Investigating GIPR (ant)agonism: A structural analysis of GIP and its receptor
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Investigating GIPR (ant)agonism : A structural analysis of GIP and its receptor. / Smit, Florent X.; van der Velden, Wijnand J. C.; Kizilkaya, Husun S.; Nørskov, Amalie; Lückmann, Michael; Hansen, Tobias N.; Sparre-Ulrich, Alexander H.; Qvotrup, Katrine; Frimurer, Thomas M.; Rosenkilde, Mette M.
I: Structure, Bind 29, Nr. 7, 2021, s. 679-693.e6.Publikation: Bidrag til tidsskrift › Tidsskriftartikel › fagfællebedømt
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TY - JOUR
T1 - Investigating GIPR (ant)agonism
T2 - A structural analysis of GIP and its receptor
AU - Smit, Florent X.
AU - van der Velden, Wijnand J. C.
AU - Kizilkaya, Husun S.
AU - Nørskov, Amalie
AU - Lückmann, Michael
AU - Hansen, Tobias N.
AU - Sparre-Ulrich, Alexander H.
AU - Qvotrup, Katrine
AU - Frimurer, Thomas M.
AU - Rosenkilde, Mette M.
PY - 2021
Y1 - 2021
N2 - The glucose-dependent insulinotropic polypeptide (GIP) is a 42-residue metabolic hormone that is actively being targeted for its regulatory role of glycemia and energy balance. Limited structural data of its receptor has made ligand design tedious. This study investigates the structure and function of the GIP receptor (GIPR), using a homology model based on the GLP-1 receptor. Molecular dynamics combined with in vitro mutational data were used to pinpoint residues involved in ligand binding and/or receptor activation. Significant differences in binding mode were identified for the naturally occurring agonists GIP(1-30) NH2 and GIP(1-42) compared with high potency antagonists GIP(3-30)NH2 and GIP(5-30)NH2. Residues R183(2.60), R190(2.67), and R300(5.40) are shown to be key for activation of the GIPR, and evidence suggests that a disruption of the K293(ECL2)-E362(ECL3) salt bridge by GIPR antagonists strongly reduces GIPR activation. Combinatorial use of these findings can benefit rational design of ligands targeting the GIPR.
AB - The glucose-dependent insulinotropic polypeptide (GIP) is a 42-residue metabolic hormone that is actively being targeted for its regulatory role of glycemia and energy balance. Limited structural data of its receptor has made ligand design tedious. This study investigates the structure and function of the GIP receptor (GIPR), using a homology model based on the GLP-1 receptor. Molecular dynamics combined with in vitro mutational data were used to pinpoint residues involved in ligand binding and/or receptor activation. Significant differences in binding mode were identified for the naturally occurring agonists GIP(1-30) NH2 and GIP(1-42) compared with high potency antagonists GIP(3-30)NH2 and GIP(5-30)NH2. Residues R183(2.60), R190(2.67), and R300(5.40) are shown to be key for activation of the GIPR, and evidence suggests that a disruption of the K293(ECL2)-E362(ECL3) salt bridge by GIPR antagonists strongly reduces GIPR activation. Combinatorial use of these findings can benefit rational design of ligands targeting the GIPR.
KW - GASTRIC-INHIBITORY POLYPEPTIDE
KW - DEPENDENT INSULINOTROPIC POLYPEPTIDE
KW - GLP-1 RECEPTOR
KW - GLUCOSE
KW - DYNAMICS
KW - GLUCAGON
KW - FAMILY
KW - FRAGMENT
KW - LESSONS
KW - COMPLEX
U2 - 10.1016/j.str.2021.04.001
DO - 10.1016/j.str.2021.04.001
M3 - Journal article
C2 - 33891864
VL - 29
SP - 679-693.e6
JO - Structure
JF - Structure
SN - 0969-2126
IS - 7
ER -
ID: 274273129