Functional map of arrestin binding to phosphorylated opsin, with and without agonist

Peterhans, Christian; Lally, Ciara C. M.; Ostermaier, Martin K.; Sommer, Monika; Standfuss, Joerg

doi:10.1038/srep28686

Cited by 28 publications

(31 citation statements)

References 61 publications

(134 reference statements)

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“…This mode of binding was captured in our MD simulations using an isolated C-domain of pre-active p44, and we anticipate that this interaction significantly stabilizes the high-affinity complex. Note that the different membrane anchor orientations for the pre-complex and high-affinity complex, which we predict based on our fluorescence data, is corroborated by a recent alanine scan mutagenesis study of arrestin-1 binding to inactive and active phosphorylated rhodopsin 41 .…”

Section: Discussionsupporting

confidence: 86%

C-edge loops of arrestin function as a membrane anchor

et al. 2017

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G-protein-coupled receptors are membrane proteins that are regulated by a small family of arrestin proteins. During formation of the arrestin–receptor complex, arrestin first interacts with the phosphorylated receptor C terminus in a pre-complex, which activates arrestin for tight receptor binding. Currently, little is known about the structure of the pre-complex and its transition to a high-affinity complex. Here we present molecular dynamics simulations and site-directed fluorescence experiments on arrestin-1 interactions with rhodopsin, showing that loops within the C-edge of arrestin function as a membrane anchor. Activation of arrestin by receptor-attached phosphates is necessary for C-edge engagement of the membrane, and we show that these interactions are distinct in the pre-complex and high-affinity complex in regard to their conformation and orientation. Our results expand current knowledge of C-edge structure and further illuminate the conformational transitions that occur in arrestin along the pathway to tight receptor binding.

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Section: Discussionsupporting

confidence: 86%

C-edge loops of arrestin function as a membrane anchor

et al. 2017

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“…Comprehensive mutagenesis of every residue in the arrestin-1 revealed numerous elements affecting receptor binding, as well as an unexpected fact that there are arrestin-1 residues that differentially affect the binding to phosphorylated opsin that does or does not have bound agonist, all-trans-retinal [ 84 ], supporting the idea that receptor-bound arrestin can be in different “poses” [ 70 ] and conformations [ 61 ]. Mapping of the receptor footprint on arrestin using site-directed spin labeling/EPR [ 58 , 79 ], chimeras between rhodopsin-specific arrestin-1 and more promiscuous arrestin-2 [ 85 ], and site-directed mutagenesis [ 79 ] revealed that receptors engage a fairly large part of the concave sides of the two arrestin domains.…”

Section: Signal Transducersmentioning

confidence: 99%

Molecular Mechanisms of GPCR Signaling: A Structural Perspective

Gurevich

2017

IJMS

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G protein-coupled receptors (GPCRs) are cell surface receptors that respond to a wide variety of stimuli, from light, odorants, hormones, and neurotransmitters to proteins and extracellular calcium. GPCRs represent the largest family of signaling proteins targeted by many clinically used drugs. Recent studies shed light on the conformational changes that accompany GPCR activation and the structural state of the receptor necessary for the interactions with the three classes of proteins that preferentially bind active GPCRs, G proteins, G protein-coupled receptor kinases (GRKs), and arrestins. Importantly, structural and biophysical studies also revealed activation-related conformational changes in these three types of signal transducers. Here, we summarize what is already known and point out questions that still need to be answered. Clear understanding of the structural basis of signaling by GPCRs and their interaction partners would pave the way to designing signaling-biased proteins with scientific and therapeutic potential.

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“…3,44 Experimental swapping of various elements 44 and individual residues 45 between arrestin-1 and nonvisual arrestin-2 identified a limited set of side chains that determine receptor preference. Mutagenesis of every residue in arrestin-1 46,47 coupled with analysis of the crystal structure of the arrestin-1 complex with rhodopsin 48,49 (Fig. 2) revealed several additional residues that play important roles in GPCR binding and/or directly contact the receptor, and therefore might contribute to receptor specificity.…”

Section: Receptor Specificity: Selective Targeting Of Certain Gpcrs?mentioning

confidence: 99%

“…Chimera construction, 38,44,89 site-directed mutagenesis, 45–47,50–52,90 peptide interaction studies, 91 EPR, 21,92 NMR, 93 and X-ray crystallography 48,49,56,94 all suggest that the receptors engage the concave sides of both arrestin domains (Figs. 1 and 2).…”

Section: “Designer Arrestins”: a Roadmap Or A Dream?mentioning

confidence: 99%

Arrestins: Introducing Signaling Bias Into Multifunctional Proteins

Gurevich

Chen

Gurevich

2018

Progress in Molecular Biology and Translational Science

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Arrestins were discovered as proteins that bind active phosphorylated G protein-coupled receptors (GPCRs) and block their interactions with G proteins, i.e., for their role in homologous desensitization of GPCRs. Mammals express only four arrestin subtypes, two of which are largely restricted to the retina. Two nonvisual arrestins are ubiquitous and interact with hundreds of different GPCRs and dozens of other binding partners. Changes of just a few residues on the receptor-binding surface were shown to dramatically affect GPCR preference of inherently promiscuous nonvisual arrestins. Mutations on the cytosol-facing side of arrestins modulate their interactions with individual downstream signaling molecules. Thus, it appears feasible to construct arrestin mutants specifically linking particular GPCRs with signaling pathways of choice or mutants that sever the links between selected GPCRs and unwanted pathways. Signaling-biased “designer arrestins” have the potential to become valuable molecular tools for research and therapy.

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Functional map of arrestin binding to phosphorylated opsin, with and without agonist

Cited by 28 publications

References 61 publications

C-edge loops of arrestin function as a membrane anchor

C-edge loops of arrestin function as a membrane anchor

Molecular Mechanisms of GPCR Signaling: A Structural Perspective

Arrestins: Introducing Signaling Bias Into Multifunctional Proteins

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