Mechanism of rhodopsin kinase activation

The role of the cytoplasmic loops and C-terminal region of bovine rhodopsin (Rho) in binding and activating rhodopsin kinase was investigated. The ability of various enzymatically truncated forms of photolyzed rhodopsin (Rho*) to stimulate rhodopsin kinase activity was quantified. Following endopeptidase Asp-N cleavage of all phosphorylation sites on the C-terminal, the resulting truncated Rho* (329G-Rho*) was not phosphorylated by rhodopsin kinase. This suggests that rhodopsin kinase only phosphorylates C-terminal sites of Rho*. However 329G-Rho* could bind rhodopsin kinase and stimulate phosphorylation of exogenous peptide. Kinase stimulation was investigated for other truncated forms of Rho* in which the C-terminal region was either partially or completely eliminated, and the V-VI loop was either cleaved or left intact (339K-Rho*, 341E239E-Rho*, 329G239E-Rho*, 327P240S-Rho*). Results suggest that the V-VI loop is crucial for kinase binding (similar to the binding of GT). Mastoparan, a model peptide for G-protein-coupled receptors, was found to stimulate rhodopsin kinase in a mechanism similar to that of truncated Rho*. We conclude that rhodopsin kinase binds to the cytoplasmic loops of Rho* to cause a stimulation of its catalytic activity.     

Carboxyl terminal of rhodopsin kinase is required for the phosphorylation of photo—activated rhodopsin

Human rhodopsin kinase (RK) and a carboxyl terminus-truncated mutant RK lacking the last 59 amino acids (RKC) were expressed in human embryonic kidney 293 cells to investigate the role of the carboxyl terminus of RK in recognition and phosphorylation of rhodopsin.RKC,like the wild-type RK,was detected in both plasma membranes and cytosolic fractions.The Cterminal truncated rhodopsin kinase was unable to phosphorylate photo-activated rhodopsin,but possesses kinase activity similar to the wild-type RK in phosphorylation of small peptide substrate.It suggests that the truncation did not disturb the gross structures of RK catalytic domain.Our results also show that RKC failed to translocate to photo-activated rod out segments.Taken together,our study demonstrate the carboxyl terminus of RK is required for phosphorylation of photo-activated rhodopsin and strongly indicate that carboxyl-terminus of RK may be involved in interaction with photo-activated rhodopsin.     

Characterization and Chromosomal Localization of the Gene for Human Rhodopsin Kinase

G-protein-dependent receptor kinases (GRKs) play a key role in the adaptation of receptors to persistent stimuli. In rod photoreceptors rhodopsin kinase (RK) mediates rapid desensitization of rod photoreceptors to light by catalyzing phosphorylation of the visual pigment rhodopsin. To study the structure and mechanism of GRKs in human photoreceptors, we have isolated and characterized cDNA and genomic clones derived from the human RK locus using a bovine rhodopsin kinase cDNA fragment as a probe. The RK locus, assigned to chromosome 13 band q34, is composed of seven exons that encode a protein 92% identical in amino acid sequence to bovine rhodopsin kinase. The marked difference between the structure of this gene and that of another recently cloned human GRK gene suggests the existence of a wide evolutionary gap between members of the GRK gene family.     

Structure and function in rhodopsin: effects of disulfide cross-links in the cytoplasmic face of rhodopsin on transducin activation and phosphorylation by rhodopsin kinase.

