Takuhiko Akatsu

Macrophage colony-stimulating factor is indispensable for both proliferation and differentiation of osteoclast progenitors.

The mechanism of action of macrophage colony-stimulating factor (M-CSF) in osteoclast development was examined in a co-culture system of mouse osteoblastic cells and spleen cells. In this co-culture, osteoclast-like multinucleated cells (MNCs) were formed within 6 d in response to 10 nM 1 alpha,25(OH)2D3 added only for the final 2 d of culture. Simultaneously adding hydroxyurea for the final 2 d completely inhibited proliferation of cultured cells without affecting 1 alpha,25(OH)2D3-stimulated MNC formation. Autoradiographic examination using [3H]-thymidine revealed that osteoclast progenitors primarily proliferated during the first 4 d, whereas their differentiation into MNCs occurred predominantly during the final 2 d of culture in response to 1 alpha,25(OH)2D3. When anti-M-CSF antibody or anti-M-CSF receptor antibody was added either for the first 4 d or for the final 2 d, the MNC formation was similarly inhibited. In co-cultures of normal spleen cells and osteoblastic cells obtained from op/op mice, which cannot produce functionally active M-CSF, the lack of M-CSF either for the first 4 d or for the final 2 d failed to form MNCs in response to 1 alpha,25(OH)2D3 added for the last 2 d. These results clearly indicate that M-CSF is indispensable for both proliferation of osteoclast progenitors and their differentiation into mature osteoclasts.

Bisphosphonates act on osteoblastic cells and inhibit osteoclast formation in mouse marrow cultures

We examined the mode of action of bisphosphonates on osteoclastic cell recruitment using mouse marrow cultures with or without osteoblastic cells. Tartrate-resistant acid phosphatase-positive multinucleated cells [TRAP(+)MNC] formed in cultures were determined to be osteoclastic cells. In marrow cultures, TRAP(+) MNC formation in the presence of 10(-8) mol/L 1,25(OH)2D3 was not affected by the addition of 10(-6) mol/L dihydrogen (cycloheptylamino)-methylenebisphosphonate monohydrate (YM175). However, it was inhibited in cocultures of marrow cells with osteoblastic cells. The inhibitory effect was evident throughout the entire culture period. YM175 dose dependently inhibited TRAP(+) MNC formation, and other bisphosphonates--pamidronate and alendronate--also inhibited TRAP(+) MNC formation in the coculture. Similar observations were also made in the coculture of spleen cells with osteoblastic cells. The conditioned media of osteoblastic cells treated with 10(-6) mol/L YM175 inhibited TRAP(+) MNC formation in marrow cultures. The presence of YM175 in methylcellulose cultures affected neither the colony formation of monocyte-macrophage lineage, nor TRAP(+) MNC formation in the succeeding cocultures of recovered cells with osteoblastic cells. These results indicate that YM175 and probably other bisphosphonates as well preferentially inhibit the later stage of osteoclastogenesis through its action on osteoblastic cells. Our findings suggest that part of the inhibitory action by osteoblastic cells in the presence of bisphosphonates is mediated through soluble factor(s).

Osteoclastogenesis inhibitory factor exhibits hypocalcemic effects in normal mice and in hypercalcemic nude mice carrying tumors associated with humoral hypercalcemia of malignancy.

Osteoclastogenesis inhibitory factor (OCIF) is a novel secreted protein that inhibits osteoclastogenesis both in vitro and in vivo. In this study, we examined the effects of OCIF on serum calcium (Ca) concentrations in normal mice and in hypercalcemic nude mice carrying tumors associated with humoral hypercalcemia of malignancy. In normal mice, a single intraperitoneal injection of OCIF reduced serum Ca levels in a dose-dependent manner. Significant decrease in serum Ca (by 1.6 +/- 0.3 mg/dL, n = 5) was observed 2 h after the injection of OCIF at 20 mg/kg and the hypocalcemic effect continued for up to 12 h. Serum phosphate (Pi) concentrations also decreased in response to OCIF. Urinary excretion of Ca, Pi, and creatinine did not change significantly after injection of OCIF or vehicle. In hypercalcemic, tumor-bearing nude mice, a single intraperitoneal injection of OCIF at 20 mg/kg resulted in a dramatic decrease in serum Ca (maximal decrease 2.8 +/- 0.37 mg/dL, n = 11), which continued for up to 24 h. The results suggest that OCIF decreased serum Ca through its inhibitory effect on bone resorption. Furthermore, it is suggested that OCIF has therapeutic potential for the treatment of hypercalcemic conditions such as malignancy-associated hypercalcemia.

HYPOCALCEMIC EFFECT OF OSTEOCLASTOGENESIS INHIBITORY FACTOR/OSTEOPROTEGERIN IN THE THYROPARATHYROIDECTOMIZED RAT

Osteoclastogenesis inhibitory factor (OCIF), also termed as osteoprotegerin (OPG), is a soluble member of the tumor necrosis factor receptor family. Although OCIF/OPG is shown to inhibit osteoclast formation in vitro and prevent ovariectomy-induced bone loss in vivo, its effect on serum calcium level remains to be determined. In this study we examined the acute effect of OCIF on thyroparathyroidectomized rats whose serum calcium concentrations were raised either by exogenous PTH or 1,25-(OH)2D3. When OCIF was administered at the start of PTH infusion, it attenuated the initial rise in serum calcium. When OCIF was administered into rats with established hypercalcemia, it decreased serum calcium rapidly (within 2 hr) and dramatically. OCIF did not increase urinary calcium excretion. These findings, especially the rapid onset of its hypocalcemic effect, suggest that OCIF not only inhibits the formation of osteoclasts but also affects the function and/or survival of mature osteoclasts at doses used in this study.

