A single phenylalanine residue in ß-arrestin2 critically regulates its binding to G protein-coupled receptors.

Arrestins and their yeast homologs, arrestin-related trafficking adaptors (ARTs), share a stretch of 29 amino acids called the ART motif. However, the functionality of that motif is unknown. We now report that deleting this motif prevents agonist-induced ubiquitination of ß-arrestin2 (ß-arr2) and blocks its association with activated G protein-coupled receptors (GPCRs). Within the ART motif, we have identified a conserved phenylalanine residue, Phe116, that is critical for the formation of ß-arr2-GPCR complexes. ß-arr2 Phe116Ala mutant has negligible effect on blunting ß2-adrenergic receptor-induced cAMP generation unlike ß-arr2, which promotes rapid desensitization. Furthermore, available structures for inactive and inositol hexakisphosphate 6-activated forms of bovine ß-arr2 revealed that Phe116 is ensconced in a hydrophobic pocket, whereas the adjacent Phe117 and Phe118 residues are not. Mutagenesis of Phe117 and Phe118, but not Phe116, preserves GPCR interaction of ß-arr2. Surprisingly, Phe116 is dispensable for the association of ß-arr2 with its non-GPCR partners. ß-arr2 Phe116Ala mutant presents a significantly reduced protein half-life compared with ß-arr2 and undergoes constitutive Lys-48-linked polyubiquitination, which tags proteins for proteasomal degradation. We also found that Phe116 is critical for agonist-dependent ß-arr2 ubiquitination with Lys-63-polyubiquitin linkages that are known mediators of protein scaffolding and signal transduction. Finally, we have shown that ß-arr2 Phe116Ala interaction with activated ß2-adrenergic receptor can be rescued with an in-frame fusion of ubiquitin. Taken together, we conclude that Phe116 preserves structural stability of ß-arr2, regulates the formation of ß-arr2-GPCR complexes that inhibit G protein signaling, and promotes subsequent ubiquitin-dependent ß-arr2 localization and trafficking.

Ubiquitin-Related Roles of ß-Arrestins in Endocytic Trafficking and Signal Transduction.

The non-visual arrestins, ß-arrestin1, and ß-arrestin2 were originally identified as proteins that bind to seven-transmembrane receptors (7TMRs, also called G protein-coupled receptors, GPCRs) and block heterotrimeric G protein activation, thus leading to desensitization of transmembrane signaling. However, as subsequent discoveries have continually demonstrated, their functionality is not constrained to desensitization. They are now recognized for their critical roles in mediating intracellular trafficking of 7TMRs, growth factor receptors, ion transporters, ion channels, nuclear receptors, and non-receptor proteins. Additionally, they function as crucial mediators of ubiquitination of 7TMRs as well as other receptors and non-receptor proteins. Recently, emerging studies suggest that a class of proteins with predicted structural features of ß-arrestins regulate substrate ubiquitination in yeast and higher mammals, lending support to the idea that the adaptor role of ß-arrestins in protein ubiquitination is evolutionarily conserved. ß-arrestins also function as scaffolds for kinases and transduce signals from 7TMRs through pathways that do not require G protein activation. Remarkably, the endocytic and scaffolding functions of ß-arrestin are intertwined with its ubiquitination status; the dynamic and site specific ubiquitination on ß-arrestin plays a critical role in stabilizing ß-arrestin-7TMR association and the formation of signalosomes. This review summarizes the current findings on ubiquitin-dependent regulation of 7TMRs as well as ß-arrestins and the potential role of reversible ubiquitination as a "biological switch" in signal transduction. J. Cell. Physiol. 231: 2071-2080, 2016. © 2016 Wiley Periodicals, Inc.