Six rhodopsin mutants containing disulfide cross-links between different cytoplasmic regions were prepared: disulfide bond 1, between Cys65 (interhelical loop I-II) and Cys316 (end of helix VII); disulfide bond 2, between Cys246 (end of helix VI) and Cys312 (end of helix VII); disulfide bond 3, between Cys139 (end of helix III) and Cys248 (end of helix VI); disulfide bond 4, between Cys139 (end of helix III) and Cys250 (end of helix VI); disulfide bond 5, between Cys135 (end of helix III) and Cys250 (end of helix VI); and disulfide bond 6, between Cys245 (end of helix VI) and Cys338 (C-terminus). The effects of local restrictions caused by the cross-links on transducin (G(T)) activation and phosphorylation by rhodopsin kinase (RK) following illumination were studied. Disulfide bond 1 showed little effect on either G(T) activation or phosphorylation by RK, suggesting that the relative motion between interhelical loop I-II and helix VII is not crucial for recognition by G(T) or by RK. In contrast, disulfide bonds 2-5 abolished both G(T) activation and phosphorylation by RK. Disulfide bond 6 resulted in enhanced G(T) activation but abolished phosphorylation by RK, suggesting the structure recognized by G(T) was stabilized in this mutant by cross-linking of the C-terminus to the cytoplasmic end of helix VI. Thus, the consequences of the disulfide cross-links depended on the location of the restriction. In particular, relative motions of helix VI, with respect to both helices III and VII upon light activation, are required for recognition of rhodopsin by both G(T) and RK. Further, the conformational changes in the cytoplasmic face that are necessary for protein-protein interactions need not be cooperative, and may be segmental.     

Identification of the autophosphorylation sites in rhodopsin kinase.

Rhodopsin kinase (RK) is a second-messenger-independent protein kinase that is involved in deactivation of photolyzed rhodopsin (Rho*). We have developed a significantly improved method for isolation of RK based on the specific interactions of phosphorylated forms of the enzyme with heparin-Sepharose. Conversion of the dephosphorylated form of RK to the fully phosphorylated enzyme leads to specific elution of the kinase from the resin. Limited proteolysis of RK with endoproteinase Asp-N removes the phosphorylation sites. Peptides containing the autophosphorylation sites were isolated by reverse-phase high performance liquid chromatography and analyzed by Edman degradation and tandem mass spectrometry. The derived amino acid sequence of the peptide containing the major autophosphorylation site yielded the following sequence: DVGAFS488T489VKGVAFEK, where Ser488 and Thr489 are phosphorylated. Additionally, a minor autophosphorylation site was identified at Ser21. A 15-residue peptide (DVGAFSTVKGVAFEK) encompassing the major autophosphorylation site was synthesized and used for phosphorylation and inhibition studies. In contrast to many other protein kinases, the low catalytic activity of RK toward its autophosphorylation site peptide and the poor inhibitory properties of this peptide suggest unique properties of this member of the family of G protein-coupled receptor kinases.     

Differential inhibitory effects of lovastatin on protein isoprenylation and sterol synthesis

It has been reported that when 3-hydroxy-3-methylglutaryl-CoA reductase inhibitors are utilized for treatment of hypercholesterolemia, as much as 50% inhibition of whole body cholesterol biosynthesis is observed. As general inhibitors of isoprenoid biosynthesis, these compounds can also inhibit the synthesis of the substituents of isoprenylated proteins. For two mammalian proteins (p21ras and lamin A), it has been demonstrated that such inhibition of biosynthesis of the isoprenoid substituent blocks proteolytic maturation of these proteins. It has been argued that advantage may be taken of this phenomenon to block the synthesis of p21ras in malignancies. It is also possible that treatment of hypercholesterolemia with lovastatin might produce problematic inhibition of protein processing dependent upon isoprenylation. In this report, we compare the concentration dependence of inhibition of isoprenylation dependent protein processing and sterol biosynthesis. Effects of partial inhibition of isoprenylated protein processing on whole cells can be sensitively assessed by visualization of lamina structure through indirect immunofluorescence. Our results indicate that the degree of inhibition of p21ras and prelamin A maturation by lovastatin is identical. Thus, 3-hydroxy-3-methylglutaryl-CoA reductase inhibitors are unlikely to be useful as anti-malignancy drugs. However, the conditions of lovastatin treatment which produce 50% inhibition of sterol biosynthesis analogous to pharmacological conditions, produce no observable effects on isoprenylated protein maturation.     

