Structure-bioactivity of C-terminal pentapeptide of osteogenic growth peptide [OGP(10-14)].

The amino acid sequence of osteogenic growth peptide (OGP) consists of 14 residues identical to the C-terminal tail of histone H4. Native and synthetic OGP are mitogenic to osteoblastic and fibroblastic cells and enhance osteogenesis and hematopoiesis in vivo. The C-terminal truncated pentapeptide of OGP, H-Tyr-Gly-Phe-Gly-Gly-OH [OGP(10-14)], is a naturally occurring osteoblastic mitogen, equipotent to OGP. The present study assesses the role of individual amino acid residues and side chains in the OGP(10-14) mitogenic activity which showed a very high correlation between osteoblastic and fibroblastic cell cultures. Truncation of either Tyr10 or its replacement by Ala or D-Ala resulted in substantial, but not complete, loss of activity. Nevertheless, only a small loss of activity was observed following removal of the Tyr10 amino group. No further loss occurred consequent to the monoiodination of desaminoTyr10 on meta-position. However, a marked decrease in proliferative activity followed removal of the Tyr10 phenolic or the Phe12 aromatic group. Loss of activity of a similar magnitude also occurred subsequent to replacing Gly11 with L- or D-Ala. Approximately 50% loss of mitogenic activity occurred subsequent to truncation of Gly14 or blocking the C-terminal group as the methyl ester. All other modifications of the C-terminus and L- or D-Ala substitution of Gly13 resulted in 70-97% decrease in activity. Collectively, these data suggest that the integrity of the pharmacophores presented by Tyr and Phe side chains, as well as the Gly residues at the C-terminus, are important for optimal bioactivity of OGP(10-14).

Osteogenic growth peptide increases blood and bone marrow cellularity and enhances engraftment of bone marrow transplants in mice.

The osteogenic growth peptide (OGP) was characterized recently in regenerating bone marrow (BM) and normal serum. In vitro, the OGP regulates stromal-cell proliferation and differentiated functions. In vivo, an increase in serum OGP accompanies the osteogenic phase of postablation BM regeneration. The present results in normal mice show that OGP induces a balanced increase in WBC counts and overall BM cellularity. In mice receiving myeloablative irradiation and syngeneic or semiallogeneic BM transplants, OGP stimulates hematopoietic reconstruction and doubles the survival rate; these effects are dependent on initiating the OGP administration before irradiation. Chimerism measurements in semiallogeneic graft recipients suggest no preferential effect of OGP on residual host cells. The data implicate OGP in the acceleration of hematopoiesis secondary to expansion of the stromal microenvironment and/or enhancement of stroma-derived signals to stem cells. The low-dose effectiveness of OGP is explained by the demonstration of an autocrine positive feedback loop that together with the OGP-binding protein sustains high serum levels of the peptide. A potential OGP-based treatment in combination with chemoradiotherapy is attractive because of the OGP-induced balanced multi-lineage enhancement of hematopoiesis and possible replacement of expensive recombinant cytokines by a readily synthesized peptide.

Structural and functional characterization of osteogenic growth peptide from human serum: identity with rat and mouse homologs.

The osteogenic growth peptide (OGP) was recently characterized in regenerating bone marrow. In experimental animals, OGP increases osteogenesis. Immunoreactive OGP (irOGP) in high abundance was demonstrated in normal animal serum mainly as an OGP-OGP-binding protein (OGPBP) complex. Here we show the presence of an OGP-OGPBP system in normal human serum. The total irOGP content, of which the bound peptide comprises at least 80-90%, ranged from 480-4460 mumol/L, several orders of magnitude higher than that of other regulatory polypeptides. The steady state/total irOGP ratio declined between 23 and 49 yr of age. The bound irOGP, purified by boiling, ultrafiltration, and hydrophobic high pressure liquid chromatography, was identical to OGP obtained previously from rat regenerating marrow and mouse stromal cell cultures in terms of its amino acid sequence, immunoreactivity, and mitogenicity. These data demonstrate the usefulness of our immunoassay to measure circulating OGP. More importantly, the identity of the human OGP with that of other species indicates the peptide's evolutionary conservation and, thus, its biological importance. The natural occurrence of OGP in man signifies its potential role in the prevention of bone loss and rescue of bone mass, especially in osteoporosis.