus are initiated well before any evidence of morphological differentiation.

Mechanistic studies on rhodopsin kinase. Light-dependent phosphorylation of C-terminal peptides of rhodopsin

The phosphorylation of a synthetic peptide, corresponding to the C-terminal 11 amino acids of bovine rhodopsin (VII, residues 338-348), was studied under different conditions. The peptide was only phosphorylated in the presence of photoactivated rhodopsin. Using the same protocol, 12 other peptides, mapping in the rhodopsin C-terminal, were screened for their effectiveness as substrates for rhodopsin kinase. It was found that the peptides became poorer substrates with increasing length, and the best substrates comprised the most C-terminal 9-12 amino acids as opposed to other parts of the C-terminus. It was noted that the absence of the two-terminal residues Pro347 and Ala348 impaired peptide phosphorylation. The effect of the decay of metarhodopsin II on the phosphorylation of rhodopsin and the peptides was determined, and it was found that the rhodopsin and peptide phosphorylations decayed with half times of approximately 33 min and 28 min, respectively. The sites of phosphorylation on the peptides were determined and in all cases the phosphorylation was found to be predominantly on serine residues. Only the 11-residue peptide (VII, residues 338-348) contained significant threonine phosphorylation, which was about 25% that on serine residues. Cumulatively, the results suggest that Ser343 is the preferred site of phosphorylation in vitro. The reason for the poor substrate effectiveness of the larger peptides was examined by competitive experiments in which it was shown that a poorly phosphorylated larger peptide successfully inhibited the phosphorylation of a 'good' peptide substrate. The studies above support a mechanism for rhodopsin kinase that we have termed the 'kinase-activation hypothesis'. This requires that the kinase exists in an inactive form and is activated only after binding to photoactivated rhodopsin.

Iodopsin, a red-sensitive cone visual pigment in the chicken retina

The vertebrate retina contains two kinds of visual cells: rods, responsible for twilight (scotopic) vision (black and white discrimination); and cones, responsible for daylight (photopic) vision (color discrimination). Here we attempt to explain some of their functional differences and similarities in terms of their visual pigments. In the chicken retina there are four types of single cones and a double cone; each of the single cones has its own characteristic oil droplet (red, orange, blue, or colorless) and the double cone is composed of a set of principal and accessory members, the former of which has a green-colored oil droplet. Iodopsin, the chicken red-sensitive cone visual pigment, is located at outer segments of both the red single cones and the double cones, while the other single cones and the rod contain their own visual pigments with different absorption spectra. The diversity in absorption spectra among these visual pigments is caused by the difference in interaction between chromophore (11-cis retinal) and protein moiety (opsin). However, the chromophore-binding pocket in iodopsin is similar to that in rhodopsin. The difference in absorption maxima between both pigments could be explained by the difference in distances between the protonated Schiff-bases at the chromophore-binding site and their counter ions in iodopsin and rhodopsin. Furthermore, iodopsin has a unique chloride-binding site whose chloride ion serves for the red-shift of the absorption maximum of iodopsin. Visual pigment bleaches upon absorption of light through several intermediates and finally dissociates into all-trans retinal and opsin. That the sensitivity of cones is lower than rods cannot be explained by the relative photosensitivity of iodopsin to rhodopsin, but may be understood to some extent by the short lifetime of an enzymatically active intermediate (corresponding to metarhodopsin II) produced in the photobleaching process of iodopsin. The rapid formation and decay of the meta II-intermediate of iodopsin compared with metarhodopsin II are not contradictory to the rapid generation and recovery of cone receptor potential compared with rod receptor potential. The rapid recovery of the cone receptor potential may be due to a more effective shutoff mechanism of the visual excitation, including the phosphorylation of iodopsin. The rapid dark adaptation of cones compared with rods has been explained by the rapid regeneration of iodopsin from 11-cis retinal and opsin. One of the reasons for the rapid regeneration and susceptibility to chemicals of iodopsin compared with rhodopsin may be a unique structure near the chromophore-binding site of iodopsin.