Regulation of the methylation status of G protein-coupled receptor kinase 1 (rhodopsin kinase)

Rhodopsin kinase (GRK1) is a member of G protein-coupled receptor kinase family and a key enzyme in the quenching of photolysed rhodopsin activity and desensitisation of the rod photoreceptor neurons. Like some other rod proteins involved in phototransduction, GRK1 is posttranslationally modified at the C terminus by isoprenylation (farnesylation), endoproteolysis and α-carboxymethylation. In this study, we examined the potential mechanisms of regulation of GRK1 methylation status, which have remained unexplored so far. We found that considerable fraction of GRK1 is endogenously methylated. In isolated rod outer segments, its methylation is inhibited and demethylation stimulated by low-affinity nucleotide binding. This effect is not specific for ATP and was observed in the presence of a non-hydrolysable ATP analogue AMP-PNP, GTP and other nucleotides, and thus may involve a site distinct from the active site of the kinase. GRK1 demethylation is inhibited in the presence of Ca(2+) by recoverin. This inhibition requires recoverin myristoylation and the presence of the membranes, and may be due to changes in GRK1 availability for processing enzymes upon its redistribution to the membranes induced by recoverin/Ca(2+). We hypothesise that increased GRK1 methylation in dark-adapted rods due to elevated cytoplasmic Ca(2+) levels would further increase its association with the membranes and recoverin, providing a positive feedback to efficiently suppress spurious phosphorylation of non-activated rhodopsin molecules and thus maximise senstivity of the photoreceptor. This study provides the first evidence for dynamic regulation of GRK1 α-carboxymethylation, which might play a role in the regulation of light sensitivity and adaptation in the rod photoreceptors.     

Substrate specificity of the isoprenylated protein endoprotease.

Proteins containing a CAAX motif at their carboxyl termini are subject to isoprenylation at the cysteine residue. Proteolytic trimming of isoprenylated proteins is essential in the activation of these proteins. A microsomal endopeptidase activity has been identified which cleaves all-trans farnesylated cysteine containing tetrapeptides between the modified residue and the adjacent amino acid to liberate the modified cysteine residue and an intact tripeptide. Structure/activity studies are reported here on this endopeptidase activity which are consistent with the premise that this protease is identical to the one normally involved in the cellular isoprenylation pathway. The protease only processes peptides which possess an isoprenyl moiety. Within the isoprenyl series, the enzyme hydrolyzes all-trans-farnesyl-, all-trans-geranylgeranyl-, and geranyl-containing peptides. The protease also recognizes the AAX sequence, because the protease behaves either stereospecifically or stereoselectively with respect to the individual amino acids of the tripeptide. The enzyme only measurably hydrolyzes isoprenylated peptides possessing L-amino acids at C and A. On the other hand, there is a small but measurable hydrolysis of isoprenylated peptides containing a D-amino acid at X.     

A functional rhodopsin-green fluorescent protein fusion protein localizes correctly in transgenic Xenopus laevis retinal rods and is expressed in a time-dependent pattern

To study rhodopsin biosynthesis and transport in vivo, we engineered a fusion protein (rho-GFP) of bovine rhodopsin (rho) and green fluorescent protein (GFP). rho-GFP expressed in COS-1 cells bound 11-cis retinal, generating a pigment with spectral properties of rhodopsin (A(max) at 500 nm) and GFP (A(max) at 488 nm). rho-GFP activated transducin at 50% of the wild-type activity, whereas phosphorylation of rho-GFP by rhodopsin kinase was 10% of wild-type levels. We expressed rho-GFP in the rod photoreceptors of Xenopus laevis using the X. laevis principal opsin promoter. Like rhodopsin, rho-GFP localized to rod outer segments, indicating that rho-GFP was recognized by membrane transport mechanisms. In contrast, a rho-GFP variant lacking the C-terminal outer segment localization signal distributed to both outer and inner segment membranes. Confocal microscopy of transgenic retinas revealed that transgene expression levels varied between cells, an effect that is probably analogous to position-effect variegation. Furthermore, rho-GFP concentrations varied along the length of individual rods, indicating that expression levels varied within single cells on a daily or hourly basis. These results have implications for transgenic models of retinal degeneration and mechanisms of position-effect variegation and demonstrate the utility of rho-GFP as a probe for rhodopsin transport and temporal regulation of promoter function.     

