NMR analysis of rhodopsin-transducin interactions.

Heterotrimeric G-protein activation by an agonist-stimulated G-protein coupled receptor (R*) requires the propagation of structural signals from the receptor interacting surfaces to the guanine nucleotide-binding pocket. Employing high-resolution NMR methods, we are probing heterotrimer-associated and rhodopsin-stimulated changes in an isotope-labeled G-protein alpha-subunit (G(alpha)). A key aspect of the work involves the trapping and interrogation of discrete R*-bound conformations of G(alpha). Our results demonstrate that functionally important changes in G(alpha) structure and dynamics can be detected and characterized by NMR, enabling the generation of robust models for the global and local structural changes accompanying signal transfer from R* to the G-protein.

Evidence for structural changes in carboxyl-terminal peptides of transducin alpha-subunit upon binding a soluble mimic of light-activated rhodopsin.

Although a high-resolution crystal structure for the ground state of rhodopsin is now available, portions of the cytoplasmic surface are not well resolved, and the structural basis for the interaction of the cytoplasmic loops with the retinal G-protein transducin (G(t)) is still unknown. Previous efforts aimed at the design, construction, and functional characterization of soluble mimics for the light-activated state of rhodopsin have shown that grafting defined segments from the cytoplasmic region of bovine opsin onto a surface loop in a mutant form of thioredoxin (HPTRX) is sufficient to confer partial G(t) activating potential [Abdulaev et al. (2000) J. Biol. Chem. 275, 39354-39363]. To assess whether these designed mimics could provide a structural insight into the interaction between light-activated rhodopsin and G(t), the ability of an HPTRX fusion protein comprised of the second (CD) and third (EF) cytoplasmic loops (HPTRX/CDEF) to bind G(t) alpha-subunit (G(t)(alpha)) peptides was examined using nuclear magnetic resonance (NMR) spectroscopy. Transfer NOESY (TrNOESY) experiments show that an 11 amino acid peptide corresponding to the carboxyl terminus of G(t)(alpha) (GtP), as well as a "high-affinity" peptide analogue, HAP1, binds to HPTRX/CDEF in the fast-exchange regime and undergoes similar, subtle structural changes at the extreme carboxyl terminus. Observed TrNOEs suggest that both peptides when bound to HPTRX/CDEF adopt a reverse turn that is consistent with the C-cap structure that has been previously reported for the interaction of GtP with the light-activated signaling state, metarhodopsin II (MII). In contrast, TrNOESY spectra provide no evidence for structuring of the amino terminus of either GtP or HAP1 when bound to HPTRX/CDEF, nor do the spectra show any measurable changes in the CD and EF loop resonances of HPTRX/CDEF, which are conformationally dynamic and significantly exchange broadened. Taken together, the NMR observations indicate that HPTRX/CDEF, previously identified as a functional mimic of MII, is also an approximate structural mimic for this light-activated state of rhodopsin.

Functionally discrete mimics of light-activated rhodopsin identified through expression of soluble cytoplasmic domains.

Numerous studies on the seven-helix receptor rhodopsin have implicated the cytoplasmic loops and carboxyl-terminal region in the binding and activation of proteins involved in visual transduction and desensitization. In our continuing studies on rhodopsin folding, assembly, and structure, we have attempted to reconstruct the interacting surface(s) for these proteins by inserting fragments corresponding to the cytoplasmic loops and/or the carboxyl-terminal tail of bovine opsin either singly, or in combination, onto a surface loop in thioredoxin. The purpose of the thioredoxin fusion is to provide a soluble scaffold for the cytoplasmic fragments thereby allowing them sufficient conformational freedom to fold to a structure that mimics the protein-binding sites on light-activated rhodopsin. All of the fusion proteins are expressed to relatively high levels in Escherichia coli and can be purified using a two- or three-step chromatography procedure. Biochemical studies show that some of the fusion proteins effectively mimic the activated conformation(s) of rhodopsin in stimulating G-protein or competing with the light-activated rhodopsin/G-protein interaction, in supporting phosphorylation of the carboxyl-terminal opsin fragment by rhodopsin kinase, and/or phosphopeptide-stimulated arrestin binding. These results suggest that specific segments of the cytoplasmic surface of rhodopsin can adopt functionally discrete conformations in the absence of the connecting transmembrane helices and retinal chromophore.

