Alendronate does not prevent long bone fragility in an inactive rat model.

The lack of estrogen and inactivity are both important in the pathogenesis of osteoporosis in elderly women, and there have been no appropriate rodent studies to examine the effects of common bisphosphonates on these two components separately. We compared the efficacy of alendronate (ALN) on the long bones of aged female rats, which were sedentary, estrogen deficient, or both. The rats were either forced to remain in a sitting position or allowed to walk in standard cages with or without ALN administration. The 8-week experimental period began 5 weeks after ovariectomy or sham surgery. Parameters of the hindlimb bones were determined by a three-point bending test, peripheral quantitative computed tomography, microfocus computed tomography, confocal laser Raman microspectroscopy, and dynamic histomorphometry. Regardless of ovariectomy, ALN was ineffective against the deterioration of breaking stress caused by sitting even though the trabecular bone mineral density was significantly higher in the sitting-ALN groups. Toughness was significantly deficient in the ovariectomy sitting-ALN group. This was in agreement with the bone geometry with a greater marrow space. Sitting also increased the mineral-to-matrix ratio and the carbonate-to-phosphate ratio, both indicative of aged bone. A greater loss of proteinaceous amide intensity compared with mineral intensity resulted in an increased mineral-to-matrix ratio in the presence of ALN. Sitting resulted in deficits in the quality and the geometry of cortical bone, resulting in fragility. The use of bisphosphonates, such as ALN, may provide a therapy best suited for osteoporotic individuals whose daily activity is not limited.

Mechanotransduction activates α5ß1 integrin and PI3K/Akt signaling pathways in mandibular osteoblasts.

It is unclear how bone cells at different sites detect mechanical loading and how site-specific mechanotransduction affects bone homeostasis. To differentiate the anabolic mechanical responses of mandibular cells from those of calvarial and long bone cells, we isolated osteoblasts from C57B6J mouse bones, cultured them for 1week, and subjected them to therapeutic low intensity pulsed ultrasound (LIPUS). While the expression of the marker proteins of osteoblasts and osteocytes such as alkaline phosphatase and FGF23, as well as Wnt1 and ß-catenin, was equally upregulated, the expression of mandibular osteoblast messages related to bone remodeling and apoptosis differed from that of messages of other osteoblasts, in that the messages encoding the pro-remodeling protein RANKL and the anti-apoptotic protein Bcl-2 were markedly upregulated from the very low baseline levels. Blockage of the PI3K and α(5)ß(1) integrin pathways showed that the mandibular osteoblast required mechanotransduction downstream of α(5)ß(1) integrin to upregulate expression of the proteins ß-catenin, p-Akt, Bcl-2, and RANKL. Mandibular osteoblasts thus must be mechanically loaded to preserve their capability to promote remodeling and to insure osteoblast survival, both of which maintain intact mandibular bone tissue. In contrast, calvarial Bcl-2 is fully expressed, together with ILK and phosphorylated mTOR, in the absence of LIPUS. The antibody blocking α(5)ß(1) integrin suppressed both the baseline expression of all calvarial proteins examined and the LIPUS-induced expression of all mandibular proteins examined. These findings indicate that the cellular environment, in addition to the tridermic origin, determines site-specific bone homeostasis through the remodeling and survival of osteoblastic cells. Differentiated cells of the osteoblastic lineage at different sites transmit signals through transmembrane integrins such as α(5)ß(1) integrin in mandibular osteoblasts, whose signaling may play a major role in controlling bone homeostasis.

Prior treatment with vitamin K(2) significantly improves the efficacy of risedronate.

UNLABELLED: Prior 8-week treatment with menatetrenone, MK-4, followed by 8-week risedronate prevented the shortcomings of individual drugs and significantly increased the strength of ovariectomized ICR mouse femur compared to the ovariectomized (OVX) controls. Neither MK-4 following risedronate nor the concomitant administration may be recommended because they brought the least beneficial effect. INTRODUCTION: The objective of this study was to determine the best combinatory administration of risedronate at 0.25 mg/kg/day (R) with vitamin K(2) at approximately 100 microg MK-4/kg/day (K) to improve strength of osteoporotic mouse bone. METHODS: Thirteen-week-old ICR mice, ovariectomized at 9-week, were treated for 8 weeks with R, K, or R plus K (R/K), and then, either the treatment was withdrawn (WO) or switched to K or R in the case of R and K. After another 8 weeks, the mice were killed, and mechanical tests and analyses of femur properties by peripheral quantitative computed tomography, microfocus X-ray tube computed tomography, and confocal laser Raman microspectroscopy were carried out. RESULTS: The K to R femur turned out superior in parameters tested such as material properties, bone mineral density, BMC, trabecular structure, and geometry of the cortex. The increased cross-sectional moment of inertia, which occurred after K withdrawal, was prevented by risedronate in K to R. In addition to K to R, some properties of R to WO diaphysis and K to WO epiphysis were significantly better than OVX controls. CONCLUSION: Prior treatment with MK-4 followed by risedronate significantly increased femur strength in comparison to the OVX controls.