Identification of a C-terminal protein carboxyl methyltransferase in rat liver membranes utilizing a synthetic farnesyl cysteine-containing peptide substrate

Polypeptides synthesized in eucaryotic cells with a C-terminal -Cys-Xaa-Xaa-Xaa (-CXXX) sequence are candidates for post-translational modifications that include the removal of the last 3 amino acids and the lipidation and methyl esterification of the cysteinyl residue. To characterize the methylation reaction in vitro, the peptide Leu-Ala-Arg-Tyr-Lys-Cys (LARYKC) and its S-isoprenylated and S-alkylated derivatives were synthesized and assayed as methyl-accepting substrates with subcellular fractions of rat tissues including liver microsomal membranes. While little or no peptide-specific methyltransferase activity was detected in the latter preparation using the unmodified hexapeptide, the C10, C15, and C20 isoprenylated derivatives were substrates with Km values of 389 microM for S-geranyl-LARYKC, 2.2 microM for S-farnesyl-LARYKC, and approximately 10.9 microM for S-geranylgeranyl-LARYKC. The methyl-acceptor activities of a variety of n-alkyl S-derivatives of LARYKC (C8, C10, C13, C15) were also tested; all of these compounds were poorer substrates than the S-geranyl derivative. This enzyme activity uses S-adenosyl-L-methionine as the methyl donor (Km = 2.1 microM) and can be inhibited by S-adenosylhomocysteine (Ki = 9.2 microM), a product of the methylation reaction. The S-farnesyl-LARYKC peptide can inhibit the carboxyl methylation of bovine retinal rod outer segment membrane proteins that was previously shown to occur at the alpha-carboxyl group of C-terminal cysteine residues, demonstrating that the same enzyme can methylate both peptides and proteins. These results suggest that the methyl esterification of proteins containing a C-terminal -CXXX sequence requires not only the removal of the 3 terminal amino acids, but the isoprenylation of the sulfhydryl group as well.     

Structural basis for calcium-induced inhibition of rhodopsin kinase by recoverin

Recoverin, a member of the neuronal calcium sensor branch of the EF-hand superfamily, serves as a calcium sensor that regulates rhodopsin kinase (RK) activity in retinal rod cells. We report here the NMR structure of Ca(2+)-bound recoverin bound to a functional N-terminal fragment of rhodopsin kinase (residues 1-25, called RK25). The overall main-chain structure of recoverin in the complex is similar to structures of Ca(2+)-bound recoverin in the absence of target (<1.8A root-mean-square deviation). The first eight residues of recoverin at the N terminus are solvent-exposed, enabling the N-terminal myristoyl group to interact with target membranes, and Ca(2+) is bound at the second and third EF-hands of the protein. RK25 in the complex forms an amphipathic helix (residues 4-16). The hydrophobic face of the RK25 helix (Val-9, Val-10, Ala-11, Ala-14, and Phe-15) interacts with an exposed hydrophobic groove on the surface of recoverin lined by side-chain atoms of Trp-31, Phe-35, Phe-49, Ile-52, Tyr-53, Phe-56, Phe-57, Tyr-86, and Leu-90. Residues of recoverin that contact RK25 are highly conserved, suggesting a similar target binding site structure in all neuronal calcium sensor proteins. Site-specific mutagenesis and deletion analysis confirm that the hydrophobic residues at the interface are necessary and sufficient for binding. The recoverin-RK25 complex exhibits Ca(2+)-induced binding to rhodopsin immobilized on concanavalin-A resin. We propose that Ca(2+)-bound recoverin is bound between rhodopsin and RK in a ternary complex on rod outer segment disk membranes, thereby blocking RK interaction with rhodopsin at high Ca(2+).     