The primary structure of iodopsin, a chicken red-sensitive cone pigment

A purified iodopsin was digested by CNBr or several proteolytic enzymes into fragments, the amino acid sequences of which were determined. A partial sequence of the C-terminal fragment was utilized for synthesizing an oligonucleotide probe which identified the iodopsin cDNA (1339 bases). The deduced amino acid sequence (362 residues) had 80%, 42%, or 43% homology to that of human red-sensitive cone pigment, cattle or chicken rhodospin, respectively. Although the hydropathy profile implies that iodopsin, like rhodopsin, has 7 transmembrane alpha-helical segments, iodopsin may have a hydrophilic pocket near the seventh segment on the basis of the unexpected cleavages in the middle of the segment VII by chymotrypsin under nondenaturing conditions.

Substrate recognition determinants for rhodopsin kinase: studies with synthetic peptides, polyanions, and polycations

Rhodopsin kinase phosphorylates serine- and threonine-containing peptides from bovine rhodopsin's carboxyl-terminal sequence. Km's for the peptides decrease as the length of the peptide is increased over the range 12-31 amino acids, reaching 1.7 mM for peptide 318-348 from the rhodopsin sequence. The Km for phosphorylation of rhodopsin is about 10(3) lower than that for the peptides, which suggests that binding of rhodopsin kinase to its substrate, photolyzed rhodopsin, involves more than just binding to the carboxyl-terminal peptide region that is to be phosphorylated. A synthetic peptide from the rhodopsin sequence that contains both serines and threonines is improved as a substrate by substitution of serines for the threonines, suggesting that serine residues are preferred as substrates. Analogous 25 amino acid peptides from the human red or green cone visual pigment, a beta-adrenergic receptor, or M1 muscarinic acetylcholine receptors are better substrates for bovine rhodopsin kinase than is the peptide from bovine rhodopsin. An acidic serine-containing peptide from a non-receptor protein, alpha s1B-casein, is also a good substrate for rhodopsin kinase. However, many basic peptides that are substrates for other protein kinases--histone IIA, histone IIS, clupeine, salmine, and a neurofilament peptide--are not phosphorylated by rhodopsin kinase. Polycations such as spermine or spermidine are nonessential activators of phosphorylation of rhodopsin or its synthetic peptide 324-348. Polyanions such as poly(aspartic acid), dextran sulfate, or poly(adenylic acid) inhibit the kinase. Poly(L-aspartic acid) is a competitive inhibitor with respect to rhodopsin (KI = 300 microM) and shows mixed type inhibition with respect to ATP.

An analysis of the periodicity of conserved residues in sequence alignments of G-protein coupled receptors. Implications for the three-dimensional structure

Twenty-three sequences from the family of G-protein coupled receptors have been aligned according to the 'historical alignment' procedure of Feng and Doolittle. Fourier transform analysis of this reveals that parts of five of the seven putative membrane-spanning regions exhibit a periodicity of conserved/nonconserved residues which is compatible with the periodicity of the alpha-helix. This would place the conserved residues on one side of the helix, which may face the inside of the proposed seven membered helical bundle.

Removal of phosphorylation sites from the beta 2-adrenergic receptor delays onset of agonist-promoted desensitization

Eukaryotic cells have evolved a variety of mechanisms for dampening their responsiveness to hormonal stimulation in the face of sustained activation. The mechanisms for such processes, collectively referred to as desensitization, often involve alterations in the properties and number of cell-surface hormone receptors. It has been speculated that phosphorylation-dephosphorylation reactions, which are known to regulate the catalytic activities of enzymes, also regulate the function of receptors. Highly specific receptor kinases, such as rhodopsin kinase and beta-adrenergic receptor kinase, which show stimulus-dependent phosphorylation of receptors have been described. Direct evidence for a causal relationship between receptor phosphorylation and desensitization has been lacking however. Here we report that prevention of agonist-stimulated beta 2-adrenergic receptor (beta 2AR) phosphorylation by truncation of its serine and threonine-rich phosphate acceptor segment delays the onset of desensitization. We also show that selective replacement of these serine and threonine residues by alanine and glycine delays desensitization even further. These data provide the first direct evidence that one molecular mechanism of desensitization of G-protein-coupled receptors involves their agonist-induced phosphorylation.