Cell-substratum attachment and cell surface hyaluronate of Rous sarcoma virus-transformed chondrocytes.

Hyaluronate is associated with the cell surface of cultured Rous sarcoma virus-transformed chondrocytes. Detachment of these cells from their substratum by a variety of reagents is accompanied by release of 75-100% of this hyaluronate into solution. Treatment of the cells with 200 U/ml protease-free Streptomyces hyaluronidase at 37 degrees C cause release of greater than 90% of the cell surface hyaluronate and complete cell detachment. Treatment with a lower concentration of Streptomyces hyaluronidase (30 U/ml) at 25 degrees C or a corresponding activity of testicular hyaluronidase gives similar results, but only in the presence of mM EGTA. Treatment with the lower activities of either hyaluronidase or with 1 mM EGTA alone release only approximately 45% of the cell surface hyaluronate and does not cause significant cell detachment. It is concluded that there are two populations of cell surface hyaluronate differing in their accessibility or their resistance to dissociation from other components of the cell surface. It is proposed that the less readily released fraction is located between the transformed chondrocyte surface and substratum and is necessary for their interaction.

Low-intensity pulsed ultrasound accelerates periodontal wound healing after flap surgery.

BACKGROUND AND OBJECTIVE: A study was conducted to evaluate the effects of low-intensity pulsed ultrasound on wound healing in periodontal tissues after mucoperiosteal flap surgery. MATERIAL AND METHODS: Bony defects were surgically produced bilaterally at the mesial roots of the mandibular fourth premolars in four beagle dogs. The flaps were repositioned to cover the defects and sutured after scaling and planing of the root surface to remove cementum. The affected area in the experimental group was exposed to low-intensity pulsed ultrasound, daily for 20 min, for a period of 4 wk from postoperative day 1 using a probe, 13 mm in diameter. On the control side, no ultrasound was emitted from the probe placed contralaterally. After the experiment, tissue samples were dissected out and fixed in 10% formalin for histological and immunohistochemical analyses. RESULTS: The experimental group showed that the processes in regeneration of both cementum and mandibular bone were accelerated by low-intensity pulsed ultrasound compared with the control group. In addition, the expression level of heat shock protein 70 was higher in the gingival epithelial cells of the low-intensity pulsed ultrasound-treated tooth. CONCLUSION: Our results suggest that osteoblasts, as well as cells in periodontal ligament and gingival epithelium, respond to mechanical stress loaded by low-intensity pulsed ultrasound, and that ultrasound accelerates periodontal wound healing and bone repair.

Characterization of peptic inhibitory activity associated with sulfated glycoprotein isolated from gastric mucosa.

Sulfated glycoproteins were extracted and purified from porcine stomach mucous scraping. Four sulfated glycoprotein fractions were separated and subsequently purified. These compounds always accompanied the apparent peptic inhibitory activity and consisted of 15-18% (w/w) protein. The carbohydrate portions contained an equimolar ratio of galactose and hexosamine (mainly glucosamine), together with lesser amounts of fucose and sialic acid. The sulfate content of the above fractions was 2-9% (w/w) of the total sulfated glycoprotein. The mode of inhibition of the sulfated glycoproteins to peptic activity was investigated and suggested that there was binding of the sulfated glycoproteins to the substrate of pepsin, making the substrate resistant to peptic activity. The sulfated glycoproteins neither bound pepsin at pH 1.8 nor inhibited the hydrolysis of a synthetic dipeptide substrate of pepsin. Desulfation of the sulfated glycoproteins resulted in the loss of both the inhibitory activity and the precipitate formation. The precipitation curve for sulfated glycoprotein and porcine serum albumin showed that both bound in varying proportions and suggests that both components are multivalent in this precipitate formation.