Folding and assembly in rhodopsin. Effect of mutations in the sixth transmembrane helix on the conformation of the third cytoplasmic loop.

Previous studies on bovine opsin folding and assembly have identified an amino-terminal fragment, EF(1-232), which folds and inserts into a membrane only after coexpression with its complementary carboxyl-terminal fragment, EF(233-348). To further characterize this interaction, EF(1-232) production was examined upon coexpression with carboxyl-terminal fragments of varying length and/or amino acid composition. These included fragments with incremental deletions of the third cytoplasmic loop (TH(241-348) and EF(249-348)), a fragment composed of the third cytoplasmic loop and sixth transmembrane helix (HF(233-280)), a fragment composed of the sixth and seventh transmembrane helices (FG(249-312)), and EF(233-348) and TH(241-348) fragments with Pro-267 or Trp-265 mutations. Although EF(1-232) production was independent of the third cytoplasmic loop and carboxyl-terminal tail, both the sixth and seventh transmembrane helices were essential. The effects of mutations in the sixth transmembrane helix on EF(1-232) expression were dependent on the length of the third cytoplasmic loop. Although Pro-267 mutations in EF(233-348) failed to stabilize EF(1-232) expression, their introduction into TH(241-348) was without discernible effects. However, Trp-265 substitutions in the EF(233-348) and TH(241-348) fragments conferred significant EF(1-232) production. Therefore, key residues in the transmembrane helices may exert their effects on opsin folding, assembly, and/or function by influencing the conformation of the connecting loops.

The three-dimensional structures of two isoforms of nucleoside diphosphate kinase from bovine retina.

The crystal structures of two isoforms of nucleoside diphosphate kinase from bovine retina overexpressed in Escherischia coli have been determined to 2.4 A resolution. Both the isoforms, NBR-A and NBR-B, are hexameric and the fold of the monomer is in agreement with NDP-kinase structures from other biological sources. Although the polypeptide chains of the two isoforms differ by only two residues, they crystallize in different space groups. NBR-A crystallizes in space group P212121 with an entire hexamer in the asymmetric unit, while NBR-B crystallizes in space group P43212 with a trimer in the asymmetric unit. The highly conserved nucleotide-binding site observed in other nucleoside diphosphate kinase structures is also observed here. Both NBR-A and NBR-B were crystallized in the presence of cGMP. The nucleotide is bound with the base in the anti conformation. The NBR-A active site contained both cGMP and GDP each bound at half occupancy. Presumably, NBR-A had retained GDP (or GTP) from the purification process. The NBR-B active site contained only cGMP.

Nucleoside diphosphate kinase from bovine retina: purification, subcellular localization, molecular cloning, and three-dimensional structure.

The biochemical and structural properties of bovine retinal nucleoside diphosphate kinase were investigated. The enzyme showed two polypeptides of approximately 17.5 and 18.5 kDa on SDS-PAGE, while isoelectric focusing revealed seven to eight proteins with a pI range of 7.4-8.2. Sedimentation equilibrium yielded a molecular mass of 96 +/- 2 kDa for the enzyme. Carbohydrate analysis revealed that both polypeptides contained Gal, Man, GlcNAc, Fuc, and GalNac saccharides. Like other nucleoside diphosphate kinases, the retinal enzyme showed substantial differences in the Km values for various di- and triphosphate nucleotides. Immunogold labeling of bovine retina revealed that the enzyme is localized on both the membranes and in the cytoplasm. Screening of a retinal cDNA library yielded full-length clones encoding two distinct isoforms (NBR-A and NBR-B). Both isoforms were overexpressed in Escherichia coli and their biochemical properties compared with retinal NDP-kinase. The structures of NBR-A and NBR-B were determined by X-ray crystallography in the presence of guanine nucleotide(s). Both isoforms are hexameric, and the fold of the monomer is similar to other nucleoside diphosphate kinase structures. The NBR-A active site contained both a cGMP and a GDP molecule each bound at half occupancy while the NBR-B active site contained only cGMP.

