On the disulphide bonds of rhodopsins

Structure and function in rhodopsin: Mass spectrometric identification of the abnormal intradiscal disulfide bond in misfolded retinitis pigmentosa mutants

Retinitis pigmentosa (RP) point mutations in both the intradiscal (ID) and transmembrane domains of rhodopsin cause partial or complete misfolding of rhodopsin, resulting in loss of 11-cis-retinal binding. Previous work has shown that misfolding is caused by the formation of a disulfide bond in the ID domain different from the native Cys-110-Cys-187 disulfide bond in native rhodopsin. Here we report on direct identification of the abnormal disulfide bond in misfolded RP mutants in the transmembrane domain by mass spectrometric analysis. This disulfide bond is between Cys-185 and Cys-187, the same as previously identified in misfolded RP mutations in the ID domain. The strategy described here should be generally applicable to identification of disulfide bonds in other integral membrane proteins.

Irreversible activation of the gonadotropin-releasing hormone receptor by photoaffinity cross-linking: localization of attachment site to Cys residue in N-terminal segment

Photoaffinity cross-linking with [azidobenzoyl-d-Lys6]GnRH leads to irreversible activation of the gonadotropin-releasing hormone (GnRH) receptor. In order to localize the cross-linking site, the disulfide bridge structure was initially probed by mutagenesis. A consistent pattern of changes in the ability of GnRH to stimulate signal transduction after Ser substitutions of extracellularly located Cys residues indicated that Cys14 in the N-terminal domain is connected to Cys200 in the second extracellular loop, while Cys196 in this loop is connected to the highly conserved Cys114 at the extracellular end of transmembrane helix 3. Protein chemical analysis of radioactive fragments of cross-linked GnRH receptor following deglycosylation and enzymatic digest with endoproteinase Glu-C and trypsin before and after introduction or elimination of potential protease cleavage sites indicated that 125I[azidobenzoyl-d-Lys6]GnRH cross-links to a segment comprising residues 12-18 of the N-terminal domain. The existence of the Cys114-Cys196 bridge was directly confirmed as a labeled fragment, including that Cys114 was resolvable only under reducing conditions. The observation that the cross-linked N-terminal enzymatic fragments had identical apparent size under non-reducing conditions shows that the cross-linking reaction disconnected the disulfide bridge between Cys14 and Cys200 and indicates that Cys14 is probably the residue involved in cross-linking of the ligand. It is concluded that covalent tethering of GnRH through a photoreactive side chain located at position 6 in the middle of the peptide leads to continued activation of the receptor presumably through covalent binding to Cys14 in the N-terminal domain of the receptor.

Point mutations in bovine opsin can be classified in four groups with respect to their effect on the biosynthetic pathway of opsin

Expression in vitro with the recombinant baculovirus expression system showed correct biosynthesis and post-translational processing of "wild-type' bovine opsin with regard to translocation, glycosylation, palmitoylation and targeting. However, several of these processes were severely affected by point mutations. From the overall results of 16 mutants reported here, four groups were distinguished. One group significantly affected neither biosynthesis nor folding of opsin (D83N, P291A, A299C-V300A-P303G). A second group produced a truncated protein (R69H, Y301F), suggesting that these positions are essential for a correct translational process. A third group affected membrane translocation as well as glycosylation, which can be interpreted as interference with the function of a transfer signal. Substitutions at positions Glu-113, Glu-122, Glu-134, Arg-135 and Lys-248 belong to this category. A fourth group induced structural changes in the protein that led to heterogeneous distribution in the plasma membrane (E113Q/D, W265F, Y268S). Taking any functional consequences of these mutations into consideration, it seems that point mutations can have mosaic effects and therefore should be examined at several levels (folding, targeting, functional parameters).

Effect of carboxyl mutations on functional properties of bovine rhodopsin

Bovine rod rhodopsin and membrane-carboxyl group mutants are expressed using the recombinant baculovirus expression system. Biosynthesis of wild-type and the mutant D83N is normal. The mutations E122L and E134D/R affect glycosylation and translocation. After regeneration, purification and reconstitution in retina lipids a wild-type photosensitive pigment with spectral and photolytic properties identical to native bovine rod rhodopsin is generated. Only the mutations D83N and E122L affect the spectral properties and then only slightly. All mutations induce a shift in the Meta I<==>Meta II equilibrium towards Meta I (E134D/R) or Meta II (D83N, E122L). FT-IR analysis shows that the mutation E134D/R does not significantly affect the carboxyl-vibration region but, in particular in the case of E134R, affects secondary structural changes upon Meta II formation. E122L also has an effect on secondary structural changes and in addition eliminates a negative band at 1728 cm-1. The mutation D83N removes a pair of negative/positive bands from the carboxyl-vibration region, indicating that Asp83 stays protonated upon formation of Meta II but undergoes a change in hydrogen bonding.

