Functional Role of Arrestin-1 Residues Interacting With Unphosphorylated Rhodopsin Elements (original) (raw)
Related papers
Journal of Biological Chemistry, 1998
Arrestin plays an important role in quenching phototransduction via its ability to bind to the phosphorylated light-activated form of the visual receptor rhodopsin (P-Rh*). Remarkable selectivity of visual arrestin toward this functional form is determined by an elegant sequential multisite binding mechanism. Previous structure-function studies have suggested that the COOH-terminal region of arrestin (residues 356-404) is not directly involved in rhodopsin interaction, but instead plays a regulatory role. This region supports basal arrestin conformation and ensures arrestin's transition into a high affinity rhodopsin-binding state upon an encounter with P-Rh*. Overall, our results corroborate this hypothesis and identify three functional subregions (residues 361-368, 369-378, and 379-404) and individual amino acids involved in the control of arrestin stability and binding selectivity. Two of the most potent mutants, arrestin(1-378) and arrestin(F375A,V376A,F377A) belong to a novel class of constitutively active arrestins with high affinity for P-Rh*, dark P-Rh, and Rh* (but not dark Rh), in contrast to earlier constructed mutants arrestin(R175E) and arrestin(⌬2-16) with high affinity for light-activated forms only. The implications of these findings for the mechanism of arrestin-rhodopsin interaction are discussed in light of the recently determined crystal structure of arrestin.
Involvement of distinct arrestin-1 elements in binding to different functional forms of rhodopsin
Proceedings of the National Academy of Sciences, 2013
Solution NMR spectroscopy of labeled arrestin-1 was used to explore its interactions with dark-state phosphorylated rhodopsin (P-Rh), phosphorylated opsin (P-opsin), unphosphorylated light-activated rhodopsin (Rh*), and phosphorylated light-activated rhodopsin (P-Rh*). Distinct sets of arrestin-1 elements were seen to be engaged by Rh* and inactive P-Rh, which induced conformational changes that differed from those triggered by binding of P-Rh*. Although arrestin-1 affinity for Rh* was seen to be low (K D > 150 μM), its affinity for P-Rh (K D ∼80 μM) was comparable to the concentration of active monomeric arrestin-1 in the outer segment, suggesting that P-Rh generated by high-gain phosphorylation is occupied by arrestin-1 under physiological conditions and will not signal upon photo-activation. Arrestin-1 was seen to bind P-Rh* and P-opsin with fairly high affinity (K D of ∼50 and 800 nM, respectively), implying that arrestin-1 dissociation is triggered only upon P-opsin regeneration with 11-cis-retinal, precluding noise generated by opsin activity. Based on their observed affinity for arrestin-1, P-opsin and inactive P-Rh very likely affect the physiological monomer-dimer-tetramer equilibrium of arrestin-1, and should therefore be taken into account when modeling photoreceptor function. The data also suggested that complex formation with either P-Rh* or P-opsin results in a global transition in the conformation of arrestin-1, possibly to a dynamic molten globule-like structure. We hypothesize that this transition contributes to the mechanism that triggers preferential interactions of several signaling proteins with receptor-activated arrestins.
Molecular pharmacology, 1997
Arrestin plays an important role in quenching phototransduction via its ability to interact specifically with the phosphorylated light-activated form of the visual receptor rhodopsin (P-Rh*). Previous studies have demonstrated that Arg175 in bovine arrestin is directly involved in the phosphorylation-dependent binding of arrestin to rhodopsin and seems to function as a phosphorylation-sensitive trigger. In this study, we further probed the molecular mechanism of phosphorylation recognition by substituting 19 different amino acids for Arg175. We also assessed the effects of mutagenesis of several other highly conserved residues within the phosphorylation-recognition region (Val170, Leu172, Leu173, Ile174, Val177, and Gln178). The binding of all of these mutants to P-Rh*, light-activated rhodopsin, and truncated rhodopsin, which lacks the carboxyl-terminal phosphorylation sites, was then characterized. Overall, our results suggest that arrestin interaction with the phosphorylated carb...
