Molecular Approximation between a Residue in the Amino-terminal Region of Calcitonin and the Third Extracellular Loop of the Class B G Protein-coupled Calcitonin Receptor

Self Cite

The glucagon-like peptide 1 (GLP1) receptor is a member of Family B G protein-coupled receptors and represents an important drug target for type 2 diabetes. Despite recent solution of the structure of the amino-terminal domain of this receptor and that of several close family members, understanding of the molecular basis of natural ligand GLP1 binding to its intact receptor remains limited. The goal of this study was to explore spatial approximations between specific receptor residues within the carboxyl terminus of GLP1 and its receptor as normally docked. Therefore, we developed and characterized two high affinity, full-agonist photolabile GLP1 probes having sites for covalent attachment in positions 24 and 35. Both probes labeled the receptor specifically and saturably. Subsequent peptide mapping using chemical and proteinase cleavages of purified wild-type and mutant GLP1 receptor identified that the Arg 131 -Lys 136 segment at the juxtamembrane region of the receptor amino terminus contained the site of labeling for the position 24 probe, and the specific receptor residue labeled by this probe was identified as Glu 133 by radiochemical sequencing. Similarly, nearby residue Glu 125 within the same region of the receptor amino-terminal domain was identified as the site of labeling by the position 35 probe. These data represent the first direct demonstration of spatial approximation between GLP1 and its intact receptor as docked, providing two important constraints for the modeling of this interaction. This should expand our understanding of the molecular basis of natural agonist ligand binding to the GLP1 receptor and may be relevant to other family members.G protein-coupled receptors (GPCRs) 2 are the largest group of membrane receptors with seven transmembrane domains and represent targets for over 30% of approved drugs. Understanding of the molecular basis of ligand binding and activation of these receptors will facilitate the development and refinement of drugs acting at these targets. Currently, the molecular basis of ligand binding and activation of Family B GPCRs is less well understood than that of the larger Family A, where high resolution crystal structures have recently been described for several members (1-4).A characteristic structural feature of this family is a long and structurally complex extracellular amino-terminal domain containing six conserved cysteine residues that form disulfide bonds important for stabilizing the folded structure. This domain has been suggested to interact with the carboxyl-terminal region of the natural peptide ligands, based on structure-activity relationship, site-directed mutagenesis, and chimeric receptor studies (5-10), and this is a consistent theme throughout their family.Insights into the structure of the predominant ligand binding domain, the amino terminus of the Family B GPCRs, have substantially advanced with the solution of NMR and crystal structures of the isolated ligand-bound amino terminus of the receptors for corticotrophin-releasing factor (11-13...

supporting

confidence: 77%

mentioning

confidence: 99%

Molecular Basis of Glucagon-like Peptide 1 Docking to Its Intact Receptor Studied with Carboxyl-terminal Photolabile Probes

Chen

Pinon

Miller

et al. 2009

Self Cite

“…Each receptor possesses a characteristically large and sequence-divergent extracellular N-terminal domain; however, there is conservation of key residues, including three disulfide bonds within this domain, that aids in stability and confers similarities in secondary structure (3,4). The widely accepted peptide-receptor binding model for family B GPCRs is the two domain model, whereby the ␣-helical C terminus of the endogenous ligand interacts with the N-terminal domain of the receptor, and the N terminus of the peptide interacts with the core domain of the receptor, which includes both the extracellular loops and TM bundle (5)(6)(7). Generically, the N-terminal domain of the receptor is primarily responsible for ligand recognition and specificity, whereas the core of the receptor has a major influence in signaling specificity and transmission (8).…”

Section: Gpcrsmentioning

confidence: 99%

Second Extracellular Loop of Human Glucagon-like Peptide-1 Receptor (GLP-1R) Has a Critical Role in GLP-1 Peptide Binding and Receptor Activation

Koole

Wootten

Simms

et al. 2012

Self Cite

121

Background: The ECL2 of family B GPCRs has been suggested to contribute to biological activity. Results: Mutation of most ECL2 residues to alanine results in changes in binding and/or efficacy of GLP-1 peptide agonists. Conclusion: The ECL2 of the GLP-1R is critical for GLP-1 peptide-mediated receptor activation and selective signaling. Significance: This work reveals broad significance for ECL2 in maintaining receptor conformations driving selective signaling.

“…In human CT (hCT), amino acid 16, located one helical turn apart from residue 19, cross-linked to Phe 137 , consistent with orientation of the ␣-helix of agonist peptides with the membrane-proximal region of the receptor amino terminus (46). We have also demonstrated that hCT amino acid 26 interacts with Thr 30 in the distal amino terminus (46), whereas hCT amino acid 8 interacts with Leu 368 in the third extracellular loop (47).…”

Section: Calcitonins (Cts)mentioning

confidence: 77%

Insights into Interactions between the α-Helical Region of the Salmon Calcitonin Antagonists and the Human Calcitonin Receptor using Photoaffinity Labeling

Pham

Dong

Wade

et al. 2005

Self Cite

Fish-like calcitonins (CTs), such as salmon CT (sCT), are widely used clinically in the treatment of bone-related disorders; however, the molecular basis for CT binding to its receptor, a class II G protein-coupled receptor, is not well defined. In this study we have used photoaffinity labeling to identify proximity sites between CT and its receptor. Calcitonins (CTs)1 are 32-amino acid peptide hormones with a wide spectrum of biological activity. The most recognized action is the inhibition of osteoclast-mediated bone resorption, which forms the basis for its primary clinical use in the treatment of bone-related disorders such as Paget disease, osteoporosis, and hypercalcemia of malignancy (1-3). CT, however, also has activity that includes modulation of renal ion excretion (4 -7), analgesia (8), inhibition of appetite (9), and gastric acid secretion (10 -12), as well as effects on reproduction via effects on embryological implantation and sperm function (13-15).Calcitonin receptors (CTRs) belong to the class II subfamily of G protein-coupled receptors, which also includes receptors for other peptides such as parathyroid hormone (PTH) and PTH-related peptide, secretin, vasoactive intestinal peptide, glucagon, glucagon-like peptide-1, growth hormone-releasing hormone, calcitonin gene-related peptide, and corticotropinreleasing factor. These peptide hormone class II G proteincoupled receptors share 30 -50% amino acid identity as well as a number of conserved structural motifs and are thought to interact with their ligands in a similar manner (16 -18).Alternative RNA splicing yields multiple CTR mRNA isoforms. In man, at least six potential variants exist (19 -26); however, the most common hCTR isoforms differ by the presence (hCTR b ) or absence (hCTR a ) of a 16-amino acid insert between amino acids 174 and 175, within the first intracellular loop of the receptor (23). Of these, the hCTR a is the major human receptor isoform and is expressed in essentially all tissues known to express the CTR.CTs from different species can be subdivided into three major classes: human/rodent, artiodactyl, and teleost/avian. Of these, the members of the teleost/avian group are generally the most potent, although relative potency varies in a species-and isoform-specific manner (19,(27)(28)(29)(30)(31). The higher potency combined with a longer in vivo half-life has led to fish-like CTs, exemplified by salmon CT (sCT), being the principle form of CT used for the clinical treatment of bone disorders (32, 33).However, the usefulness of CT is limited by the development of clinical resistance. This can be due to the development of circulating antibodies against non-human CT (34 -38), but it also occurs from loss of responsiveness to CT, presumably via receptor down-regulation and inhibition of new receptor synthesis (39 -41). The optimal use of CTs remains unresolved, a situation that stems in part from lack of understanding of the bimolecular interaction between CT and its receptor and how