Arrestin-Rhodopsin Binding Stoichiometry in Isolated Rod Outer Segment Membranes Depends on the Percentage of Activated Receptors

107

174

Arrestin-1 (visual arrestin) binds to light-activated phosphorylated rhodopsin (P-Rh*) to terminate G-protein signaling. To map conformational changes upon binding to the receptor, pairs of spin labels were introduced in arrestin-1 and double electron-electron resonance was used to monitor interspin distance changes upon P-Rh* binding. The results indicate that the relative position of the N and C domains remains largely unchanged, contrary to expectations of a "clam-shell" model. A loop implicated in P-Rh* binding that connects β-strands V and VI (the "finger loop," residues 67-79) moves toward the expected location of P-Rh* in the complex, but does not assume a fully extended conformation. A striking and unexpected movement of a loop containing residue 139 away from the adjacent finger loop is observed, which appears to facilitate P-Rh* binding. This change is accompanied by smaller movements of distal loops containing residues 157 and 344 at the tips of the N and C domains, which correspond to "plastic" regions of arrestin-1 that have distinct conformations in monomers of the crystal tetramer. Remarkably, the loops containing residues 139, 157, and 344 appear to have high flexibility in both free arrestin-1 and the P-Rh*complex.A rrestin was first discovered in the visual system as a protein that blocks ("arrests") the signaling of the prototypical G protein-coupled receptor (GPCR) rhodopsin (Rh) via specific binding to the phosphorylated activated form P-Rh* (1). Mammals express four arrestin subtypes: Arrestin-1 and -4 are specific for the visual system, whereas arrestin-2 and -3 are ubiquitous (2). [We use systematic names of arrestins: arrestin-1 (historic names S-antigen, 48-kDa protein, or visual or rod arrestin), arrestin-2 (β-arrestin or β-arrestin1), arrestin-3 (β-arrestin2 or hTHY-ARRX), and arrestin-4 (cone or X-arrestin).] The discovery of nonvisual arrestins (3) showed that phosphorylation followed by arrestin binding is a common mechanism of GPCR regulation. Crystal structures of all four arrestin subtypes in their basal state revealed similar topology: two cup-like domains linked by an interdomain hinge ( Fig. 1) (4-7). Arrestin-1 was proposed to undergo a conformational rearrangement during the P-Rh* interaction that results in the release of the C-terminal sequence (C tail) (8, 9) but does not involve major secondary structure changes (8, 10). Recent site-directed spin labeling (SDSL) studies identified specific parts of arrestin-1 engaged by different functional forms of rhodopsin and provided direct evidence of binding-induced conformational changes (11,12). A conformational change in the so-called finger loop (Fig. 1) implicated in P-Rh* recognition was also observed using NMR and fluorescence quenching (13,14). Arrestin-1 shows a remarkable selectivity for P-Rh*. Observed binding to inactive phosphorylated (P-Rh) or active unphosphorylated rhodopsin (Rh*) is usually less than 10% of the binding to P-Rh*, whereas its binding to inactive unphosphorylated rhodopsin (Rh) is barely detectable ...

supporting

confidence: 65%

mentioning

confidence: 99%

Conformation of receptor-bound visual arrestin

Kim

Vishnivetskiy²,

Eps

et al. 2012

107

174

“…Principally, the reorganized interface could thus provide a secondary binding site for the accommodation of a GPCR dimer. Indeed it has been suggested that the arrestin C loop binds a second rhodopsin molecule in disc membranes containing high levels of activated rhodopsin (18,42). Site-directed spin-labeling studies, on the other hand, revealed a high flexibility of this arrestin region upon binding to both highly activated P-ROS* and nanodiscs containing only monomeric P-rhodopsin* (28).…”