Cloning, sequencing, and expression of the gene coding for the human platelet alpha 2-adrenergic receptor

The gene for the human platelet alpha 2-adrenergic receptor has been cloned with oligonucleotides corresponding to the partial amino acid sequence of the purified receptor. The identity of this gene has been confirmed by the binding of alpha 2-adrenergic ligands to the cloned receptor expressed in Xenopus laevis oocytes. The deduced amino acid sequence is most similar to the recently cloned human beta 2- and beta 1-adrenergic receptors; however, similarities to the muscarinic cholinergic receptors are also evident. Two related genes have been identified by low stringency Southern blot analysis. These genes may represent additional alpha 2-adrenergic receptor subtypes.

mRNAs coding for proteins of the cGMP cascade in the degenerative retina of the rd mouse

A lesion in cGMP metabolism has been hypothesized to cause retinal degeneration in rd mice. Available cloned cDNAs coding for proteins involved in the cGMP cascade have been used to compare the corresponding retinal RNAs in the degenerative (rd/rd) mouse at 8-11 days with those in the 8-11-day-old morphologically normal (rd/+) and adult normal (+/+) mice. Northern analysis of these RNAs hybridized to the specific 32P-labeled cDNA probes for G-protein, 48,000 MW protein and opsin, indicates in each case, that the corresponding transcripts are made in the rd/rd mouse retina and that there are no overt differences in their size compared to the transcripts hybridized in the rd/+ or +/+ mouse retinas. Although a defect in the phosphorylation of opsin has been described in rd mice, no difference was found in the transcripts hybridized by a cDNA probe corresponding to the region of the opsin molecule on which phosphorylation occurs. We do find, however, that labeled bovine-derived opsin cDNA recognizes five different RNA size classes in mouse and bovine retinas. Control experiments were performed to confirm that the RNA hybridized by opsin cDNA was not due to non-specific hybridization to unrelated RNAs.

The carboxyl terminus of the hamster beta-adrenergic receptor expressed in mouse L cells is not required for receptor sequestration

The structural basis for agonist-mediated sequestration and desensitization of the beta-adrenergic receptor (beta AR) was examined by oligonucleotide-directed mutagenesis of the hamster beta AR gene and expression of the mutant genes in mouse L cells. Treatment of these cells with the agonist isoproterenol corresponded to a desensitization of beta AR activity. A mutant receptor that bound agonist but did not couple to adenylate cyclase showed a dramatically reduced sequestration response to agonist stimulation. In contrast, beta AR mutants in which the C-terminus was truncated and/or in which two regions that have been proposed as phosphorylation substrates for cAMP-dependent protein kinase were removed showed normal sequestration responses. These results demonstrate that agonist-mediated sequestration of the beta AR can occur in the absence of the C-terminus of the protein and reveal a strong correlation between effective coupling to Gs and sequestration.

Structural features of the terminal loop region of frog retinal rod outer segment disk membranes: I. Organization of lipid components

We have applied thin sectioning and freeze-fracture techniques to investigate the terminal loop structure of photoreceptive disks in frog retinal rod outer segments. Our studies of this region demonstrate a highly curved terminal loop bilayer that is continuous with both lamellar bilayers of the disk, and equivalent to them in dimensions and staining properties. Rhodopsin, however, appears to be excluded from this region of high curvature.

Beta-adrenergic receptor-coupled adenylate cyclase. Biochemical mechanisms of regulation

Beta-adrenergic receptor-coupled adenylate cyclase is regulated by both amplification and desensitization processes. Desensitization of adenylate cyclase is divided into two major categories. Homologous desensitization is initiated by phosphorylation of the receptors by a beta-adrenergic receptor kinase. This reaction serves to functionally uncouple the receptors and trigger their sequestration away from the cell surface. These sequestered receptors can rapidly recycle to the cell surface or, with time, become down regulated, being destroyed within the cell. Dephosphorylation of the receptors is accomplished in the sequestered compartment of the cell, which may functionally regenerate the receptors and allow their return to the cell surface. In heterologous desensitization, receptor function is also regulated by phosphorylation, but in the absence of receptor sequestration or down regulation. In this case, phosphorylation serves only to functionally uncouple the receptors, that is, to impair their interactions with the guanine nucleotide regulatory protein Ns. Several protein kinases are capable of promoting this phosphorylation, including the cAMP-dependent kinase and protein kinase C. In addition to the receptor phosphorylation, heterologous desensitization is associated with modifications at the level of the nucleotide regulatory protein Ns and perhaps Ni. Adenylate cyclase systems are also subject to amplification that involves a protein kinase C-mediated phosphorylation of the catalytic unit of the enzyme. Phosphorylation of the catalytic unit enhances its catalytic activity and results in amplified stimulation by the regulatory protein Ns. Other receptor/effector systems exhibit qualitatively similar regulatory phenomena, suggesting that covalent modification (phosphorylation) may represent a general mechanism for regulating receptor function.

