G protein-coupled receptor (GPCR) activation mediated by ligand-induced structural reorganization of its helices is poorly understood. To determine the universal elements of this conformational switch, we used evolutionary tracing (ET) to identify residue positions commonly important in diverse GPCRs. When mapped onto the rhodopsin structure, these trace residues cluster into a network of contacts from the retinal binding site to the G protein-coupling loops. Their roles in a generic transduction mechanism were verified by 211 of 239 published mutations that caused functional defects. When grouped according to the nature of the defects, these residues subdivided into three striking sub-clusters: a trigger region, where mutations mostly affect ligand binding, a coupling region near the cytoplasmic interface to the G protein, where mutations affect G protein activation, and a linking core in between where mutations cause constitutive activity and other defects. Differential ET analysis of the opsin family revealed an additional set of opsin-specific residues, several of which form part of the retinal binding pocket, and are known to cause functional defects upon mutation. To test the predictive power of ET, we introduced novel mutations in bovine rhodopsin at a globally important position, Leu-79, and at an opsin-specific position, Trp-175. Both were functionally critical, causing constitutive G protein activation of the mutants and rapid loss of regeneration after photobleaching. These results define in GPCRs a canonical signal transduction mechanism where ligand binding induces conformational changes propagated through adjacent trigger, linking core, and coupling regions.The profusion and diversity of G protein-coupled receptors (GPCRs) 1 give them a central role in health and disease. In humans, over 1000 genes encode these receptors (1), each of which responds to a single or few ligands by activating G proteins, which then modulate enzymes and channels to initiate highly amplified signaling cascades. Such cascades control sight, taste, smell, slow neurotransmission and the responses to most water-soluble hormones and chemokines. In fact, GPCRs are so ubiquitous that, although they are the targets of nearly 50% of current drugs (2), this is still a small fraction of their pharmacological potential (3).Some of the major questions relevant to GPCR pharmacology include the following: What residues are critical for ligand binding and G protein activation? What do different receptor families have in common with regard to their activation mechanism? From a structural perspective, it is known that all GPCRs form a seven transmembrane (TM) ␣-helical bundle, connected by three intracellular and three extracellular loops, with an extracellular N terminus and an intracellular C terminus (4, 5). However, low overall sequence identity of 25% even within class A GPCRs (6 -8) suggests that significant deviations can occur in ligand binding pockets and in interhelical contacts that stabilize or mediate the transition between a...
This report describes the biochemical characterization of a double mutant of rhodopsin (N2C,D282C) in which Cys residues engineered into the protein at positions 2 (in the amino-terminal extracellular domain) and 282 (in the extracellular loop between transmembrane helices 6 and 7) are shown to form a disulfide bond and increase the thermal stability of the unliganded or opsin form of the protein. Wild-type opsin does not survive detergent solubilization and purification at pH 7.5 and 25 degrees C. In contrast, the N2C,D282C mutant opsin survives the purification protocol and loses less than 50% activity after incubation for 20 days under the same conditions. Less than 5% is lost after 20 days at 4 degrees C. While the disulfide bond clearly has a dramatic effect on protein stability, it has a minor impact on the activity of the pigment. The MII lifetime of the mutant (6.6 min) is similar to that of the wild type (7.9 min), and the specific activity of the light-activated mutant for activation of transducin is within 20% of the wild-type activity. Therefore, it seems likely that the disulfide bond does not perturb greatly the structure of the protein. For these reasons, we anticipate that the mutant may be of use in detailed kinetic and mechanistic investigations of the ligand binding reaction and for crystallization trials involving recombinant rhodopsin, especially the unliganded opsin form of the protein.
The Thr94 --> Ile mutation in the second transmembrane segment of rhodopsin has been reported to be associated with a congenital night blindness phenotype in a large Irish pedigree. Previously, two other known rhodopsin mutants that cause congenital night blindness, A292E and G90D, have been shown in vitro to constitutively activate the G protein transducin in the absence of a chromophore. The proposed mechanism of constitutive activation of these two mutants is an electrostatic disruption of the active site salt bridge between Glu113 and Lys296 that contributes to stabilization of the protein in the inactive state. Here, the T94I rhodopsin mutant is characterized and compared to the two other known rhodopsin night blindness mutants. The T94I mutant opsin is shown also to constitutively activate transducin. The T94I mutant pigment (with a bound 11-cis-retinal chromophore), like the other known rhodopsin night blindness mutants, is not active in the dark and has wild-type activity upon exposure to light. Similar to the Gly90 --> Asp substitution, position 94 is close enough to the Schiff base nitrogen that an Asp at this position can functionally substitute for the Glu113 counterion. However, in contrast to the other night blindness mutants, the T94I MII intermediate decays with a half-life that is approximately 8-fold slower than in the wild-type MII intermediate. Thus, the one phenotype shared by all congenital night blindness mutants that is different from the wild-type protein is constitutive activation of the apoprotein.
