Functional Selectivity of a Biased Cannabinoid-1 Receptor (CB1R) Antagonist.
Ziyi LiuMalliga R IyerGrzegorz GodlewskiTony JourdanJie LiuNathan J CoffeyCharles N ZawatskyHenry L PuhlJürgen WessJaroslawna MeisterJeih-San LiowRobert B InnisSergio A HassanYong-Sok LeeGeorge KunosResat CinarPublished in: ACS pharmacology & translational science (2021)
Seven-transmembrane receptors signal via G-protein- and β-arrestin-dependent pathways. We describe a peripheral CB1R antagonist (MRI-1891) highly biased toward inhibiting CB1R-induced β-arrestin-2 (βArr2) recruitment over G-protein activation. In obese wild-type and βArr2-knockout (KO) mice, MRI-1891 treatment reduces food intake and body weight without eliciting anxiety even at a high dose causing partial brain CB1R occupancy. By contrast, the unbiased global CB1R antagonist rimonabant elicits anxiety in both strains, indicating no βArr2 involvement. Interestingly, obesity-induced muscle insulin resistance is improved by MRI-1891 in wild-type but not in βArr2-KO mice. In C2C12 myoblasts, CB1R activation suppresses insulin-induced akt-2 phosphorylation, preventable by MRI-1891, βArr2 knockdown or overexpression of CB1R-interacting protein. MRI-1891, but not rimonabant, interacts with nonpolar residues on the N-terminal loop, including F108, and on transmembrane helix-1, including S123, a combination that facilitates βArr2 bias. Thus, CB1R promotes muscle insulin resistance via βArr2 signaling, selectively mitigated by a biased CB1R antagonist at reduced risk of central nervous system (CNS) side effects.
Keyphrases
- wild type
- insulin resistance
- contrast enhanced
- magnetic resonance imaging
- high fat diet induced
- type diabetes
- metabolic syndrome
- high dose
- adipose tissue
- diffusion weighted imaging
- high glucose
- signaling pathway
- body weight
- diabetic rats
- cell proliferation
- high fat diet
- magnetic resonance
- emergency department
- escherichia coli
- polycystic ovary syndrome
- transcription factor
- sleep quality
- stem cell transplantation
- protein kinase
- brain injury
- weight gain
- blood brain barrier
- combination therapy
- structural basis
- functional connectivity