Proposed Ligand Binding Site of the Transmembrane Receptor for Neurotensin(8–13)

Yuan-Ping Pang,Bernadette Cusack,Karen Groshan,Elliott Richelson

doi:10.1074/jbc.271.25.15060

Yuan-Ping Pang, Bernadette Cusack + Show 2 more

Open Access

https://doi.org/10.1074/jbc.271.25.15060

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Abstract

We report here the first proposed ligand binding site of the transmembrane receptor for neurotensin(8-13) in human and rat, the corresponding bound conformation of the peptide ligand, and site-directed mutagenesis studies that support the binding site model. These three-dimensional structures were generated by using a heuristic approach in conjunction with experimental data. The proposed neurotensin(8-13) binding site is primarily composed of eight residues (i.e., Phe326, Ile329, Trp334, Phe337, Tyr339, Phe341, Tyr342, and Tyr344 in the human receptor; Phe331, Ile334, Trp339, Phe342, Phe344, Phe346, Tyr347, and Tyr349 in the rat receptor) located in the third extracellular loop. The seven aromatic residues form an aromatic pocket on the extracellular surface of the neurotensin receptor to accommodate its ligands apparently by cation-pi, pi-pi, and hydrogen bonding interactions. The neurotensin(8-13) ligand adopts a compact conformation at the proposed binding site. In the bound conformation of neurotensin(8-13), the backbone of Arg9-Pro10-Tyr11-Ile12 forms the proline type I turn, and the hydroxy group of Tyr11 interacts with the two guanidinium groups of Arg8 and Arg9. These guanidinium groups are curled toward the hydroxy group so that they interact electrostatically with the hydroxy group, and that the guanidinium group of Arg9 forms an intra-hydrogen bond with the hydroxy group. The proposed three-dimensional structure may not only provide a basis for rationalizing mutations of the neurotensin receptor gene but also offer insights into understanding the binding of many neurotensin analogs, biological functions of the neurotensin receptors, and structural elements for species specificity of the neurotensin receptors, and may expedite developing nonpeptidic neurotensin mimetics for the potential treatment of the neuropsychiatric diseases.

Highlights

§ To whom correspondence should be addressed: Neurochemistry Research, Mayo Foundation for Medical Education and Research, 4500 San Pablo Rd., Jacksonville, FL 32224
Knowledge of the three-dimensional structure of the NT(8 –13) binding site can expedite the development of such mimetics and non-peptidic antagonists of NT for evaluating the physiological and putative pathological roles of NT, provide a basis for rationalizing mutations of the NT receptor gene, and enhance our understanding of the binding of many NT analogs, biological functions of the NT receptors, and structural elements for species specificity of the NT receptors
Tanaka et al first reported the putative regions of the transmembrane helices and the loops in the rat NT receptor based on their hydropathicity profile analysis and sequence comparison with some representative G-protein-coupled receptors [8]

Summary

Introduction

§ To whom correspondence should be addressed: Neurochemistry Research, Mayo Foundation for Medical Education and Research, 4500 San Pablo Rd., Jacksonville, FL 32224. Another common approach to modeling of transmembrane receptors is de novo tertiary prediction [12] This involves (i) aligning a family of homologous sequences to identify the locations of the ␣-helices, ␤-strands, and ␤-turns, (ii) predicting such secondary structures, (iii) packing such secondary structures into a group of rough tertiary folds, (iv) refining the folds into detailed tertiary structures, and (v) selecting the most reasonable structure according to experimental data. This approach is, in principle, applicable to the modeling of the NT receptors. In delineating the NT(8 –13) binding site, we applied the latter approach using constraints that were empirically defined according to the NT receptor specificity and the nature of the

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