Transglutaminase modification of rhodopsin in retinal rod outer segment disk membranes

Rhodopsin in rod outer segment disk membranes was enzymatically modified by erythrocyte transglutaminase, which linked small primary amines to glutamine residues. In order to avoid formation of protein crosslinks, rhodopsin was first reductively methylated to modify its lysines. From 1.9 to 2.5 mol of putrescine, ethanolamine, or dinitrophenylcadaverine were incorporated into rhodopsin by transglutaminase during 16 h reaction time. A maximum of 3.5 mol of [14C]putrescine was incorporated per mole of rhodopsin during 48 h. Essentially all of the rhodopsin sequence containing the putrescine could be removed by limited proteolysis of the membranes by thermolysin. Glutamine residues in positions 236, 237, 238, and 344 were modified to approximately equal extents, as determined by isolation of the cyanogen bromide peptides of modified rhodopsin followed by further subdigestion of the peptides. The modified glutamine residues are located in the helix V-VI (or F1-F2) connecting loop and in the carboxyl-terminal region of rhodopsin.

Light-dependent phosphorylation of rhodopsin by beta-adrenergic receptor kinase

The structural components involved in transduction of extracellular signals as diverse as a photon of light impinging on the retina or a hormone molecule impinging on a cell have been highly conserved. These components include a recognition unit or receptor (for example, the beta-adrenergic receptor (beta AR) for catecholamines or the 'light receptor' rhodopsin), a guanine nucleotide regulatory or transducing protein, and an effector enzyme (for example, adenylate cyclase or cyclic GMP phosphodiesterase). Molecular cloning has revealed that the beta AR shares significant sequence and three-dimensional homology with rhodopsin. The function of the beta AR is diminished by exposure to stimulatory agonists, leading to desensitization. Similarly, 'light adaptation' involves decreased coupling of photoactivated rhodopsin to cGMP phosphodiesterase activation. Both forms of desensitization involve receptor phosphorylation. The latter is mediated by a unique protein kinase, rhodopsin kinase, which phosphorylates only the light-bleached form of rhodopsin. An analogous enzyme (termed beta AR kinase or beta ARK) phosphorylates only the agonist-occupied beta AR. We report here that beta ARK is also capable of phosphorylating rhodopsin in a totally light-dependent fashion. Moreover, rhodopsin kinase can phosphorylate the agonist-occupied beta AR. Thus the mechanisms which regulate the function of these disparate signalling systems also appear to be similar.

Molecular biology of the visual pigments

With the identification and structural characterization of several visual pigments has come a new era of investigation. The above comparisons of amino acids sequences predict specific functional domains that may be tested to tell us how visual pigments function to absorb light and transform this "signal" to trigger a neural response. The details of how rod and cone pigments differ are now known for human pigments. The striking similarities between vertebrate and invertebrate pigments are remarkable for pigments that have been subject to divergence for over 500 million years. There are yet challenges ahead of us. The true tertiary structure of visual pigments must be obtained from a 3-dimensional crystal structure. The predictions for functional domains of interaction with the GTP binding protein must be confirmed or redefined. A rigorous definition of the chromophore environment and the properties that control the wavelength of absorption of 11-cis retinal chromophore are certainly still on the drawing boards. Specific genetic alteration through in vitro mutagenesis promises much insight, but the technology for expressing these membrane proteins in functional form has yet to be achieved. We may expect, however, these problems will be addressed and in the next few years facts should replace what are now speculations. Finally, it is a delightful observation that nature has capitalized on a general biochemical mechanism for control of second messengers in the cytoplasm of cells. Protein structural data deduced from genetic information now document the hypothesis that the structure and function of receptors for the catecholamines and that of visual pigments are similar. The receptors for serotonin, leukotrienes, prostaglandins, histamine and acetylcholine (muscarinic) are expected to belong to this same family. The lessons learned about visual pigments can be applied broadly to a general set of membrane receptors.