Cloning and expression of frog rhodopsin cDNA

The cDNA encoding the putative rhodopsin of frog (Rana catesbeiana) was cloned and expressed in cultured cells. The deduced amino acid sequence (354 residues) has more than 90% identity with the rhodopsins of two other frogs (Rana pipiens and Xenopus laevis) and 80% identity with other vertebrate rhodopsins. The isoelectric point calculated from the sequence was about 8.2, which is intermediate between rhodopsins and the cone visual pigments of higher vertebrates. The cloned cDNA was expressed in cultured mammalian cells. The difference absorbance maximum before and after photobleaching was about 500 nm, the same as that observed in the retina, demonstrating that the cloned cDNA does indeed encode functional rhodopsin.

The phospho-opsin phosphatase from bovine rod outer segments. An insight into the mechanism of stimulation of type-2A protein phosphatase activity by protamine

The vertebrate visual transduction system involves a cycle of phosphorylation and dephosphorylation of a transmembranous photoreceptor (rhodopsin). Upon illumination, the activated photoreceptor (metarhodopsin-II) is phosphorylated by a specific kinase on up to seven serine and threonine residues. A dephosphorylation process must then be undertaken to return the photoreceptor to its ground state. Initial work, along with studies using the rabbit skeletal muscle catalytic subunit of protein phosphatase 2A, indicated that the phosphatase responsible was a member of the type-2 family. The work has been further extended and using 1000 bovine retinae, the catalytic subunit and a holoenzyme form of phospho-opsin phosphatase were purified 2100-fold and 550-fold respectively. The stimulation of the activities of both these fractions with protamine sulphate and the inhibition by okadaic acid are consistent with the fact that these phosphatases belong to the type-2A family. Western blotting using a variety of specific antibodies established that the catalytic subunit (36 kDa, C subunit) was indeed of type 2A, while the holoenzyme was a heterotrimer comprising the preceding catalytic subunit complexed to two other polypeptides of 55 kDa (B subunit) and 65 kDa (A subunit), both of which were of alpha subtype; phospho-opsin phosphatase may thus be described as a trimeric enzyme containing the ABC subunits of type-2A protein phosphatase, i.e. PP2A1. The dephosphorylation of phospho-opsin by both fractions was found to be stimulated (4-8-fold) by the presence of protamine sulphate (250 micrograms/ml; 50 microM). However, when phospho-peptides corresponding to the C-terminal region of opsin were used, these were maximally dephosphorylated without requiring the presence of protamine; at equivalent concentrations of substrates the phospho-peptides were dephosphorylated (in the absence of protamine) at rates which were approximately equal to those obtained with phospho-opsin (in the presence of protamine). It was shown that type-1 phosphatases had little activity against these phospho-peptides. Furthermore, if phospho-opsin was treated with protamine, the activity of the phosphatase assumed an elevated level and was not significantly stimulated by the addition of exogenous protamine. This effect could be reversed by washing the protamine-treated substrate with 1 M NaCl, whence the protamine-dependent stimulation returned to normal levels. To this end, studies revealed that protamine was binding to the particulate substrate in a ratio of protamine/opsin of 0.7:1. The cumulative finding may be rationalised by suggesting that the effect of protamine is a substrate-directed phenomenon and a hypothetical mechanism for this effect is considered.

Structure and function in rhodopsin: replacement by alanine of cysteine residues 110 and 187, components of a conserved disulfide bond in rhodopsin, affects the light-activated metarhodopsin II state

A disulfide bond that is evidently conserved in the guanine nucleotide-binding protein-coupled receptors is present in rhodopsin between Cys-110 and Cys-187. We have replaced these two cysteine residues by alanine residues and now report on the properties of the resulting rhodopsin mutants. The mutant protein C110A/C187A expressed in COS cells resembles wild-type rhodopsin in the ground state. It folds correctly to bind 11-cis-retinal and form the characteristic rhodopsin chromophore. It is inert to hydroxylamine in the dark, and its stability to dark thermal decay is reduced, relative to that of the wild type, by a delta delta G not equal to of only -2.9 kcal/mol. Further, the affinities of the mutant and wild-type rhodopsins to the antirhodopsin antibody rho4D2 are similar, both in the dark and in light. However, the metarhodopsin II (MII) and MIII photointermediates of the mutant are less stable than those formed by the wild-type rhodopsin. Although the initial rates of transducin activation are the same for both mutant and wild-type MII intermediates at 4 degrees C, at 15 degrees C the MII photointermediate in the mutant decays more than 20 times faster than in wild type. We conclude that the disulfide bond between Cys-110 and Cys-187 is a key component in determining the stability of the MII structure and its coupling to transducin activation.