Light-induced exposure of the cytoplasmic end of transmembrane helix seven in rhodopsin.

A key step in signal transduction in the visual cell is the light-induced conformational change of rhodopsin that triggers the binding and activation of the guanine nucleotide-binding protein. Site-directed mAbs against bovine rhodopsin were produced and used to detect and characterize these conformational changes upon light activation. Among several antibodies that bound exclusively to the light-activated state, an antibody (IgG subclass) with the highest affinity (Ka approximately 6 x 10(-9) M) was further purified and characterized. The epitope of this antibody was mapped to the amino acid sequence 304-311. This epitope extends from the central region to the cytoplasmic end of the seventh transmembrane helix and incorporates a part of a highly conserved NPXXY motif, a critical region for signaling and agonist-induced internalization of several biogenic amine and peptide receptors. In the dark state, no binding of the antibody to rhodopsin was detected. Accessibility of the epitope to the antibody correlated with formation of the metarhodopsin II photointermediate and was reduced significantly at the metarhodopsin III intermediate. Further, incubation of the antigen-antibody complex with 11-cis-retinal failed to regenerate the native rhodopsin chromophore. These results suggest significant and reversible conformational changes in close proximity to the cytoplasmic end of the seventh transmembrane helix of rhodopsin that might be important for folding and signaling.

Functional expression of bovine opsin in the methylotrophic yeast Pichia pastoris.

The methylotrophic yeast Pichia pastoris was examined for functional expression of bovine opsin. An expression plasmid was constructed where the bovine opsin gene was placed downstream from the P. pastoris alcohol oxidase 1 gene promoter and fused at its amino-terminus to the acid phosphatase secretion signal. Quantitative-competitive PCR analysis of a stable yeast transformant showed that one copy of the opsin gene was integrated into the yeast genome. The expression level in this transformant corresponded to approximately 0.3 mg of opsin per liter of cell culture (A600 = 1.0). Sucrose density sedimentation analysis indicated that the opsin was associated exclusively with the membrane fraction. Similar to retinal opsin, P. pastoris-expressed opsin migrated as a single band of approximately 37 kDa on SDS-PAGE and showed high mannose N-glycosylation. A portion of the expressed opsin (approximately 4-15%) reacted with 11-cis-retinal to form the rhodopsin chromophore (lambda max 500 nm), and after purification showed ground and excited state spectral characteristics indistinguishable from those of the native pigment. Further, the metarhodopsin-II-mediated G-protein-activating potential of yeast expressed rhodopsin was similar to that of native rhodopsin. These results show that P. pastoris cells have the capacity to functionally express bovine opsin.

Examining rhodopsin folding and assembly through expression of polypeptide fragments.

Previous work on the expression of bovine opsin fragments separated in the cytoplasmic region has allowed the identification of specific polypeptide segments that contain sufficient information to fold independently, insert into a membrane, and assemble to form a functional photoreceptor. To further examine the contributions of these and other polypeptide segments to the mechanism of opsin folding and assembly, we have constructed 20 additional opsin gene fragments where the points of separation occur in the intradiscal, transmembrane, and cytoplasmic regions. Nineteen of the fragments were stably expressed in COS-1 cells. A five-helix fragment was stably produced only after coexpression with its complementary two-helix fragment. Two fragments composed of the amino-terminal region and the first transmembrane helix were not N-glycosylated and were only partially membrane integrated. One of the singly expressed fragments, which is truncated after the retinal attachment site, bound 11-cis-retinal. Of the coexpressed complementary fragments, only those separated in the second intradiscal and third cytoplasmic regions formed noncovalently linked rhodopsin. Both of the pigments showed reduced transducin activation. Therefore, while many opsin fragments contain enough information to fold and insert into a membrane, only those separated at specific locations assemble to a retinal-binding opsin.

Mapping light-dependent structural changes in the cytoplasmic loop connecting helices C and D in rhodopsin: a site-directed spin labeling study.