Molecular vision, 2006
The purpose of our study was to determine whether arrestin residues previously predicted by computational modeling to interact with an aspartic acid substituted rhodopsin tail are actually involved in interactions with phospho-residues on the rhodopsin cytoplasmic tail. We generated arrestin mutants with altered charges at predicted positions. These mutants were then tested for the ability to inhibit rhodopsin using both direct binding assays, as well as functional assays involving transducin inhibition assays. Our results demonstrate that the computer-predicted residues are indeed involved in both the ability of the low-affinity state of arrestin to bind to rhodopsin as well as the ability of arrestin to be induced into a higher-affinity state in a phospho-residue-dependent manner. Our results also suggest that positions K14, K15, R29, H301, and K300 on arrestin interact with the phosphorylated carboxyl tail of rhodopsin and that this translates to the efficient activation of arres...
N-terminal and C-terminal Domains of Arrestin Both Contribute in Binding to Rhodopsin†
Photochemistry and Photobiology, 2007
Visual arrestin terminates the signal amplification cascade in photoreceptor cells by blocking the interaction of light activated phosphorylated rhodopsin with the G-protein transducin. Although crystal structures of arrestin and rhodopsin are available, it is still unknown how the complex of the two proteins is formed. To investigate the interaction sites of arrestin with rhodopsin various surface regions of recombinant arrestin were sterically blocked by different numbers of fluorophores (Alexa 633). The binding was recorded by time-resolved light scattering. To accomplish site-specific shielding of protein regions, in a first step all three wild-type cysteines were replaced by alanines. Nevertheless, regarding the magnitude and specificity of rhodopsin binding, the protein is still fully active. In a second step, new cysteines were introduced at selected sites to allow covalent binding of fluorophores. Upon attachment of Alexa 633 to the recombinant cysteines we observed that these bulky labels residing in the concave area of either the Nor the C-terminal domain do not perturb the activity of arrestin. By simultaneously modifying both domains with one Alexa 633 the binding capacity was reduced. The presence of two Alexa 633 molecules in each domain prevented binding of rhodopsin to arrestin. This observation indicates that both concave sites participate in binding.
The Role of Arrestin-1 Middle Loop in Rhodopsin Binding
International Journal of Molecular Sciences
Arrestins preferentially bind active phosphorylated G protein-coupled receptors (GPCRs). The middle loop, highly conserved in all arrestin subtypes, is localized in the central crest on the GPCR-binding side. Upon receptor binding, it directly interacts with bound GPCR and demonstrates the largest movement of any arrestin element in the structures of the complexes. Comprehensive mutagenesis of the middle loop of rhodopsin-specific arrestin-1 suggests that it primarily serves as a suppressor of binding to non-preferred forms of the receptor. Several mutations in the middle loop increase the binding to unphosphorylated light-activated rhodopsin severalfold, which makes them candidates for improving enhanced phosphorylation-independent arrestins. The data also suggest that enhanced forms of arrestin do not bind GPCRs exactly like the wild-type protein. Thus, the structures of the arrestin-receptor complexes, in all of which different enhanced arrestin mutants and reengineered receptors...
Frontiers in Molecular Neuroscience
We determined the effects of different expression levels of arrestin-1-3A mutant with enhanced binding to light-activated rhodopsin that is independent of phosphorylation. To this end, transgenic mice that express mutant rhodopsin with zero, one, or two phosphorylation sites, instead of six in the WT mouse rhodopsin, and normal complement of WT arrestin-1, were bred with mice expressing enhanced phosphorylation-independent arrestin-1-3A mutant. The resulting lines were characterized by retinal histology (thickness of the outer nuclear layer, reflecting the number of rod photoreceptors, and the length of the outer segments, which reflects rod health), as well as single-and double-flash ERG to determine the functionality of rods and the rate of photoresponse recovery. The effect of co-expression of enhanced arrestin-1-3A mutant with WT arrestin-1 in these lines depended on its level: higher (240% of WT) expression reduced the thickness of ONL and the length of OS, whereas lower (50% of WT) expression was harmless in the retinas expressing rhodopsin with zero or one phosphorylation site, and improved photoreceptor morphology in animals expressing rhodopsin with two phosphorylation sites. Neither expression level increased the amplitude of the a-and b-wave of the photoresponse in any of the lines. However, high expression of enhanced arrestin-1-3A mutant facilitated photoresponse recovery 2-3-fold, whereas lower level was ineffective. Thus, in the presence of normal complement of WT arrestin-1 only supra-physiological expression of enhanced mutant is sufficient to compensate for the defects of rhodopsin phosphorylation.
