Why Study GPCR Arrestin Recruitment?

GPCR β-Arrestin Signaling

Arrestins are ubiquitously expressed and function in the activation of GPCRs, desensitization of most 7-transmembrane receptors (7-TMs), and regulation of other signaling molecules such as protein kinases.

There are currently four known arrestins:

Visual and cone arrestins play a major role in photoreceptor cell regulation
β-arrestin1 and 2 interact with the majority of commonly targeted 7-TMs

For GPCRs, ligand-induced β-arrestin (1 or 2) recruitment activates signaling cascades independently of G-protein signaling to provide a stoichiometric, non-amplified signal. β-arrestin recruitment assays offer an easy to use alternative to second messenger cAMP and calcium G-protein dependent pathways to enable enhanced profiles of compound pharmacology – a universal assay that expands opportunities for development of novel drugs.

Explore Eurofins DiscoverX β-Arrestin Products and Services

Benefits of a Non-amplified System

The β-arrestin signaling pathway is an ideal system for discovering antagonists, studying GPCR deorphanization, and dissecting ligand pharmacology differences.

cAMP Second Messenger G-protein Dependent Signaling Pathway

An amplified system that can lead to rapid saturation using low levels of GPCR activating ligands. This is a more sensitive system based on partial receptor occupancy giving a full signal due to the amplified signaling event (receptor reserve phenomena) after ligand activation. Agonist can easily be detected since it does not take much agonist to obtain a full signal, but differentiating partial from full agonists can be difficult, and cAMP assays tend to have lower sensitivities to antagonists than do arrestin assays.

β-Arrestin Signaling Pathway

A stoichiometric (1 receptor: 1 ligand), non-amplified system that requires full ligand occupancy of the ligand bound to the receptor to give a full signal. This leads to a lower sensitivity to agonists, but improved ability to detect differences of efficacy between agonists, and superior sensitivity for antagonists (compared to second messenger systems). This makes β-arrestin an ideal system for fine tuning GPCR biology when screening antagonists as well as for deorphanizing GPCRs and distinguishing between full, super, and partial agonists.

Multiple Applications of β-Arrestin Assays

Perform multiple pathway analysis in the same cell line
Uncover unique pharmacology
Correctly rank order ligands
Deorphanize GPCRs
Evaluate difficult GPCRs
Compare ligand responses in different species receptors (orthologs)
Study mutant or isoform differences
Investigate tissue specific variations using different cell types
Enable ligand bias studies

β-Arrestin Resources

Learn how DiscoverX can help you research β-arrestin applications and more through the use of cell-based assays. DiscoverX provides a complete set of tools to analyze β-arrestin biology. The PathHunter® β-arrestin assays and reagents offer a powerful and universal screening and profiling platform that can be used for virtually any G_i-, G_s, or G_q-coupled receptor.
Read application notes:
Discover other β-arrestin applications through customer publications. These publications cover many class A and B GPCRs where researchers used small molecule and/or biologic ligands. The publications include basic research experiments and drug discovery studies from assay development through screening and preclinical programs.
Publications used in this article:
- Lundstrom, K., “New winds in GPCR-based drug discovery.” Future Medicinal Chemistry, 2016; 8(6): 605-608.
- Bassoni, D., et. al., “Measurements of β-arrestin recruitment to activated seven transmembrane receptors using enzyme complementation.” Methods Mol. Biol. 2012; 897: 181-203.

Author

Dana Haley-Vicente, PhD