All 20 single cysteine substitution mutants in the sequence Y136-M155 of bovine rhodopsin have been prepared and modified with a sulfhydryl-specific nitroxide reagent. This sequence contains the C-D interhelical loop, a transducin interaction site. The accessibilities of the attached nitroxides to collisions with paramagnetic probes in solution were determined, and the electron paramagnetic resonance spectra were analyzed, both in the dark and after photoexcitation. Accessibility data show that the rhodopsin polypeptide crosses an aqueous/hydrophobic boundary near V138 and H152. The nitroxide mobilities inferred from the spectra are consistent with a model where the C helix extends to at least residue C140, with much of the helix surface in contact with protein rather than lipid near the cytoplasmic surface of the membrane. Upon photoexcitation, electron paramagnetic resonance spectral changes are observed at sites on the putative C helix surface that are in contact with the protein and at specific sites in the C-D interhelical loop. A simple interpretation of these results is that photoexcitation involves a rigid body movement of the C helix relative to the others in the helix bundle.

Mapping of the amino acids in the cytoplasmic loop connecting helices C and D in rhodopsin. Chemical reactivity in the dark state following single cysteine replacements.

The cytoplasmic loop connecting helices C and D in rhodopsin is a part of the region involved in protein-protein interactions during signal transduction. To probe the structure of the CD loop, we have replaced, one at a time, the amino acids 136-150 by cysteine residues. The cysteine substitution mutants contained only the introduced single reactive cysteines and were prepared from a base opsin mutant that retained only the three intradiscal cysteines. All of the cysteine substitution mutants formed the characteristic rhodopsin chromophore (lambda max, 500 nm) with 11-cis-retinal. They showed normal photobleaching characteristics and activated transducin in a light-dependent manner, albeit at lower levels than the wild-type pigment. The newly introduced cysteines in the substitution mutants all underwent alkylation in the dark with the membrane-permeant sulfhydryl reagent N-ethylmaleimide, but with varying rates. The cysteine substitution mutants also showed prominent differences in alkylation with membrane-impermeant N-polymethylenecarboxylmaleimides of various alkyl chain lengths. Notably, derivatization of the cysteines in the mutants was not observed with the polar sulfhydryl reagents iodoacetic acid or iodoacetamide. These findings highlight intrinsic differences in both the reactivity and accessibility of the different cysteine residues in the CD loop and support the important role for a structure in the second cytoplasmic region of rhodopsin.

In vivo assembly of rhodopsin from expressed polypeptide fragments.

Rhodopsin folding and assembly were investigated by expression of five bovine opsin gene fragments separated at points corresponding to proteolytic cleavage sites in the second or third cytoplasmic regions. The CH(1-146) and CH(147-348) gene fragments encode amino acids 1-146 and 147-348 of opsin, while the TH(1-240) and TH(241-348) gene fragments encode amino acids 1-240 and 241-348, respectively. Another gene fragment, CT(147-240), encodes amino acids 147-240. All five opsin polypeptide fragments were stably produced upon expression of the corresponding gene fragments in COS-1 cells. The singly expressed polypeptide fragments failed to form a chromophore with 11-cis-retinal, whereas coexpression of two or three complementary fragments [CH(1-146) + CH(147-348), TH(1-240) + TH(241-348), or CH(1-146) + CT(147-240) + TH(241-348)] formed pigments with spectral properties similar to wild-type rhodopsin. The NH2-terminal polypeptide in these rhodopsins showed a glycosylation pattern characteristic of wild-type COS-1 cell rhodopsin and was noncovalently associated with its complementary fragment(s). Further, the CH(1-146) + CH(147-348) rhodopsin showed substantial light-dependent activation of transducin. We conclude that the functional assembly of rhodopsin is mediated by the association of at least three protein-folding domains.

Structure and function in rhodopsin. Separation and characterization of the correctly folded and misfolded opsins produced on expression of an opsin mutant gene containing only the native intradiscal cysteine codons.

