It has been established that regenerating marrow induces an osteogenic response in distant skeletal sites and that this activity is mediated by factors released into the circulation by the healing tissue. In the present study we have characterized one of these factors, a 14 amino acid peptide named osteogenic growth peptide (OGP). Synthetic OGP, identical in structure to the native molecule, stimulates the proliferation and alkaline phosphatase activity of osteoblastic cells in vitro and increases bone mass in rats when injected in vivo. Immunoreactive OGP in high abundance is present physiologically in the serum, mainly in the form of an OGP‐OGP binding protein complex. A marked increase in serum bound and unbound OGP accompanies the osteogenic phase of post‐ablation marrow regeneration and associated systemic osteogenic response. Authentic OGP is identical to the C‐terminus of histone H4 and shares a five residue motif with a T‐cell receptor beta‐chain V‐region and the Bacillus subtilis outB locus. Since these latter proteins have not been implicated previously in the control of cell proliferation or differentiation, OGP may belong to a novel, heretofore unrecognized family of regulatory peptides. Perhaps more importantly, OGP appears to represent a new class of molecules involved in the systemic control of osteoblast proliferation and differentiation.
In an effort to characterize the bimolecular interface between parathyroid hormone (PTH) and its human receptor PTH1-Rc (hPTH1-Rc), we previously identified two contact sites in the receptor: one for position 1 and another for position 13 (located at the ends of the principal activation domain) in PTH(1-34). The present study reports a third, novel "contact site" between hPTH1-Rc and Lys(27) of PTH(1-34). Lys(27) is located in the principal binding domain of the hormone (residues 25-34). The photoreactive PTH(1-34) analogue K27 contains a benzophenone (BP) moiety on Lys(27). The analogue binds to stably transfected HEK 293/C-21 cells (which express a high level of recombinant hPTH1-Rc) and stimulates adenylyl cyclase activity with a potency similar to PTH(1-34). In addition, (125)I-K27 cross-links effectively and specifically to the hPTH1-Rc. Enzymatic (Glu-C and Lys-C) and chemical (CNBr and BNPS-skatole) digestions of the photoconjugate between (125)I-K27 and hPTH1-Rc were performed. In addition, photoconjugates involving the bioactive mutants [L261M]- and [R262K]-hPTH1-Rc, transiently expressed in COS-7 cells, were also digested. The data obtained clearly identify L(261) or R(262) of the first extracellular loop of hPTH1-Rc as the contact site for Lys(27) in the hormone. On the basis of (i) the similarity in molecular mass between the CNBr digest of the (125)I-K27-[L261M]hPTH1-Rc conjugate and free (125)I-K27 and (ii) the failure to cross-link (125)I-K27 to a bioactive mutant receptor [L261A]hPTH1-Rc, we conclude that L(261) is the cross-linking site. These results provide the first demonstration of an interaction between the principal binding domain of PTH and the first extracellular loop of hPTH1-Rc. Revealing proximity of Lys(27) (in PTH) to L(261) (in hPTH1-Rc) provides additional insight into the nature of the ligand-receptor bimolecular interface and clearly illustrates that the extracellular loops of the receptor contribute to the specificity of the PTH-PTH1-Rc interaction. Taken together with previous studies, the new findings add important constraints on the possible positioning of the C-terminal helix of PTH (which contains the principal binding domain) relative to the first extracellular loop and the distal C-terminal helix of the large extracellular amino terminal domain of the PTH1-Rc.
Parathyroid hormone (PTH) regulates calcium metabolism through a specific G protein-coupled, seven-transmembrane helix-containing receptor. This receptor also binds and is activated by PTH-related protein (PTHrP). The human (h) PTH/PTHrP receptor is a membrane glycoprotein with an apparent molecular weight of approximately 85000 which contains four putative N-glycosylation sites. To elucidate the functional role of receptor glycosylation, if any, we studied hormone binding and signal transduction in human embryonic kidney cells transfected with hPTH/PTHrP receptor (HEK-293/C-21). These cells stably express 300000-400000 receptors per cell. Inhibition of N-glycosylation with an optimized concentration of tunicamycin yielded completely nonglycosylated hPTH/PTHrP receptor (approximately 60 kDa). This receptor form is fully functional; it maintains nanomolar binding affinity for PTH- and PTHrP-derived agonists and antagonists. PTH and PTHrP agonists stimulate cyclic AMP accumulation and increases in cytosolic calcium levels. In addition, the highly potent benzophenone (pBz2)-containing PTH-derived radioligand [Nle8,18,Lys13(epsilon-pBz2),L-2-Nal23,Tyr34 3-125I)]bPTH(1-34)NH2 can photoaffinity cross-link specifically to the nonglycosylated receptor. The molecular weight (approximately 60000) of the band representing the photo-cross-linked, nonglycosylated receptor (obtained from the tunicamycin-treated HEK-293/C-21 cells) was similar to that of the deglycosylated photo-cross-linked receptor (obtained by enzymatic treatment with Endoglycosidase-F/N-glycosidase-F). Our findings indicate that glycosylation of the hPTH/PTHrP receptor is not essential for its effective expression on the plasma membrane or for the binding of ligands known to interact with the native receptor. The nonglycosylated hPTH/PTHrP receptor remains fully functional with regard to both of its known signal transduction pathways: cAMP-protein kinase A and phospholipase C-cytosolic calcium.
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