We recently modelled and proposed four ligand-bound conformations for a G-protein-coupled receptor, namely, forms I, II, III and IV, based on the 3D structure and functional evidences for rhodopsin. In this study, the same strategy was applied to a human nociceptin receptor (NR), in order to predict ligand-bound receptor structures. Additionally, site-directed mutagenesis studies were carried out to evaluate these structures. A Thr138Ala mutant demonstrated the same affinity for [Phe(1)Psi(CH(2)-NH)Gly(2)]nociceptin(1-13)NH(2) as the wild-type receptor; however, the affinity of this mutant for nociceptin was 20-fold lower than that of the wild type. A Ser223Ala mutation showed the same characteristics as those of the wild type. On the other hand, a Gln280Ala mutation reduced the affinity to nociceptin by more than 60-folds. These results suggested that a change in the conformation of NR following agonist binding did not accompany the rigid-body rotation of the sixth transmembrane segment that was reported for an adrenergic receptor and a kappa-opioid receptor. NR is potently activated not only by nociceptin but also a synthetic peptide, i.e. Ac-RYYRIK-NH(2), although the amino acid sequences of both these ligands are completely different. The model explains why both the ligands activate NR and shows that their receptor-bound conformations have similar 3D structures.
Midkine (MK) is a heparin binding growth factor having functions of neurite-outgrowth, mitogenesis and tissue repair. This molecule is involved in tumor growth and metastasis. The MK molecule consists of five exons, but there is a truncated isoform, lacking exon 3. We established SW13 cells transfected with the human truncated MK cDNA. These cells were induced to undergo apoptosis by anticancer agents, cisplatin, etoposide (ETP), mitomycin C (MMC) and paclitaxel (PAX). Truncated midkine (tMK) suppressed cell death and helped the cells to be viable. When the cells were cultured on dishes coated with extracellular matrix molecules, spontaneous detachment occurred in the tMK expressing cells. Also tMK enhanced cell invasion. These results suggest that expression of tMK has cell-protective functions and plays important roles in carcinogenesis and malignancy. Furthermore, it is suggested that tMK has a greater ability of malignant transformation than full-length MK. Whether tMK is expressed or not will be useful information for improving cancer chemotherapy.
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