Matrix mineralization and the differentiation of osteocyte-like cells in culture.

Osteocyte-like cells were prepared by sequentially treating calvaria from newborn rats with collagenase and chelating agents. On a reconstituted gel of basement membrane components, cells from the third collagenase digest displayed a round shape and expressed the highest level of alkaline phosphatase with minimal osteocalcin deposition into the matrix. On the other hand, cells derived from the interior after EDTA treatment exhibited well-developed dendritic cell processes and expressed essentially no alkaline phosphatase. The latter population also showed quite distinct characteristics such as higher extracellular activities of casein kinase II and ecto-5'-nucleotidase and the extracellular accumulation of a large amount of osteocalcin associated with mineral. These diverse phenotypic and protein expressions as well as the sites from which each population of cells were recovered strongly suggest that we have isolated osteoblastic and osteocytic cells. Bone sialoprotein II was extracellularly phosphorylated by casein kinase II in osteocytic cells but not in osteoblastic cells. We discuss the possibility that differentiation of young osteocytes from osteoblasts may facilitate the biochemical sequence of mineral deposition in the bone matrix.

Distinct responses of different populations of bone cells to mechanical stress.

To explore lineage-dependent responses to mechanical stress in bone cells, newborn rat calvarial cells, exhibiting differential characteristics of osteoblastic and osteocytic cells, were compared in their immediate and late responses to stretching. Seven fractions of sequentially prepared cells were cultured on Matrigel to promote their differentiation. By cyclically stretching the flexible bottom of culture plates, cells were exposed to a physiological stress of approximately 4000 microstrain on Matrigel. Cells in fractions IV, V and VI exhibited striking responses; the levels of cAMP and insulin-like growth factor I, bone Gla protein, and mineral accumulation were significantly elevated in the stretched cells. Also, proliferation was significantly inhibited regardless of the presence of 10(-6)M indomethacin. In contrast, osteoblasts in fraction III and osteocyte-like cells in fraction VII exhibited no significant response. Thus, these intermediate cells, very mature osteoblasts to young osteocytes, are likely to serve as a mechanosensor in bone, controlling the metabolic aspects of physical stress. We conclude that the responses of these young osteocytes to low level, physiological strain are transmitted in a manner different from the responses of osteoblasts to higher magnitude of strain in which PGE2 induces cell proliferation, as reported by others.

In situ phosphorylation of bone and dentin proteins by the casein kinase II-like enzyme.

Our previous studies suggested the possibility of extracellular phosphorylation of matrix phosphoproteins into more phosphorylated forms by mature odontoblasts and osteocytes (Mikuni-Takagi et al., 1995; Satoyoshi et al., 1995). To elucidate such phosphorylation of bone and dentin proteins, we developed a histochemical method using frozen sections to determine the sites of enzymatic processing by the casein kinase II-like enzyme. It was observed that proteins in bone, dentin, and predentin are phosphorylated by the endogenous enzyme when the tissue slices were incubated with [gamma-32P] GTP, suggesting that there are both substrates and the enzyme in these matrices. In vivo, phosphate donors, ATP and GTP, may be supplied through dentinal canals and osteocyte canaliculi. Immunohistochemical analysis of frozen sections showed that the extremely intense staining of phosphoserine residues by anti-phosphoserine antibodies appeared in dentin only after demineralization of the tissue samples. It implies that these phosphoserine residues become bound to mineral as soon as the phosphorylation is completed, thereby being inaccessible to the antibodies without demineralization. The data support our notion that the extracellular phosphorylation of dentin/bone proteins, regulated by the developmental stages of bone and dentin cells, occurs prior to matrix mineralization.

Matrix metalloproteinase-2 in dentin matrix mineralization.

In the serum-free culture medium of bovine odontoblasts we detected active gelatinolytic metalloproteinases, matrix metalloproteinase (MMP)-2 and MMP-9 (gelatinases A and B). The activity of MMP-2, in particular, appeared suddenly around day 21 in the culture, coinciding with the development of odontoblastic cell processes and the loss of alkaline phosphatase. Reverse transcriptase-polymerase chain reaction analysis of these odontoblasts demonstrated that messages of MMP-2 but not MMP-9 increased significantly between day 15 and day 21. The in vitro observation indicates that medium conditioned by these odontoblasts and containing significant amounts of MMP-2 degrades not only the collagenous substrates but also purified dentin phosphophoryn as well. We have also observed that dephosphorylated dentin phosphoprotein becomes a better substrate for casein kinase II after limited proteolysis with MMP-2. These results support our working hypothesis that MMP-2-mediated proteolytic processing is an important step in accelerating the process of dentin matrix maturation, which includes phosphorylation and subsequent mineralization. As has been suggested previously, extracellular phosphorylation of matrix proteins is an important step in biomineralization both in bone and in dentin (Mikuni-Takagaki et al., J Bone Miner Res 1995;10:231-42; Zhu et al., Biochem J 1997; 323:637-43). Our present histochemical analysis in MMP-2 knockout mice confirms the concept with the delayed formation of mineralized tissues, dentin, and bone.

