Abstract
Arrestins quench the signaling of a wide variety of G protein-coupled receptors by virtue of high-affinity binding to phosphorylated activated receptors. The high selectivity of arrestins for this particular functional form of receptor ensures their timely binding and dissociation. In a continuing effort to elucidate the molecular mechanisms responsible for arrestin's selectivity, we used the visual arrestin model to probe the functions of its N-terminal beta-strand I comprising the highly conserved hydrophobic element Val-Ile-Phe (residues 11-13) and the adjacent positively charged Lys(14) and Lys(15). Charge elimination and reversal in positions 14 and 15 dramatically reduce arrestin binding to phosphorylated light-activated rhodopsin (P-Rh*). The same mutations in the context of various constitutively active arrestin mutants (which bind to P-Rh*, dark phosphorylated rhodopsin (P-Rh), and unphosphorylated light-activated rhodopsin (Rh*)) have minimum impact on P-Rh* and Rh* binding and virtually eliminate P-Rh binding. These results suggest that the two lysines "guide" receptor-attached phosphates toward the phosphorylation-sensitive trigger Arg(175) and participate in phosphate binding in the active state of arrestin. The elimination of the hydrophobic side chains of residues 11-13 (triple mutation V11A, I12A, and F13A) moderately enhances arrestin binding to P-Rh and Rh*. The effects of triple mutation V11A, I12A, and F13A in the context of phosphorylation-independent mutants suggest that residues 11-13 play a dual role. They stabilize arrestin's basal conformation via interaction with hydrophobic elements in arrestin's C-tail and alpha-helix I as well as its active state by interactions with alternative partners. In the context of the recently solved crystal structure of arrestin's basal state, these findings allow us to propose a model of initial phosphate-driven structural rearrangements in arrestin that ultimately result in its transition into the active receptor-binding state.
Highlights
Arrestins quench the signaling of a wide variety of G protein-coupled receptors by virtue of high-affinity binding to phosphorylated activated receptors
These results suggest that the two lysines “guide” receptor-attached phosphates toward the phosphorylation-sensitive trigger Arg[175] and participate in phosphate binding in the active state of arrestin
Based on a crystal structure of the basal state of visual arrestin (8) and on structure-based targeted mutagenesis (9), we have recently proposed a molecular mechanism for the functioning of arrestin’s main phosphate sensor (8 –10)
Summary
Rh*, light-activated unphosphorylated rhodopsin; P-Rh*, light-activated phosphorylated rhodopsin; P-Rh, dark phosphorylated rhodopsin; 3A, triple mutation F375A, V376A, F377A; N3A, triple mutation V11A, I12A, F13A; h3A, triple mutation L103A, L107A, L111A. Phosphate-binding Elements in Arrestin binding state (8, 9) This mechanism adequately explains how stereochemically heterogeneous phosphoreceptor molecules with different numbers of phosphates attached at various sites induce activation of arrestin in the same fashion. We use a visual arrestin-rhodopsin model to further explore the mechanism of arrestin’s strict preference for phosphoreceptors and describe a previously unappreciated phosphate-binding element in the N terminus of arrestin This two-residue element (Lys[14], Lys15) apparently plays a key role in the process of arrestin activation, as well as in phosphate interaction in the active receptorbinding state of arrestin (i.e. after the polar core is rearranged). They create an ingenious failsafe mechanism ensuring arrestin’s selectivity for phosphorylated receptors
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