Bone stimulating factor

Chemistry: natural resins or derivatives; peptides or proteins; – Peptides of 3 to 100 amino acid residues

Reexamination Certificate

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Details

C530S350000

Reexamination Certificate

active

06274702

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates to proteins and polypeptides which stimulate bone growth.
BACKGROUND OF THE INVENTION
It is known that even in the adult human, bone can be subject to turnover. In certain locations, such as the internal auditory capsule, there is apparently no turnover after the organ is formed. In other locations, particularly in the central skeletal axis, the turnover appears to continue during adulthood. Bone turnover occurs on the surface of the existing bone matrix, which is composed of protein (mainly collagen) and minerals. Bone turnover is initiated with the destruction of bone matrix by osteoclasts. An osteoclast is a multinucleated cell which secretes acid and proteolytic enzymes leading to the lysis of the collagen matrix protein and the release of minerals into the extracellular fluid compartment. Following this initial phase of bone destruction, or resorptive phase, formation of new bone protein matrix sets in. New bone proteins are deposited, and sometime later, minerals begin to be incorporated into the newly formed matrix. The formation of bone matrix and its subsequent mineralization are functions of osteoblasts, which are mononucleated cells. The formation phase is often followed by a period of inactivity (1,2). Resorption appears to be tightly coupled with formation (3) in vivo. Bone turnover is thus a succession of events, the location of which is known as the Bone Metabolism Unit or the BMU. Osteoblasts and osteoclasts, the putative mediators of bone turnover are thought to belong to two distinct cell lineages. These two cell types are not preformed cells, but they differentiate from their precursors through cell activation (4,5,6).
Bone matrix can either be maintained by a total cessation of bone turnover, as for the bone of the internal auditory capsule, or by a balance between formation and resorption. In many studies on skeletal changes in relation to age, a gain in the total body bone volume is observed during the growth period and the skeletal mass reaches a maximum at early adulthood. This gain is followed by a fall in bone volume as age advances. In females, a phase of more rapid bone loss often occurs during the perimenopausal period before a slower steadier phase. For this reason, bone loss in the female tends to be more severe than in the male. An understanding of bone balance in the BMU may thus be critical to understanding the pathogenesis of skeletal aging. In any case, mechanisms controlling bone turnover are complex and are not well understood at this time. The complexity of the control mechanisms has resulted in a variety of approaches to reducing bone loss.
Generally speaking, bone turnover can be regulated at two different stages. It can be regulated at the stage of the activation of precursor cells. Regulators of cellular activation can control not only the number of active BMU in the skeleton, but possibly also the number of osteoclasts and osteoblasts in an individual BMU. Alternatively, bone turnover can be regulated at the level of differentiated bone cells. The complexity of the bone cell system makes the separate study of these two levels of regulation difficult (3).
Regulators of bone cells appear to fall into two categories. The first of these interacts with specific receptors on cell membranes. One class of these regulators acts through the adenylate cyclase system with the generation of intra-cellular cyclic AMP as a second messenger acting on the protein kinase K system. Parathyroid hormone (PFM) and calcitonin (CT) belong to this class (7). A second class also interacts with a membrane receptor and results in the intracellular release of a molecule derived from phosphoinositides which in turn leads to an increase in intracellular calcium and activation of Kinase C. A third class involves interaction of the regulator with a cell surface receptor, but the second signal is generated by the receptor molecule itself with the subsequent activation of tyrosine Kinase. Many of the growth factors appear to act in this way (8-15). The second category of regulator does not interact with a cell membrane receptor, but can cross the cell membrane to bind with a cytosolic receptor. The regulator is then transported across the nuclear membrane by the cytosolic receptor to interact with the DNA resulting in increased transcription of specific genes. Steroid hormones, including vitamin D, appear to act in this manner (16).
Many hormones stimulate the proliferation of osteoclasts. These include 1,25(OH)
2
D, PTH and prostaglandins. PTH and 1,25(OH)
2
D receptors in osteoclasts have apparently not yet been identified These two hormones seem to have no effect on osteoclasts in culture. However, when osteoclasts are co-cultured with osteoblast-like cell lines, PTH and 1,25(OH)
2
D stimulate the proliferation of osteoclasts. IL-1 and TNF appear to act in a similar way as PTH and 1,25(OH)
2
D. Other growth factors, like EGF, TFG and PDGF appear to stimulate osteoclasts through increased production of PGE. Calcitonin and corticosteroids are known osteoclast inhibitors along with chemicals such as diphosphonates.
It is currently believed that interleukin 1 may stimulate collagen and non-collagen bone protein and DNA synthesis. The effect on bone protein synthesis is blocked by indomethacin, suggesting that this action of IL-1 is mediated through PGE. Indomethacin seems to have no effect on the IL-1 effect on osteoblast DNA synthesis. In culture studies on osteoblast-like cell lines suggest that some locally produced growth factors stimulate DNA and collagen synthesis. In bone cell culture, PTH or Vitamin D suppresses collagen synthesis. This in vitro effect of PTH contrasts with the in vivo effect observed in human subjects and experimental animals. It has been demonstrated in rats and in human hyperparathyroid patients that PTH can stimulate the deposition of mineralized bone matrix. Preliminary clinical trial studies on the efficacy of the PFM 1-34 amino acid fragment in the treatment of osteoporosis indicate that this PTH fragment can increase the trabecular volume. The reason for this discrepancy is not yet fully explained.
Parathyroid hormone is a peptide of 84 amino acids in its mature form. Initially translated pre-pro-parathyroid hormone is much larger, the pre sequence being a signal sequence which is cleaved when the peptide enters the rough endoplasmic reticulum. In the golgi apparatus, the pro-sequence is cleaved off leaving the intact mature hormone packaged in the secretory granule. It appears that regulation of the rate of secretion is governed not so much by the rate of production of the intracellular peptide, but in the rate of intracellular destruction and in the rate of secretion. Intracellularly, the mature peptide is truncated at both the amino and the carboxyl termini. The truncated peptide may be secreted into the circulation as an inactive fragment. The secretion of the mature peptide can be stimulated by a drop in the extracellular calcium concentration. An elevated serum calcium concentration on the other hand appears to suppress the secretion of PTH. Once in circulation, the mature peptide is rapidly cleaved in the liver at many sites of the molecule including the region of the 38 amino acid residue. The smaller fragment at the amino terminal end, which includes the first 34 amino acids, carries the full known biological activity in terms of its action on the kidney, the intestine and the bone. It also binds fully to the cell membrane receptor to stimulate cAMP production. The level of the 1-38 fragment in the serum is normally unmeasurable indicating that it has a short circulatory life. The larger inactive carboxyl terminal fragment has a relatively long half life and carries the highest proportion of the immunoreactive PTH in the circulatory system. All fragments in circulation are eventually destroyed in the kidney and the liver. One of the renal mechanisms for ridding the circulating inactive PTH fragments is glomerular filtration (17).
PTH participates in calcium and skeletal home

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