The prostacyclin receptor is isoprenylated. Isoprenylation is required for efficient receptor-effector coupling.

The prostacyclin receptor (IP), a G protein-coupled receptor, mediates the actions of the prostanoid prostacyclin and its mimetics. IPs from a number of species each contain identically conserved putative isoprenylation CAAX motifs, each with the sequence CSLC. Metabolic labeling of human embryonic kidney (HEK) 293 cells stably overexpressing the hemagluttinin epitope-tagged IP in the presence of [(3)H]mevalonolactone established that the mouse IP is isoprenylated. Studies involving in vitro assays confirmed that recombinant forms of the human and mouse IP are modified by carbon 15 farnesyl isoprenoids. Disruption of isoprenylation, by site-directed mutagenesis of Cys(414) to Ser(414), within the CAAX motif, abolished isoprenylation of IP(SSLC) both in vitro and in transfected cells. Scatchard analysis of the wild type (IP) and mutant (IP(SSLC)) receptor confirmed that each receptor exhibited high and low affinity binding sites for [(3)H]iloprost, which were not influenced by receptor isoprenylation. Whereas stable cell lines overexpressing IP generated significant agonist (iloprost and cicaprost)-mediated increases in cAMP relative to nontransfected cells, cAMP generation by IP(SSLC) cells was not significantly different from the control, nontransfected HEK 293 cells. Moreover, co-expression of the alpha (alpha) subunit of Gs generated significant augmentations in cAMP by IP but not by IP(SSLC) cells. Whereas IP also demonstrated significant, dose-dependent increases in [Ca(2+)](i) in response to iloprost or cicaprost compared with the nontransfected HEK 293 cells, mobilization of [Ca(2+)](i) by IP(SSLC) was significantly impaired. Co-transfection of cells with either Galpha(q) or Galpha(11) resulted in significant augmentation of agonist-mediated [Ca(2+)](i) mobilization by IP cells but not by IP(SSLC) cells or by the control, HEK 293 cells. In addition, inhibition of isoprenylation by lovastatin treatment significantly reduced agonist-mediated cAMP generation by IP in comparison to the nonisoprenylated beta(2) adrenergic receptor or nontreated cells. Hence, isoprenylation of IP does not influence ligand binding but is required for efficient coupling to the effectors adenylyl cyclase and phospholipase C.     

Serine 19 of human 6-pyruvoyltetrahydropterin synthase is phosphorylated by cGMP protein kinase II.

6-Pyruvoyltetrahydropterin synthase (PTPS) participates in tetrahydrobiopterin cofactor biosynthesis. We previously identified in a PTPS-deficient patient an inactive PTPS allele with an Arg(16) to Cys codon mutation. Arg(16) is located in the protein surface exposed phosphorylation motif Arg(16)-Arg-Ile-Ser, with Ser(19) as the putative phosphorylation site for serine-threonine protein kinases. Purification of recombinant PTPS-S19A from bacterial cells resulted in an active enzyme (k(cat)/K(m) = 6.4 x 10(3) M(-1) s(-1)), which was similar to wild-type PTPS (k(cat)/K(m) = 4.1 x 10(3) M(-1) s(-1)). In assays with purified enzymes, wild-type but not PTPS-S19A was a specific substrate for the cGMP-dependent protein kinase (cGK) type I and II. Upon expression in COS-1 cells, PTPS-S19A was stable but not phosphorylated and had a reduced activity of approximately 33% in comparison to wild-type PTPS. Extracts from several human cell lines, including brain, contained a kinase that bound to and phosphorylated immobilized wild-type, but not mutant PTPS. Addition of cGMP stimulated phosphotransferase activity 2-fold. Extracts from transfected COS-1 cells overexpressing cGKII stimulated Ser(19) phosphorylation more than 100-fold, but only 4-fold from cGKI overexpressing cells. Moreover, fibroblast extracts from mice lacking cGKII exhibited significantly reduced phosphorylation of PTPS. These results suggest that Ser(19) of human PTPS may be a substrate for cGKII phosphorylation also in vivo, a modification that is essential for normal activity.     

