The glucagon-like peptide-1 receptor (GLP1R) is a class B G protein-coupled receptor (GPCR) involved in metabolism. Presently, its visualization is limited to genetic manipulation, antibody detection or the use of probes that stimulate receptor activation. Herein, we present LUXendin645, a far-red fluorescent GLP1R antagonistic peptide label. LUXendin645 produces intense and specific membrane labeling throughout live and fixed tissue. GLP1R signaling can additionally be evoked when the receptor is allosterically modulated in the presence of LUXendin645. Using LUXendin645 and LUXendin651, we describe islet, brain and hESC-derived β-like cell GLP1R expression patterns, reveal higher-order GLP1R organization including membrane nanodomains, and track single receptor subpopulations. We furthermore show that the LUXendin backbone can be optimized for intravital two-photon imaging by installing a red fluorophore. Thus, our super-resolution compatible labeling probes allow visualization of endogenous GLP1R, and provide insight into class B GPCR distribution and dynamics both in vitro and in vivo.
Background and Purpose
Amino acid substitutions at the N‐termini of glucagon‐like peptide‐1 (GLP‐1) receptor agonist peptides result in distinct patterns of intracellular signalling, sub‐cellular trafficking and efficacy in vivo. Here, we to determine whether sequence differences at the ligand C‐termini of clinically approved GLP‐1 receptor agonists exendin‐4 and lixisenatide lead to similar phenomena.
Experimental Approach
Exendin‐4, lixisenatide and N‐terminally substituted analogues with biased signalling characteristics were compared across a range of in vitro trafficking and signalling assays in different cell types. Fluorescent ligands and new time‐resolved FRET approaches were developed to study agonist behaviours at the cellular and sub‐cellular level. Anti‐hyperglycaemic and anorectic effects of each parent ligand and their biased derivatives were assessed in mice.
Key Results
Lixisenatide and exendin‐4 showed equal binding affinity, but lixisenatide was fivefold less potent for cAMP signalling. Both peptides induced extensive GLP‐1 receptor clustering in the plasma membrane and were rapidly endocytosed, but the GLP‐1 receptor recycled more slowly to the cell surface after lixisenatide treatment. These combined deficits resulted in reduced maximal sustained insulin secretion and reduced anti‐hyperglycaemic and anorectic effects in mice with lixisenatide. N‐terminal substitution of His1 by Phe1 to both ligands had favourable effects on their pharmacology, resulting in improved insulin release and lowering of blood glucose.
Conclusion and Implications
Changes to the C‐terminus of exendin‐4 affect signalling potency and GLP‐1 receptor trafficking via mechanisms unrelated to GLP‐1 receptor occupancy. These differences were associated with changes in their ability to control blood glucose and therefore may be therapeutically relevant.
AbstractObjectiveTo determine how pharmacokinetically advantageous acylation impacts on glucagon-like peptide-1 receptor (GLP-1R) signal bias, trafficking, anti-hyperglycaemic efficacy and appetite suppression.MethodsIn vitro signalling responses were measured using biochemical and biosensor assays. GLP-1 receptor trafficking was determined by confocal microscopy and diffusion-enhanced resonance energy transfer. Pharmacokinetics, glucoregulatory effects and appetite suppression were measured in acute, sub-chronic and chronic settings in mice.ResultsA C-terminally acylated ligand, exendin-phe1-C16, was identified with undetectable β-arrestin recruitment and GLP-1R internalisation. Depending on the cellular system used, this molecule was up to 1000-fold less potent than the comparator exendin-asp-3-C16 for cyclic AMP signalling, yet was considerably more effective in vivo, particularly for glucose regulation.ConclusionsC-terminal acylation of biased GLP-1R agonists increases their degree of signal bias in favour of cAMP production and improves their therapeutic potential.
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