Regulation of Arrestin Binding by Rhodopsin Phosphorylation Level
Journal of Biological Chemistry, 2007
Arrestins ensure the timely termination of receptor signaling. The role of rhodopsin phosphorylation in visual arrestin binding was established more than 20 years ago, but the effects of the number of receptor-attached phosphates on this interaction remain controversial. Here we use purified rhodopsin fractions with carefully quantified content of individual phosphorylated rhodopsin species to elucidate the impact of phosphorylation level on arrestin interaction with three biologically relevant functional forms of rhodopsin: light-activated and dark phosphorhodopsin and phospho-opsin. We found that a single receptor-attached phosphate does not facilitate arrestin binding, two are necessary to induce high affinity interaction, and three phosphates fully activate arrestin. Higher phosphorylation levels do not increase the stability of arrestin complex with light-activated rhodopsin but enhance its binding to the dark phosphorhodopsin and phospho-opsin. The complex of arrestin with hyperphosphorylated light-activated rhodopsin is less sensitive to high salt and appears to release retinal faster. These data suggest that arrestin likely quenches rhodopsin signaling after the third phosphate is added by rhodopsin kinase. The complex of arrestin with heavily phosphorylated rhodopsin, which appears to form in certain disease states, has distinct characteristics that may contribute to the phenotype of these visual disorders.
How Does Arrestin Respond to the Phosphorylated State of Rhodopsin?
Journal of Biological Chemistry, 1999
Here we present structure-function data, which in conjunction with the refined crystal structure of arrestin (Hirsch, J. A., Schubert, C., Gurevich, V. V., and Sigler, P. B. (1999) Cell, in press), support a model for the conversion of a basal or "inactive" conformation of free arrestin to one that can bind to and inhibit the light activated receptor. The trigger for this transition is an interaction of the phosphorylated COOH-terminal segment of the receptor with arrestin that disrupts intramolecular interactions, including a hydrogen-bonded network of buried, charged side chains, referred to as the "polar core." This disruption permits structural adjustments that allow arrestin to bind to the receptor. Our mutational survey identifies residues in arrestin (Arg 175 , Asp 30 , Asp 296 , Asp 303 , Arg 382 ), which when altered bypass the need for the interaction with the receptor's phosphopeptide, enabling arrestin to bind to activated, nonphosphorylated rhodopsin (Rh*). These mutational changes disrupt interactions and substructures which the crystallographic model and previous biochemical studies have shown are responsible for maintaining the inactive state. The molecular basis for these disruptions was confirmed by successfully introducing structure-based second site substitutions that restored the critical interactions. The nearly absolute conservation of the mutagenically sensitive residues throughout the arrestin family suggests that this mechanism is likely to be applicable to arrestin-mediated desensitization of most G-protein-coupled receptors.
Helix Formation in Arrestin Accompanies Recognition of Photoactivated Rhodopsin
Biochemistry, 2009
Binding of arrestin to photoactivated phosphorylated rhodopsin terminates the amplification of visual signals in photoreceptor cells. Currently, there is no crystal structure of a rhodopsin-arrestin complex available, although structures of unbound rhodopsin and arrestin have been determined. High-affinity receptor binding is dependent on distinct arrestin sites responsible for recognition of rhodopsin activation and phosphorylation. The loop connecting β-strands V and VI in rod arrestin has been implicated in the recognition of active rhodopsin. We report the structure of receptor-bound arrestin peptide Arr(67-77) mimicking this loop based on solution NMR data. The peptide binds photoactivated rhodopsin in the unphosphorylated and phosphorylated form with similar affinities and stabilizes the metarhodopsin II photointermediate. A largely R-helical conformation of the receptor-bound peptide is observed. † This work was supported by grants from the Deutsche Forschungsgemeinschaft (DFG) to B.W.K. (Ko 2143/3), A.P. (Pu 186/3), and O.P. E. (Er 294/1). ‡ The atomic coordinates, chemical shift assignments, and NOE-based structural restraints of Arr(67-77) in the Rh*-bound state (accession number 20079) have been deposited in the Biological Magnetic Resonance Data Bank and the Small Molecule Structure Deposition system.