Section: Resultsmentioning

confidence: 99%

Functional map of arrestin-1 at single amino acid resolution

Ostermaier

Peterhans

Jaussi

et al. 2014

Arrestins function as adapter proteins that mediate G proteincoupled receptor (GPCR) desensitization, internalization, and additional rounds of signaling. Here we have compared binding of the GPCR rhodopsin to 403 mutants of arrestin-1 covering its complete sequence. This comprehensive and unbiased mutagenesis approach provides a functional dimension to the crystal structures of inactive, preactivated p44 and phosphopeptide-bound arrestins and will guide our understanding of arrestin-GPCR complexes. The presented functional map quantitatively connects critical interactions in the polar core and along the C tail of arrestin. A series of amino acids (Phe375, Phe377, Phe380, and Arg382) anchor the C tail in a position that blocks binding of the receptor. Interaction of phosphates in the rhodopsin C terminus with Arg29 controls a C-tail exchange mechanism in which the C tail of arrestin is released and exposes several charged amino acids (Lys14, Lys15, Arg18, Lys20, Lys110, and Lys300) for binding of the phosphorylated receptor C terminus. In addition to this arrestin phosphosensor, our data reveal several patches of amino acids in the finger (Gln69 and Asp73-Met75) and the lariat loops (L249-S252 and Y254) that can act as direct binding interfaces. A stretch of amino acids at the edge of the C domain (Trp194-Ser199, Gly337-Gly340, Thr343, and Thr345) could act as membrane anchor, binding interface for a second rhodopsin, or rearrange closer to the central loops upon complex formation. We discuss these interfaces in the context of experimentally guided docking between the crystal structures of arrestin and light-activated rhodopsin.visual system | scanning mutagenesis | membrane receptor | cell signaling | protein engineering T he human genome encodes more than 800 G protein-coupled receptors (GPCRs), which mediate signaling between cells and provide an important link to our environment as the principal receptors for taste, smell, and vision. The visual system with its photoreceptor rhodopsin is an excellent system to understand GPCR signaling, as detailed information exists on the structures and dynamic interactions of the protein constituents (1). G protein-mediated signaling by light-activated rhodopsin is terminated by a process that begins with the phosphorylation of rhodopsin's C terminus by the rhodopsin kinase GRK1. The phosphorylated, light-activated rhodopsin binds then to arrestin-1, which stops signaling by occluding the G protein-binding site. Further cloning efforts yielded two ubiquitously expressed nonvisual arrestins (arrestin-2 and arrestin-3 or β-arrestin-1 and β-arrestin-2) and the cone-specific arrestin-4. It seems clear today that most GPCRs share a common mechanism of signal termination involving receptor phosphorylation and the binding of arrestins. Arrestin-bound receptors may be internalized and degraded, internalized and recycled, and/or initiate G proteinindependent signaling (2).In recent years there has been tremendous progress in the structure determination of active GPCR states includ...

“…Monomeric rhodopsin was shown to be necessary and sufficient for high-affinity arrestin-1 binding (26,45). However, recent reports suggest that two types of arrestin-1-rhodopsin complexes are formed upon activation of a high fraction of rhodopsin in native disk membranes, with 1:1 and 1:2 arrestin: rhodopsin stoichiometries (46,47). In the latter, arrestin-1 apparently binds only one rhodopsin with high affinity, stabilizing its Meta II state (46) and trapping all-transretinal (47), whereas the other molecule is engaged with much lower affinity by distinct arrestin-1 elements localized in the C-domain (47).…”

Section: Hmentioning

confidence: 99%

“…However, recent reports suggest that two types of arrestin-1-rhodopsin complexes are formed upon activation of a high fraction of rhodopsin in native disk membranes, with 1:1 and 1:2 arrestin: rhodopsin stoichiometries (46,47). In the latter, arrestin-1 apparently binds only one rhodopsin with high affinity, stabilizing its Meta II state (46) and trapping all-transretinal (47), whereas the other molecule is engaged with much lower affinity by distinct arrestin-1 elements localized in the C-domain (47). All forms of rhodopsin used here were solubilized by a large excess of bicelles and most of the perturbations were observed to be in the N domain of arrestin-1 and in the C terminus that is anchored to this part of the molecule (Figs.…”

Section: Hmentioning

confidence: 99%

Involvement of distinct arrestin-1 elements in binding to different functional forms of rhodopsin

Zhuang

Chen

Cho³

et al. 2012

119

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 (PRh*). 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 PRh* 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.G protein-coupled receptors | nuclear magnetic resonance | TROSY | bicelles