Labbé-Jullié C, Barroso S, Nicolas-Etève D, Reversat J L, Botto J M, Mazella J, Bernassau J M, Kitabgi P
Institut de Pharmacologie Moléculaire et Cellulaire du CNRS, Université de Nice-Sophia Antipolis, Sophia Antipolis, 660 Route des Lucioles, 06560 Valbonne, France.
J Biol Chem. 1998 Jun 26;273(26):16351-7. doi: 10.1074/jbc.273.26.16351.
The two neurotensin receptor subtypes known to date, NTR1 and NTR2, belong to the family of G-protein-coupled receptors with seven putative transmembrane domains (TM). SR 48692, a nonpeptide neurotensin antagonist, is selective for the NTR1. In the present study we attempted, through mutagenesis and computer-assisted modeling, to identify residues in the rat NTR1 that are involved in antagonist binding and to provide a tentative molecular model of the SR 48692 binding site. The seven putative TMs of the NTR1 were defined by sequence comparison and alignment of bovine rhodopsin and G-protein-coupled receptors. Thirty-five amino acid residues within or flanking the TMs were mutated to alanine. Additional mutations were performed for basic residues. The wild type and mutant receptors were expressed in COS M6 cells and tested for their ability to bind 125I-NT and [3H]SR 48692. A tridimensional model of the SR 48692 binding site was constructed using frog rhodopsin as a template. SR 48692 was docked into the receptor, taking into account the mutagenesis data for orienting the antagonist. The model shows that the antagonist binding pocket lies near the extracellular side of the transmembrane helices within the first two helical turns. The data identify one residue in TM 4, three in TM 6, and four in TM 7 that are involved in SR 48692 binding. Two of these residues, Arg327 in TM 6 and Tyr351 in TM 7, play a key role in antagonist/receptor interactions. The former appears to form an ionic link with the carboxylic group of SR 48692, as further supported by structure-activity studies using SR 48692 analogs. The data also show that the agonist and antagonist binding sites in the rNTR1 are different and help formulate hypotheses as to the structural basis for the selectivity of SR 48692 toward the NTR1 and NTR2.
迄今已知的两种神经降压素受体亚型,即NTR1和NTR2,属于具有7个假定跨膜结构域(TM)的G蛋白偶联受体家族。非肽类神经降压素拮抗剂SR 48692对NTR1具有选择性。在本研究中,我们试图通过诱变和计算机辅助建模,确定大鼠NTR1中参与拮抗剂结合的残基,并提供SR 48692结合位点的初步分子模型。通过牛视紫红质和G蛋白偶联受体的序列比较和比对,确定了NTR1的7个假定跨膜结构域。跨膜结构域内或其侧翼的35个氨基酸残基被突变为丙氨酸。对碱性残基进行了额外的突变。野生型和突变型受体在COS M6细胞中表达,并测试它们结合125I-NT和[3H]SR 48692的能力。以蛙视紫红质为模板构建了SR 48692结合位点的三维模型。将SR 48692对接至受体中,同时考虑诱变数据以确定拮抗剂的方向。该模型显示,拮抗剂结合口袋位于跨膜螺旋前两圈的细胞外侧附近。数据确定了跨膜结构域4中的1个残基、跨膜结构域6中的3个残基和跨膜结构域7中的4个残基参与SR 48692的结合。这些残基中的两个,即跨膜结构域6中的Arg327和跨膜结构域7中的Tyr351,在拮抗剂/受体相互作用中起关键作用。前者似乎与SR 48692的羧基形成离子键,使用SR 48692类似物的构效关系研究进一步支持了这一点。数据还表明,大鼠NTR1中的激动剂和拮抗剂结合位点不同,并有助于就SR 48692对NTR1和NTR2选择性的结构基础提出假设。