Previous mutagenesis studies have indicated the requirement of a tertiary structure in the intradiscal region with a disulfide bond between Cys-110 and Cys-187 for the correct assembly and/or function of rhodopsin. We have now studied a rhodopsin mutant in which only the natural intradiscal cysteines at positions 110, 185, and 187 are present while all the remaining seven cysteines in the wild-type bovine rhodopsin have been replaced by serines. The proteins formed on expression of this mutant in COS-1 cells bind 11-cis-retinal only partially to form the rhodopsin chromophore. We show that this is due to the presence of both correctly folded chromophore-forming opsin and misfolded opsins. Methods have been devised for the separation of the correctly folded and misfolded forms by selective elution from immunoaffinity adsorbants. Using several criteria, which include SDS-PAGE as well as UV/visible and CD spectroscopy, we find that the correctly folded mutant protein is indistinguishable in its spectral properties from the wild-type rhodopsin. Further, reaction of sulfhydryl groups in the correctly folded mutant pigment with N-ethylmaleimide indicates that alkylation of a single sulfhydryl requires denaturation or illumination, while reaction with an additional two sulfhydryl groups occurs only after reduction. The misfolded mutant opsins are characterized by reduced alpha-helical content, sulfhydryl reactivity under native conditions in the dark, and also the presence of a disulfide bond.(ABSTRACT TRUNCATED AT 250 WORDS)

Structure and function in rhodopsin: the role of asparagine-linked glycosylation.

Rhodopsin, the dim light photoreceptor of the rod cell, is an integral membrane protein that is glycosylated at Asn-2 and Asn-15. Here we report experiments on the role of the glycosylation in rhodopsin folding and function. Nonglycosylated opsin was prepared by expression of a wild-type bovine opsin gene in COS-1 cells in the presence of tunicamycin, an inhibitor of asparagine-linked glycosylation. The non-glycosylated opsin folded correctly as shown by its normal palmitoylation, transport to the cell surface, and the formation of the characteristic rhodopsin chromophore (lambda max, 500 nm) with 11-cis-retinal. However, the nonglycosylated rhodopsin showed strikingly low light-dependent activation of GT at concentration levels comparable with those of glycosylated rhodopsin. Amino acid replacements at positions 2 and 15 and the cognate tripeptide consensus sequence [Asn-2-->Gln, Gly-3-->Cys(Pro), Thr-4-->Lys, Asn-15-->Ala(Cys, Glu, Lys, Gln, Arg), Lys-16-->Cys(Arg), Thr-17-->Met(Val)] showed that the substitutions at Asn-2, Gly-3, and Thr-4 had no significant effect on the folding, cellular transport, and/or function of rhodopsin, whereas those at Asn-15 and Lys-16 caused poor folding and were defective in transport to the cell surface. Further, mutant pigments with amino acid replacements at Asn-15 and Thr-17 activated GT very poorly. We conclude that Asn-15 glycosylation is important in signal transduction.

Palmitoylation of bovine opsin and its cysteine mutants in COS cells.

Previously, bovine rhodopsin has been shown to be palmitoylated at cysteine residues 322 and 323. Here we report on palmitoylation of bovine opsin in COS-1 cells following expression of the synthetic wild-type opsin gene and several of its cysteine mutants in the presence of [3H]palmitic acid. Two moles of palmitic acid are introduced per wild-type opsin molecule in thioester linkages. Palmitoylation is abolished when both Cys-322 and Cys-323 are replaced by serine residues. Replacement of Cys-322 by serine prevents palmitoylation at Cys-323, whereas replacement of the latter with serine allows palmitoylation at Cys-322. Opsin mutants that evidently do not contain a Cys-110/Cys-187 disulfide bond and presumably remain in the endoplasmic reticulum are not palmitoylated. Replacement of Cys-140 or Cys-185 reduces the extent of palmitoylation of the opsin. Lack of palmitoylation at Cys-322 and/or Cys-323 does not affect 11-cis-retinal binding, absorption maximum or extinction coefficient of the chromophore, the bleaching behavior of the chromophore, or the light-dependent binding and activation of transducin. Mutants containing serine substitutions at Cys-140 or Cys-323 showed reduced light-dependent phosphorylation by rhodopsin kinase.