Inhibition of serotonin-induced mitogenesis, migration, and ERK MAPK nuclear translocation in vascular smooth muscle cells by atorvastatin

The HMG-CoA reductase inhibitors, statins, have pleiotropic effects which may include interference with the isoprenylation of Ras and Rho small GTPases. Statins have beneficial effects in animal models of pulmonary hypertension, although their mechanisms of action remain to be determined. Serotonin [5-hydroxytryptamine (5-HT)] is implicated in the process of pulmonary artery smooth muscle (PASM) remodeling as part of the pathophysiology of pulmonary hypertension. We examined the effect of atorvastatin on 5-HT-induced PASM cell responses. Atorvastatin dose dependently inhibits 5-HT-induced mitogenesis and migration of cultured bovine PASM cells. Inhibition by atorvastatin was reversed by mevalonate and geranylgeranylpyrophosphate (GGPP) supplement, suggesting that the statin targets a geranylgeranylated protein such as Rho. Concordantly, atorvastatin inhibits 5-HT-induced cellular RhoA activation, membrane localization, and Rho kinase-mediated phosphorylation of myosin phosphatase-1 subunit. Atorvastatin reduced activated RhoA-induced serum response factor-mediated reporter activity in HEK293 cells, indicating that atorvastatin inhibits Rho signaling, and this was reversed by GGPP. While 5-HT-induced ERK MAP and Akt kinase activation were unaffected by atorvastatin, 5-HT-induced ERK nuclear translocation was attenuated in a GGPP-dependent fashion. These studies suggest that atorvastatin inhibits 5-HT-induced PASM cell mitogenesis and migration through targeting isoprenylation which may, in part, attenuate the Rho pathway, a mechanism that may apply to statin effects on in vivo models of pulmonary hypertension.     

Palmitoylation of the human prostacyclin receptor. Functional implications of palmitoylation and isoprenylation

We have previously established that isoprenylation of the prostacyclin receptor (IP) is required for its efficient G protein coupling and effector signaling (Hayes, J. S., Lawler, O. A., Walsh, M. T., and Kinsella, B. T. (1999) J. Biol. Chem. 274, 23707-23718). In the present study, we sought to investigate whether the IP may actually be subject to palmitoylation in addition to isoprenylation and to establish the functional significance thereof. The human (h) IP was efficiently palmitoylated at Cys(308) and Cys(311), proximal to transmembrane domain 7 within its carboxyl-terminal (C)-tail domain, whereas Cys(309) was not palmitoylated. The isoprenylation-defective hIP(SSLC) underwent palmitoylation but did not efficiently couple to G(s) or G(q), confirming that isoprenylation is required for G protein coupling. Deletion of C-tail sequences distal to Val(307) generated hIP(Delta307) that was neither palmitoylated nor isoprenylated and did not efficiently couple to G(s) or to G(q), whereas hIP(Delta312) was palmitoylated and ably coupled to both effector systems. Conversion of Cys(308), Cys(309), Cys(311), Cys(308,309), or Cys(309,311) to corresponding Ser residues, while leaving the isoprenylation CAAX motif intact, did not affect hIP coupling to G(s) signaling, whereas mutation of Cys(308,311) and Cys(308,309,311) abolished signaling, indicating that palmitoylation of either Cys(308) or Cys(311) is sufficient to maintain functional G(s) coupling. Although mutation of Cys(309) and Cys(311) did not affect hIP-mediated G(q) coupling, mutation of Cys(308) abolished signaling, indicating a specific requirement for palmitoylation of Cys(308) for G(q) coupling. Consistent with this, neither hIP(C308S,C309S), hIP(C308S,C311S), nor hIP(C308S,C309S,C311S) coupled to G(q). Taken together, these data confirm that the hIP is isoprenylated and palmitoylated, and collectively these modifications modulate its G protein coupling and effector signaling. We propose that through lipid modification followed by membrane insertion, the C-tail domain of the IP may contain a double loop structure anchored by the dynamically regulated palmitoyl groups proximal to transmembrane domain 7 and by a distal farnesyl isoprenoid permanently attached to its carboxyl terminus.     