Localization of light-induced conformational changes in bovine rhodopsin

Conformational changes in the extradiscal regions of rhodopsin induced by illumination were investigated by modifying the visual pigment by mild treatment with cyanogen bromide prior to and after light exposure. Light induced an increased yield of cleavage of the Met bond 253-254 and a new cleavage at the Met bond 155-156 of the rhodopsin polypeptide chain. These residues, located at the beginnings of the membrane-buried helices 6 and 4, respectively, were concluded to become extradiscally exposed upon illumination.

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.

Activation of rod outer segment phosphodiesterase by enzymatically altered rhodopsin: a regulatory role for the carboxyl terminus of rhodopsin

Soluble enzymes, extracted from bovine retinal rod outer segments (ROS), were recombined with native ROS discs and discs which had been modified either by protease treatment or phosphorylation with rhodopsin kinase. The effect of these modifications on rhodopsin's ability to light-activate the ROS phosphodiesterase was determined. Trypsin, short-term thermolysin, and papain-digested discs were more effective in activating the phosphodiesterase than were undigested discs, whereas phosphorylated discs showed reduced ability to activate the phosphodiesterase. When a non-hydrolyzable analogue was employed in place of GTP in the assay, the same differences in the activation of phosphodiesterase as described above were observed between control discs and discs which were digested with thermolysin or phosphorylated. The proteolysis treatments remove various segments of amino acids from the carboxyl terminus of rhodopsin. In addition, at least seven phosphorylation sites are located in the terminal 15 amino acid residues of the carboxyl terminus of rhodopsin. Hence, it would appear from these studies that modifications of rhodopsin which affect the carboxyl terminus result in marked changes in the level of light-activatable phosphodiesterase activity, strongly suggesting a regulatory involvement in the light-activation process for this portion of rhodopsin.

Phosphorylation at sites near rhodopsin's carboxyl-terminus regulates light initiated cGMP hydrolysis

We find prompt, high stoichiometry phosphorylation of rhodopsin in response to low fractional rhodopsin bleaching in bovine rod outer segments (ROS). For example, 4 +/- 1 phosphates are incorporated per bleached rhodopsin (Rho*) in 30 sec and 6 +/- 2 phosphates are incorporated in 75 sec in response to bleaching 1% of the rhodopsin in the presence of 1 mM [gamma-32P]ATP and 0.1 mM nonradioactive GTP. Omission of GTP leads to ca 70% inhibition of rhodopsin phosphorylation, presumably due to the GTP-binding protein blocking access of rhodopsin kinase to rhodopsin. Light induced phosphodiesterase (PDE) activation is rapidly quenched in the presence of ATP as first reported by by Liebman and Pugh [Nature 287, 734-736 (1980)]. The kinetics of rhodopsin phosphorylation vary with conditions and from preparation to preparation, however, they are always at least as fast as the ATP dependent quenching of PDE activation. The maximum extent of rhodopsin phosphorylation was limited by specific proteolytic trimming of the carboxyl-terminal phosphorylation sites in washed ROS membranes "stripped" of extrinsic proteins. Membrane preparations with 6,4,2, or 1 phosphate(s) incorporated/Rho* (after a 75 sec post bleach incubation) were produced by treatment with: no protease, carboxypeptidase Y (C), trypsin (T), or both T and C (TC), respectively, followed by reassociation with extrinsic membrane proteins and phosphorylation. Low fractional bleaching was required for maximum phosphorylation/Rho* in membranes which were stripped and reassociated with extrinsic proteins and in isolated ROS. Removal of C-terminal rhodopsin phosphorylation sites has little or no effect on light activation of PDE in the absence of ATP. However, in the presence of ATP the extent of the removal of C-terminal rhodopsin residues has large effects on the light activation and the shut-off of PDE. The single phosphate/Rho* that was added to TC digested membranes reduced the lifetime of Rho* but apparently was not incorporated rapidly enough under our conditions to inhibit the Vmax of PDE. The two phosphates/Rho* which were incorporated after T digestion cause a large decrease in the lifetime of Rho* as well as a decrease in the Vmax of PDE (at low bleaching levels). The four phosphates/Rho* that were added after C digestion further reduce the lifetime of Rho* and the Vmax of PDE. The 6 phosphates/Rho* which were incorporated into the unproteolyzed membranes have little additional effect on Rho* lifetime compared to 4 phosphates/Rho*. However, increasing the phosphorylation observed from 4 to 6 phosphates greatly inhibits the Vmax of PDE at intermediate bleaching levels.(ABSTRACT TRUNCATED AT 400 WORDS)