The role of calcium channels in osteocyte function.

Osteocytic response to stretching, which is potentiated by PTH, is distinct from that of osteoblast to high frequency strain. A MAPK dependent signaling pathway is suggested in the osteoblast response. At least two different types of mechanotransduction pathways are present in bone cells of osteoblastic lineage.

Effects of mechanical stress on the mRNA expression of S100A4 and cytoskeletal components by periodontal ligament cells.

The periodontal ligament (PDL) functions under constant mechanical stress, and PDL cells obviously control PDL functions under such conditions. We have previously found that the mRNA expression of the Ca2+-binding protein S100A4 and beta-actin is higher in the PDL from erupted teeth than in the PDL from teeth under eruption. This suggested a role for S100A4 in the response of PDL cells to mechanical stress, possibly by coupling Ca2+ and the cytoskeletal system. In the present study, we investigated the direct effects of cyclical stretching on the mRNA expression of S100A4 and two cytoskeletal components (beta-actin and alpha-tubulin) by PDL cells. In Northern blotting analysis, the expression of S100A4, beta-actin, and alpha-tubulin mRNAs was higher in the PDL from fully erupted and functional bovine teeth than in partially erupted ones. Similarly, when bovine PDL cells were mechanically stimulated by means of the Flexercell Strain Unit, the expression of S100A4, beta-actin, and alpha-tubulin mRNAs increased over the control levels. The results of our present study indicate that S100A4 is involved in the responses of PDL cells to mechanical stress possibly by coupling Ca2+ to the cytoskeletal system in these cells.

Mechanical responses and signal transduction pathways in stretched osteocytes.

Mechanotransduction in bone is complex in nature, being influenced by many modulators such as PTH, prostanoids, and extracellular Ca2+. It has been postulated that osteocytes, dendritic resident cells in bone, transduce signals of mechanical loading that result in anabolic responses such as the expression of c-fos, insulin-like growth factor-I (IGF-I), and osteocalcin. To date, however, neither the actual stimuli to which osteocytes respond nor the pathways of signal transduction are well understood. Cultured primary rat bone cells exhibit distinct responses to stretching depending on their developmental stages: young osteocytes that become progressively dendritic show striking responses to strain at physiological levels; these include an early response of cAMP secretion and the late responses such as the production of IGF-I and osteocalcin proteins. The upregulation of steady-state levels of their mRNA is biphasic, being preceded by two peaks of PGHS-2 (inducive prostaglandin G/H synthase; cox-2) gene expression. Compared to a typical transient immediate early expression of c-fos, PGHS-2 shows another distinct peak about 8 h after the initiation of stretching. Second peaks in IGF-I and osteocalcin expression are entirely dependent on the first wave of PGHS-2 expression judging from the inhibition by NS398. PGHS-2 is perhaps critically involved in the prolonged anabolic responses of bone "memory effect" to the osteogenic mechanical stimulation. In these cells, the extracellular Ca2+ is essential to their response to stretching. Furthermore, the blockers of stretch-activated channels, gadolinium (Gd3+), and of epithelial-like Na channels, benzamil, in combination abolish the effects of stretching such as elevated osteocalcin expression. Although voltage-operated or calcium-activated calcium channels or Na+-driven mechanisms, such as a Na-Ca exchanger, for example, are functioning, particulars of secondary Ca entry pathways are not certain at this point. It is conceivable, however, that the calcium influxes, both primary and secondary, trigger the anabolic reaction of bone to stretching via Ser/Thr kinase signaling pathways in osteocytic cells.

Metalloproteinases in endochondral bone formation: appearance of tissue inhibitor-resistant metalloproteinases.