Phosphorylation of solubilised dark-adapted rhodopsin. Insights into the activation of rhodopsin kinase

A protocol for the separation of phosphorhodopsin from phospho-opsin has been developed. The method takes advantage of the finding that, while 0.5% N,N-dimethyldodecylamine-N-oxide completely solubilises membrane-embedded phosphorhodopsin, at this concentration of detergent, phospho-opsin is only sparingly soluble. Phosphorhodopsin solubilised in this manner may be freed from contaminant phospho-opsin by chromatography on hydroxyapatite. Using this method, the rhodopsin-kinase-catalysed phosphorylation of photoexcited rhodopsin and native rhodopsin was studied in rod outer-segment membranes at different levels of bleaching. Prior to analysis of the phosphorylation mixture, the phosphorylated form of photoexcited rhodopsin was converted into phospho-opsin by treatment with NH2OH. It was found that, while at a 5% bleach level the amount of phosphorhodopsin produced was 15% that of phospho-opsin, at 60% bleaching the phosphorhodopsin was less than 1% of phospho-opsin. The phosphorylation reaction under different bleaching conditions was also studied in a completely soluble system (using 2% dodecyl maltoside) and the pattern of phosphate incorporation into rhodopsin versus opsin was identical to that in the membrane system. We have previously proposed that rhodopsin kinase normally exists in an inactive form and is only activated following interaction with photoexcited rhodopsin. The present work strengthens this conclusion and also shows that, following activation, the kinase preferentially phosphorylates photoexcited rhodopsin but can also act upon unbleached rhodopsin. Two possible mechanisms for the activation of the kinase are considered. From the distribution of phosphorhodopsin and phospho-opsin at different bleaching levels, the relative rates of the phosphorylation of photoexcited rhodopsin (kR*) and rhodopsin (kR) were calculated. kR*/kR values for the membrane system of 71 +/- 20 and, for the solubilised system, of 80 +/- 19 were obtained. The algebraic equation used to obtain these values highlights the fact that the ratio of the concentrations of the two substrates, photoexcited rhodopsin and rhodopsin, in a sample, determines the final distribution of phosphate between bleached and unbleached rhodopsin. This conclusion may contribute to the understanding of 'high-gain' phosphorylation observed previously.

Spin labeled cysteines as sensors for protein-lipid interaction and conformation in rhodopsin

In stoichiometric amounts, the spin label N-tempoyl-(p-chloromercuribenzamide) reacts rapidly with one cysteine residue in membrane-bound bovine rhodopsin. This residue is distinct from the two reactive cysteines previously used as attachment sites for spectroscopic labels, and is on the external surface of the protein near the cytoplasmic membrane/aqueous interface. The spin-labeled side chain has revealed a light-induced conformational change in membrane-bound rhodopsin that is apparently not associated with protein aggregation. The changes are reversible upon the addition of 11-cis retinal, and the magnitude of the change is dependent on the identity of the phospholipid in the surrounding bilayer. Alteration of lipid composition has a much larger effect on bleached rhodopsin than rhodopsin itself, indicating that the former is more readily deformable in response to changes in bilayer properties. This is consistent with the loss of 11-cis retinal binding energy in opsin compared to rhodopsin. These results provide direct structural evidence that the conformation of a membrane protein can be modulated by the lipid properties.

In vitro expression of bovine opsin using recombinant baculovirus: the role of glutamic acid (134) in opsin biosynthesis and glycosylation

Expression levels of functional bovine opsin in the insect cell line IPLB-Sf9 using recombinant baculovirus were shown not to depend on the use of novel transfer vectors (pAcRP23, pAcDZ1) that were reported to improve biosynthesis levels of other proteins in this system. A production of 5 micrograms opsin per 10(6) cells (approx. 1.5% of total cell protein) was achieved by batch fermentation of infected cells in spinner cultures. Infection of the cells in the presence of the glycosyltransferase inhibitor tunicamycin led to the synthesis of the complete protein, which, however, now migrated with a substantially lower Mr. This demonstrates that opsin in insect cells also undergoes N-linked glycosylation and allowed partial purification (10-fold) of the resulting rhodopsin by affinity chromatography over Concanavalin A-Sepharose. Through site-directed mutagenesis (rhod)opsin mutants have been obtained allowing dissection of functional domains of opsin. Amino acid substitutions that involved Glu-134 and/or Arg-135 affected the normal biosynthetic process leading in part to nonglycosylated, to a small extent even incomplete, protein. A number of mutations, that involve other charged residues within the second and third transmembrane domain of the protein, had no effect on the biosynthetic processing of the protein. We therefore suggest that the charge-pair Glu-134-Arg-135 is part of an important internal signal sequence and that alterations in this region may result in incorrect membrane translocation and/or folding of the protein.