Rhodopsin's carboxyl-terminal threonines are required for wild-type arrestin-mediated quench of transducin activation in vitro

Many recent reports have demonstrated that rhodopsin's carboxyl-terminal serine residues are the main targets for phosphorylation by rhodopsin kinase. Phosphorylation at the serines would therefore be expected to promote high-affinity arrestin binding. We have examined the roles of the carboxyl serine and threonine residues during arrestin-mediated deactivation of rhodopsin using an in vitro transducin activation assay. Mutations were introduced into a synthetic bovine rhodopsin gene and expressed in COS-7 cells. Individual serine and threonine residues were substituted with neutral amino acids. The ability of the mutants to act as substrates for rhodopsin kinase was analyzed. The effect of arrestin on the activities of the phosphorylated mutant rhodopsins was measured in a GTPgammaS binding assay involving purified bovine arrestin, rhodopsin kinase, and transducin. A rhodopsin mutant lacking the carboxyl serine and threonine residues was not phosphorylated by rhodopsin kinase, demonstrating that phosphorylation is restricted to the seven putative phosphorylation sites. A rhodopsin mutant possessing a single phosphorylatable serine at 338 demonstrated no phosphorylation-dependent quench by arrestin. These results suggest that singly phosphorylated rhodopsin is deactivated through a mechanism that does not involve arrestin. Analysis of additional mutants revealed that the presence of threonine in the carboxyl tail of rhodopsin provides for greater arrestin-mediated quench than does serine. These results suggest that phosphorylation site selection could serve as a mechanism to modulate the ability of arrestin to quench rhodopsin.     

Rhodopsin kinase: substrate specificity and factors that influence activity

Rhodopsin kinase was prepared from bovine retinas by the method of Sitaramayya [Sitaramayya, A. (1986) Biochemistry 25, 5460] with some minor modifications. The enzyme is able to phosphorylate bovine rhodopsin in the disk membrane, rhodopsin from other species, and rhodopsin solubilized in mild detergent (dodecyl maltoside). Rhodopsin kinase can phosphorylate synthetic peptides containing the appropriate sequences from bovine rhodopsin; however, the Km values for these peptides are about 3 orders of magnitude higher than that for rhodopsin or ATP. Some peptides from the cytosolic surface of rhodopsin inhibit the phosphorylation. These results suggest that more than one region of rhodopsin is involved in the interaction of rhodopsin of the kinase. Mg2+ is required for the Mg-ATP complex as shown by the observation that (ethylenedinitrilo)tetraacetic acid inhibits kinase activity. Second, free Mg2+ above the concentration required to complex all of the ATP present activates the kinase. Third, higher concentrations of Mg2+ yield Mg-ATP-Mg instead of Mg-ATP and therefore inhibit the kinase activity. Other physiologically important cations such as Ca2+, Na+, and K+ reduce the activity of the kinase, probably by forming a metal ion-ATP complex, thereby reducing the concentration of Mg-ATP. 5'-[p-(Fluorosulfonyl)benzoyl]adenosine (FSO2BzAdo), an inhibitor of kinases and ATPases, inhibits rhodopsin kinase according to pseudo-first-order kinetics. The relationship between the first-order constant and the concentration of FSO2BzAdo is hyperbolic. This indicates that a reversible complex between the ATP analogue and the enzyme is formed prior to the covalent attachment of the analogue to rhodopsin kinase.(ABSTRACT TRUNCATED AT 250 WORDS)