Light-stable rhodopsin. II. An opsin mutant (TRP-265----Phe) and a retinal analog with a nonisomerizable 11-cis configuration form a photostable chromophore.

In order to prepare a completely light-stable rhodopsin, we have synthesized an analog, II, of 11-cis retinal in which isomerization at the C11-C12 cis-double bond is blocked by formation of a cyclohexene ring from the C10 to C13-methyl. We used this analog to generate a rhodopsin-like pigment from opsin expressed in COS-1 cells and opsin from rod outer segments (Bhattacharya, S., Ridge, K.D., Knox, B.E., and Khorana, H. G. (1992) J. Biol. Chem. 267, 6763-6769). The pigment (lambda max, 512 nm) formed from opsin and analog II (rhodospin-II) showed ground state properties very similar to those of rhodopsin, but was not entirely stable to light. In the present work, 12 opsin mutants (Ala-117----Phe, Glu-122----Gln(Ala, Asp), Trp-126----Phe(Leu, Ala), Trp-265----Ala(Tyr, Phe), Tyr-268----Phe, and Ala-292----Asp), where the mutations were presumed to be in the retinal binding pocket, were reconstituted with analog II. While all mutants formed rhodopsin-like pigments with II, blue-shifted (12-30 nm) chromophores were obtained with Ala-117----Phe, Glu-122----Gln(Ala), Trp-126----Leu(Ala), and Trp-265----Ala(Tyr, Phe) opsins. The extent of chromophore formation was markedly reduced in the mutants Ala-117----Phe and Trp-126----Ala. Upon illumination, the reconstituted pigments showed varying degrees of light sensitivity; the mutants Trp-126----Phe(Leu) showed light sensitivity similar to wild-type. Continuous illumination of the mutants Glu-122----Asp, Trp-265----Ala, Tyr-268----Phe, and Ala-292----Asp resulted in hydrolysis of the retinyl Schiff base. Markedly reduced light sensitivity was observed with the mutant Trp-265----Tyr, while the mutant Trp-265----Phe was light-insensitive. Consistent with this result, the mutant Trp-265----Phe showed no detectable light-dependent activation of transducin or phosphorylation by rhodopsin kinase.

Light-stable rhodopsin. I. A rhodopsin analog reconstituted with a nonisomerizable 11-cis retinal derivative.

With the aim of preparing a light-stable rhodopsin-like pigment, an analog, II, of 11-cis retinal was synthesized in which isomerization of the C11-C12 cis-double bond is blocked by a cyclohexene ring built around the C10 to C13-methyl. The analog II formed a rhodopsin-like pigment (rhodopsin-II) with opsin expressed in COS-1 cells and with opsin from rod outer segments. The rate of rhodopsin-II formation from II and opsin was approximately 10 times slower than that of rhodopsin from 11-cis retinal and opsin. After solubilization in dodecyl maltoside and immunoaffinity purification, rhodopsin-II displayed an absorbance ratio (A280nm/A512nm) of 1.6, virtually identical with that of rhodopsin. Acid denaturation of rhodopsin-II formed a chromophore with lambda max, 452 nm, characteristic of protonated retinyl Schiff base. The ground state properties of rhodopsin-II were similar to those of rhodopsin in extinction coefficient (41,200 M-1 cm-1) and opsin-shift (2600 cm-1). Rhodopsin-II was stable to hydroxylamine in the dark, while light-dependent bleaching by hydroxylamine was slowed by approximately 2 orders of magnitude relative to rhodopsin. Illumination of rhodopsin-II for 10 s caused approximately 3 nm blue-shift and 3% loss of visible absorbance. Prolonged illumination caused a maximal blue-shift up to approximately 20 nm and approximately 40% loss of visible absorbance. An apparent photochemical steady state was reached after 12 min of illumination. Subsequent acid denaturation indicated that the retinyl Schiff base linkage was intact. A red-shift (approximately 12 nm) in lambda max and a 45% recovery of visible absorbance was observed after returning the 12-min illuminated pigment to darkness. Rhodopsin-II showed marginal light-dependent transducin activation and phosphorylation by rhodopsin kinase.