Three-dimensional modelling of G protein-linked receptors

Members of the G protein-linked receptor superfamily have not yet yielded to X-ray crystallography. However, diffraction data from other membrane-bound receptors - the photosynthetic reaction centre and bacteriorhodopsin - have provided some information that may also apply to the G protein family. John Findlay and Elias Eliopoulos integrate this information together with analysis of amino acid sequences from cloned receptors, to derive workable three-dimensional models of these proteins. Such models identify ligand-binding and G protein-associating domains.

Adrenergic receptors. Models for regulation of signal transduction processes

Adrenergic receptors are prototypic models for the study of the relations between structure and function of G protein-coupled receptors. Each receptor is encoded by a distinct gene. These receptors are integral membrane proteins with several striking structural features. They consist of a single subunit containing seven stretches of 20-28 hydrophobic amino acids that represent potential membrane-spanning alpha-helixes. Many of these receptors share considerable amino acid sequence homology, particularly in the transmembrane domains. All of these macromolecules share other similarities that include one or more potential sites of extracellular N-linked glycosylation near the amino terminus and several potential sites of regulatory phosphorylation that are located intracellularly. By using a variety of techniques, it has been demonstrated that various regions of the receptor molecules are critical for different receptor functions. The seven transmembrane regions of the receptors appear to form a ligand-binding pocket. Cysteine residues in the extracellular domains may stabilize the ligand-binding pocket by participating in disulfide bonds. The cytoplasmic domains contain regions capable of interacting with G proteins and various kinases and are therefore important in such processes as signal transduction, receptor-G protein coupling, receptor sequestration, and down-regulation. Finally, regions of these macromolecules may undergo posttranslational modifications important in the regulation of receptor function. Our understanding of these complex relations is constantly evolving and much work remains to be done. Greater understanding of the basic mechanisms involved in G protein-coupled, receptor-mediated signal transduction may provide leads into the nature of certain pathophysiological states.

Assessment of the number of free cysteines and isolation and identification of cystine-containing peptides from acetylcholine receptor

The number of free cysteines in each polypeptide of acetylcholine receptor from the electric organ of Torpedo californica has been assessed by alkylating the native protein with N-ethylmaleimide and iodoacetamide during homogenization of the tissue and alkylating the polypeptides with N-ethylmaleimide as they were unfolded in solutions of dodecyl sulfate. The cysteines unavailable for alkylation could be accounted for as specific cystines, connecting positions in the amino acid sequences of the individual polypeptides. Unreduced, alkylated polypeptides of acetylcholine receptor were digested with thermolysin or trypsin. Cystine-containing peptides in the chromatograms of the digests were identified electrochemically by the use of a dual gold/mercury electrode. Three thermolytic peptides and three tryptic peptides have been isolated from these digests and shown to contain intact cystines that were originally present in the native protein. The majority of these peptides contained an intact, intramolecular cystine connecting two cysteines in locations homologous to cysteines 128 and 142 from the alpha polypeptide. Each of these cystines from each of the polypeptides of acetylcholine receptor was isolated in at least one peptide, respectively. Each of these cystine-containing peptides also contained glucosamine. It can be concluded that each asparagine in the sequence Asn-Cys-Thr/Ser, which occurs in the respective, homologous location in every polypeptide, is glycosylated even though a cystine sits between the asparagine and the threonine or serine. In addition, the existence of the cystine connecting the adjacent cysteines, alpha 192 and alpha 193, in the alpha subunit of acetylcholine receptor [Kao, P. N., & Karlin, A. (1986) J. Biol. Chem. 261, 8085-8088] has been confirmed.

Cysteine residues 110 and 187 are essential for the formation of correct structure in bovine rhodopsin

To investigate the role of different cysteine residues in bovine rhodopsin, a series of mutants were prepared in which the cysteine residues were systematically replaced by serines. The mutant genes were expressed in monkey kidney cells (COS-1) and the mutant opsins were evaluated for their levels of expression, glycosylation patterns, and ability to form the chromophore characteristic of rhodopsin and to activate transducin. Substitution of the three cytoplasmic cysteines (Cys-316, Cys-322, and Cys-323) and the four membrane-embedded cysteines (Cys-140, Cys-167, Cys-222, and Cys-264) produced proteins with wild-type phenotype. Also, single substitutions of Cys-185 gave rise to a wild-type phenotype. In contrast, substitution of the three intradiscal cysteines (Cys-110, Cys-185, and Cys-187) or single substitution of Cys-110 or Cys-187 gave proteins that were expressed at reduced levels, glycosylated abnormally, and unable to bind 11-cis-retinal. Thus, of the 10 cysteines in bovine rhodopsin, only intradiscal Cys-110 and Cys-187 are essential for the correct tertiary structure of the protein.