Dissected embryonic chick limbs release neutral metalloproteinases during endochondral bone development. These enzymes degrade cartilage proteoglycan and gelatin in culture medium. We found the enzymes active in the medium conditioned by explants of the region adjacent to the bone marrow cavity (cavity-surround). These enzymes degrade proteoglycan (PG) and/or gelatin. These spontaneously active enzymes are resistant to serum and tissue proteinase inhibitors, alpha 2-macroglobulin, and cartilage metalloproteinase inhibitor (TIMP). The other enzymes secreted from tarsus and bone marrow explants are mostly latent in the culture medium. Activated tarsus enzymes (PG degrading and gelatinolytic) are blocked by the above inhibitors. Activated marrow enzyme does not degrade PG but is resistant to those inhibitors. Cavity-surround enzymes may play an important role in embryonic osteogenesis of long bones because of their resistance to tissue and serum inhibitors. The in vivo mechanisms by which cavity-surround enzymes are activated are yet to be determined.

Shedding of hyaluronate from the cell surface of Rous sarcoma virus-transformed chondrocytes.

Transformation of cultured chick embryo chondrocytes with Rous sarcoma virus gives rise to increased incorporation of isotopic precursors into hyaluronate and decreased incorporation into chondroitin 6-sulfate. Chemical measurements of these glycosaminoglycans showed corresponding changes. Comparison of the kinetics of production of glycosaminoglycan by normal and Rous sarcoma virus-transformed chondrocytes demonstrated (i) that the rate of accumulation in the medium was similar in both cultures, and (ii) that approximately 50% of total glycosaminoglycan produced by the normal chondrocytes, but only 10% of that from the transformed cells, accumulated in the cell layer. Prelabel-chase experiments indicated that cell surface-associated hyaluronate, as measured by release from the cell layer by trypsin treatment, was shed rapidly into the medium and accounted for all of the hyaluronate which accumulated in the medium. Thus we conclude (i) that accumulation of cell surface-associated glycosaminoglycan is dramatically reduced in Rous sarcoma virus-transformed chondrocytes, and (ii) that hyaluronate produced by the transformed chondrocytes is first deposited in the cell-associated extracellular compartment and then rapidly shed into the medium, rather than being secreted directly into the medium.

Cartilage-degrading neutral proteinase secreted by Yoshida sarcoma cells. Purification and properties.

The Yoshida sarcoma, a malignant rat tumor, has been reported by Machinami ( Machinami , R. (1972) Acta Pathol. JPN 22, 19-39) to destroy cartilage matrix in vivo. We have characterized an enzyme secreted by Yoshida sarcoma cells in culture which degrades cartilage proteoglycan in solution and also in situ in organ culture ( Mikuni - Takagaki , Y., and Gross, J. (1981) in Proceedings of the 6th International Symposium on Glycoconjugates ( Yamakawa , T., Osawa , T., Handa , S., eds) pp. 491-492, Japan Scientific Societies Press, Tokyo) ( Mikuni - Takagaki , Y., and Gross, J. (1982) in The Extracellular Matrix ( Hawkes , S., and Wang, J.L., eds) pp. 379-385, Academic Press, New York). In this report we characterized the isolated enzyme with the help of a new assay system for measurement of proteoglycan core protein degradation, which utilizes aminopropyl glass beads derivatized with hyaluronic acid. This enzyme, with a neutral pH optimum and apparent molecular weight of about 30,000, is secreted into culture medium in an active form. It is resistant to cartilage-derived inhibitors and to alpha 2-macroglobulin as well as to synthetic and natural inhibitors of serine-, thiol- and carboxylproteinases . It is inhibited by a chelating agent, 1,10-phenanthroline and thiol compounds at relatively high concentrations, and therefore is probably a metalloproteinase. The enzyme degrades type V collagen, types I and II denatured collagen (gelatin), and casein in addition to cartilage proteoglycan, but not bovine serum albumin, myoglobin, fibrinogen, elastin or native collagen types I, II, III, and IV. These findings suggest that the Yoshida sarcoma may degrade cartilage matrix in vivo by means of a secreted, active, inhibitor-resistant enzyme.

Hyaluronate-protein complex of rous sarcoma virus-transformed chick embryo fibroblasts.