Mutations in the Rhodopsin (Rho) gene can lead to autosomal dominant retinitis pigmentosa (RP) in humans. Transgenic mouse models with mutations in Rho have been developed to study the disease. However, it is difficult to know the source of the photoreceptor (PR) degeneration in these transgenic models because overexpression of wild type (WT) Rho alone can lead to PR degeneration. Here, we report two chemically mutagenized mouse models carrying point mutations in Rho (Tvrm1 with an Y102H mutation and Tvrm4 with an I307N mutation). Both mutants express normal levels of rhodopsin that localize to the PR outer segments and do not exhibit PR degeneration when raised in ambient mouse room lighting; however, severe PR degeneration is observed after short exposures to bright light. Both mutations also cause a delay in recovery following bleaching. This defect might be due to a slower rate of chromophore binding by the mutant opsins compared with the WT form, and an increased rate of transducin activation by the unbound mutant opsins, which leads to a constitutive activation of the phototransduction cascade as revealed by in vitro biochemical assays. The mutant-free opsins produced by the respective mutant Rho genes appear to be more toxic to PRs, as Tvrm1 and Tvrm4 mutants lacking the 11-cis chromophore degenerate faster than mice expressing WT opsin that also lack the chromophore. Because of their phenotypic similarity to humans with B1 Rho mutations, these mutants will be important tools in examining mechanisms underlying Rho-induced RP and for testing therapeutic strategies.Rhodopsin is a light sensitive G-protein-coupled receptor composed of a membrane-bound opsin, encoded by the rhodopsin gene (Rho), and a covalently bound, light-sensitive chromophore, 11-cis-retinal. Upon light exposure, 11-cis-retinal is isomerized to all-trans-retinal, which induces a conformational change in rhodopsin to yield its active form, metarhodopsin II (R*).2 R* is deactivated via phosphorylation by rhodopsin kinase and binding to arrestin. In parallel, all-trans-retinal is released from R* and recycled through the visual cycle, to form 11-cisretinal, which regenerates rhodopsin in the rod outer segment. The release of chromophore from R* can also lead to high levels of free opsin in the retina. Free opsin can activate the phototransduction cascade, albeit at a lower rate than R*, and can potentially lead to constitutive activation of transduction after it is phosphorylated and forms a complex with arrestin (1, 2), a phenomena associated with photoreceptor degeneration (1).The maintenance of rod photoreceptors is critically dependent on normal levels of rhodopsin. Rod degeneration is observed in Rho Ϫ/Ϫ mice (3-5) and the human disorder retinitis pigmentosa (RP) caused by Rho mutations is characterized by progressive rod degeneration (6). More than 100 point mutations in rhodopsin collectively account for ϳ25% of autosomal dominant RP as well as some forms of autosomal recessive RP (7,8). These observations have spurred the development...
Recent studies on the endoplasmic reticulum stress have shown that the unfolded protein response (UPR) is involved in the pathogenesis of inherited retinal degeneration caused by mutant rhodopsin. However, the main question of whether UPR activation actually triggers retinal degeneration remains to be addressed. Thus, in this study, we created a mouse model for retinal degeneration caused by a persistently activated UPR to assess the physiological and morphological parameters associated with this disease state and to highlight a potential mechanism by which the UPR can promote retinal degeneration. We performed an intraocular injection in C57BL6 mice with a known unfolded protein response (UPR) inducer, tunicamycin (Tn) and examined animals by electroretinography (ERG), spectral domain optical coherence tomography (SD-OCT) and histological analyses. We detected a significant loss of photoreceptor function (over 60%) and retinal structure (35%) 30 days post treatment. Analysis of retinal protein extracts demonstrated a significant upregulation of inflammatory markers including interleukin-1β (IL-1β), IL-6, tumor necrosis factor-α (TNF-α), monocyte chemoattractant protein-1 (MCP-1) and IBA1. Similarly, we detected a strong inflammatory response in mice expressing either Ter349Glu or T17M rhodopsin (RHO). These mutant rhodopsin species induce severe retinal degeneration and T17M rhodopsin elicits UPR activation when expressed in mice. RNA and protein analysis revealed a significant upregulation of pro- and anti-inflammatory markers such as IL-1β, IL-6, p65 nuclear factor kappa B (NF-kB) and MCP-1, as well as activation of F4/80 and IBA1 microglial markers in both the retinas expressing mutant rhodopsins. We then assessed if the Tn-induced inflammatory marker IL-1β was capable of inducing retinal degeneration by injecting C57BL6 mice with a recombinant IL-1β. We observed ~19% reduction in ERG a-wave amplitudes and a 29% loss of photoreceptor cells compared with control retinas, suggesting a potential link between pro-inflammatory cytokines and retinal pathophysiological effects. Our work demonstrates that in the context of an established animal model for ocular disease, the persistent activation of the UPR could be responsible for promoting retinal degeneration via the UPR-induced pro-inflammatory cytokine IL-1β.
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