The structure of mammalian rod opsins

Ovine rhodopsin is organised in disc membranes as a monomer. The determination of its amino acid sequence has permitted the utilisation of structure prediction programmes which indicate the probable disposition of the polypeptide chain in the bilayer. This putative model is consistent with labelling data using the chemical probes, [14C]succinic anhydride, [125I]diazodiido sulphanilic acid and [125I]iodophenyl azide, and with the cleavage points for several proteases. More surprisingly the predicted structure points to the occurrence of breaks/distortions in the transmembrane helical segments. These distorted regions may be of primary functional importance to the protein and at least one is associated with the attachment point of the chromophore. This particular part of the structure is also identified as a "mutational hot spot", for bovine, equine, ovine and porcine opsins exhibit different sequences (but conserved molecular volumes) in the four residues following the retinyllysine. In an otherwise highly conserved protein with no obvious functional differences between the four species, the high substitution rate in this region is unexplained.

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.

Isolation and nucleotide sequence of a partial cDNA clone for bovine opsin

Bovine cDNAs were cloned by using a mixture of 18-base-long synthetic deoxyribonucleotides as a hybridization probe. The longest cDNA clone (pBO-1) contained an 811-bp insert that included the 434 bp of the coding region corresponding to the C-terminal 144 amino acid residues of opsin peptide and the 377 bp of the 3'-untranslated region. The size of opsin mRNA was determined as 23 S by Northern blot hybridization. Bovine liver DNA gave rise to a single band of 2.8 kb, 1.1 kb and 7.9 kb each with Eco RI, Hind III and Bam HI, respectively, by Southern blot hybridization with pBO-1 as probe. Therefore, bovine opsin gene may occur once per haploid genome.

Preparation of peptides containing any desired amino acid: methionyl peptides of bovine rhodopsin

A general method is described which allows the identification and preparation of peptides containing any amino acid of interest. The method has been applied to isolation of the methionyl peptides from a peptic digest of oxidized bovine rhodopsin. The peptide digestion mixture is first partially separated by ion exchange column chromatography. Location of peptides containing the desired amino acid is performed by amino acid analysis of acid hydrolyzed column fractions by high voltage paper electrophoresis. Peptides are further purified and prepared by peptide mapping, elution, and amino acid analysis using inexpensive high capacity techniques. Peptide sequencing is performed by a manual dansyl-Edman method well adapted for rapidly processing large numbers of samples. The methods are particularly well suited for detection and preparation of peptides containing amino acids for which there is no specific detection method.

Rhodopsin in reconstituted phospholipid vesicles. 1. Structural parameters and light-induced conformational changes detected by resonance energy transfer and fluorescence quenching

The structure of purified rhodopsin was investigated by steady-state resonance energy transfer and fluorescence quenching techniques: (1) Fluorescence parameters and relative distances between rhodopsin sites labeled with fluorescent probes and the endogenous chromophore 11-cis-retinal were measured in micellar detergent solution and in reconstituted phospholipid vesicles. (2) The accessibility of the labeled rhodopsin sites in reconstituted vesicles to N-methyl- and N-benzylpicolinium was studied in the dark and subsequent to rhodopsin bleaching. Fluorescent-labeled rhodopsin was affinity purified in octyl glucoside from rod outer segments which were previously reacted with either the sulfhydryl-specific reagents, pyrenylmaleimide or monobromobimane, or reagents specific to amino groups, dansyl chloride or fluorescein isothiocyanate. The purified protein was recombined with phospholipids, and vesicles were formed by detergent dialysis. All four fluorophores appear to react greater than or equal to 30 A away from the endogenous chromophore as estimated from the efficiency of energy transfer and presumably probe rhodopsin domains exposed at the membrane surface. The maximal fraction of quenchable fluorescence and the mean quenching constant were determined in dark and bleached vesicles: bleaching did not affect the quenching of the fluorophores attached to sulfhydryl groups but markedly decreased the quenching constants of the fluorophores coupled to amino groups. The apparent collisional rate constant decreased by 20- and 4-fold for dansyl and fluorescein, respectively. The results suggest that bleaching reduced the accessibility of these sites which, in turn, may reflect light-induced displacements of rhodopsin domains at the membrane surface. Such structural changes may regulate rhodopsin-rhodopsin as well as rhodopsin-enzyme interactions.