Involvement of covalently linked protein or peptide in the structure or synthesis of hyaluronate has not previously been convincingly demonstrated. We have developed conditions for double-labeling with [3H]leucine and [14C]acetate, then isolating and characterizing the cell-associated and secreted hyaluronate-protein complexes of Rous sarcoma virus-transformed chick embryo fibroblasts. The preparations were purified by Bio-Gel A-15m gel filtration and CsCl density gradient ultracentrifugation under dissociative conditions, followed by acid agarose gel electrophoresis in the presence of 0.1% Nonidet P-40. The purified hyaluronate preparations did not change their 3H:14C ratios after further sodium dodecyl sulfate or alkali treatment. The cell-derived hyaluronate-protein was resistant to pronase but susceptible to proteinase K in the presence of sodium dodecyl sulfate. After chondroitinase ABC digestion, the cell-derived 3H-labeled protein was separated from the 14C-labeled hyaluronate disaccharides, then shown to give a broad band corresponding to Mr approximately 12,000 on sodium dodecyl sulfate-urea polyacrylamide gel electrophoresis and to be susceptible to both pronase and proteinase K. The corresponding 3H-labeled peptide was prepared in the same manner from the medium hyaluronate and the [3H]leucine shown to be present in material smaller in amount and size than that from the cell. We propose from these and other published data that the cell-associated hyaluronate-protein may be bound to the cell surface and that the hyaluronate in the medium may be derived from it as a result of proteolytic scission.

Mechanotransduction in stretched osteocytes--temporal expression of immediate early and other genes.

Osteocytes, dendritic bone cells, transduce signals of mechanical loading that results in bone formation. We have reported in stretched primary osteocytes that the cAMP level, IGF-I and osteocalcin protein levels were elevated (Endocrinology 137:2028, 1996). Here we report that stretching induces the expression of immediate early genes, c-fos, and COX-2; inducive cyclooxygenase gene. Compared to c-fos, COX-2 as well as IGF-I and osteocalcin mRNA appeared in a biphasic manner; second peaks at 8 (COX-2) or 24 hrs (IGF-I and osteocalcin) later. Furthermore, these second peaks are abolished by including NS398, a specific inhibitor of the inducive cyclooxygenase, during the 3-hr stretching. A sequence that the calcium influx activates PkA which, in turn, activates c-fos and COX-2 transcription resulting in the production of proteins such as IGF-I and osteocalcin. A long-lasting effect of mechanical loading in vivo can be explained from the secondary anabolic reaction we observed through the upregulated COX-2 mRNA.

Post-translational processing of chicken bone phosphoproteins. Identification of the bone phosphoproteins of embryonic tibia.

In order to understand the mechanism of the post-translational processing of bone phosphoproteins in embryonic bone, periosteal bone strips isolated from 12-day-embryonic-chick tibiae were cultured and the bone proteins labelled with Na2H32PO4. Of the total radiolabelled proteins recovered from the medium and bone extracts in the absence of SDS ('medium', 'EDTA extract' and 'EDTA/guanidinium chloride extract'), nearly 80% of the radioactivity was found in the EDTA extract. The three major radiolabelled phosphoproteins in the EDTA extract of apparent Mr 68,000, 63,000 and 58,000 reacted with polyclonal as well as monoclonal antibodies raised against '32-kDa' and '150-kDa' bone phosphoproteins which were derived from 14-week-old chicken. Therefore these phosphorylated embryonic proteins are identified as chicken bone phosphoproteins. Judging from their common N-terminal sequences, differences in the patterns obtained by labelling them with several radioisotopes, and slightly different amino acid compositions, these components seem to have been derived from the same original protein by sequential proteolytic cleavage and other processing such as glycosylation and phosphorylation.

Post-translational processing of chicken bone phosphoproteins. Identification of bone (phospho)protein kinase.

We have detected a protein kinase which phosphorylates bone phosphoproteins (BPPs) in the detergent extract of the membranous fractions in the periosteal bone strips of 12-day-embryonic-chick tibia. This enzyme, tentatively named BPP kinase, has a catalytic subunit of Mr approximately 39,000, utilizes GTP as well as ATP as a phospho-group donor, is inhibited by 2,3-bisphosphoglycerate and heparin, and is therefore similar to casein kinase II. The enzyme can phosphorylate dephosphorylated proteins such as casein, phosvitin and chicken BPPs, but the last-named are preferred substrates. The in vitro-phosphorylation-assay products of this enzyme in the extract were indistinguishable on an SDS/polyacrylamide gel from the major [32P]phosphoproteins metabolically labelled in the embryonic-chick bone tissue. The regulatory mechanisms of the phosphorylation process of BPPs by BPP kinase as well as the potential role of this enzyme in mineralization are discussed.