Involvement of cyclo-oxygenase-2 in osteoclast formation and bone destruction in bone metastasis of mammary carcinoma cell lines.

We previously reported that mouse mammary carcinoma cell lines (MMT060562 and BALB/c‐MC) induced osteoclast formation through production of prostaglandin E2 (PGE2) in cocultures with mouse bone marrow cells, but the mechanism(s) of PG production remained unclear. In the present in vitro and in vivo studies, we tested the involvement of cyclo‐oxygenase‐2 (COX‐2), an inducible rate‐limiting enzyme in PG biosynthesis, in the stimulation of osteoclast formation by mouse mammary carcinoma cell lines. Addition of a selective COX‐2 inhibitor, JTE‐522, to cocultures of mammary carcinoma cell lines and bone marrow cells lowered PGE2 concentration in the culture media and inhibited osteoclast formation in a dose‐dependent manner. Northern blotting showed a very high level of COX‐2 messenger RNA (mRNA) expression in MMT060562. The mRNA expression was low in BALB/c‐MC, but it increased when BALB/c‐MC and bone marrow cells were cocultured. The results of immunocytochemistry for COX‐2 protein in respective cultures were compatible with the results of COX‐2 mRNA. In vivo, BALB/c‐MC injected into the heart of Balb/c mice metastasized to bone and formed osteolytic lesions in their hindlimbs. Histological examination revealed that tumor cells had metastasized to the bone marrow cavity and destroyed the bone trabeculae. Immunohistochemistry demonstrated that bone marrow stromal cells adjacent to tumor cells expressed COX‐2 protein. These findings suggest that COX‐2 plays an important role in the osteolysis of bone metastasis in vivo as well as in osteoclast formation in cocultures used as an in vitro model of metastatic bone disease.

Biphasic Effect of Prostaglandin E2 on Osteoclast Formation in Spleen Cell Cultures: Role of the EP2 Receptor†

We examined the effect of PGE2 on OC formation from spleen cells treated with M‐CSF and RANKL. PGE2 decreased OC number at 5–6 days of culture and increased OC number, size, and resorptive activity at 7–8 days. A selective EP2 receptor agonist mimicked these effects. Deletion of the EP2 receptor or depletion of T‐cells abrogated the increase in OC number.

Lack of bone resorption in osteosclerotic (oc/oc) mice is due to a defect in osteoclast progenitors rather than the local microenvironment provided by osteoblastic cells

In a co-culture system of mouse spleen cells and osteoblastic cells, we have demonstrated that a suitable microenvironment must be provided by osteoblastic cells in order for osteoclast-like multinucleated cell (MNC) formation. Using this co-culture system, we examined the pathogenetic mechanism underlying the lack of bone resorption in osteosclerotic oc/oc mice. Numerous tartrate-resistant acid phosphatase (TRAP, an osteoclast marker enzyme)-positive MNCs were formed in response to 1 alpha,25-dihydroxyvitamin D3 [1 alpha,25(OH)2D3] both in co-cultures of oc/oc spleen cells and normal osteoblastic cells and in those of normal spleen cells and oc/oc osteoblastic cells. TRAP-positive MNCs derived from normal spleen cells tended to spread out on culture dishes, whereas those from oc/oc spleen cells remained as small, compact MNCs. When TRAP-positive MNCs enriched from co-cultures of normal spleen cells and oc/oc osteoblastic cells were cultured on dentine slices, they formed numerous resorption pits with ruffled borders and clear zones. In contrast, none of the TRAP-positive MNCs derived from oc/oc spleen cells formed either ruffled borders or resorption pits. These results indicate that the lack of bone resorption in oc/oc mice is due to a defect in osteoclast progenitors rather than the local microenvironment provided by osteoblastic cells.

The effect of deletion of cyclooxygenase-2, prostaglandin receptor EP2, or EP4 in bone marrow cells on osteoclasts induced by mouse mammary cancer cell lines1

The inducible prostaglandin (PG) synthesis enzyme, cyclooxygenase-2 (COX-2), is involved in osteoclast (OC) formation in cocultures of mouse mammary cancer cell lines (MMT060562 or BALB/c-MC) and bone marrow cells through production of PGE(2). There are four PGE(2) receptors but only the EP2 and EP4 receptors are reported to be important for OC formation. We have investigated the role of COX-2, EP2 receptor, and EP4 receptor in marrow cells for osteoclastogenesis in cocultures of cancer cells and bone marrow cells. We cocultured cancer cell lines with bone marrow cells from COX-2 knockout (-/-), EP2 -/- or EP4 -/- mice compared to wild-type mice. In addition, an EP4 receptor antagonist (EP4 RA) was added in some cocultures. Disruption of COX-2 gene in bone marrow cells had no effect on PGE(2) production and OC formation in cocultures with MMT060562, while it abrogated PGE(2) production and OC formation in cocultures with BALB/c-MC. Disruption of the EP2 gene in bone marrow cells had no effect on OC formation in the cocultures, while disruption of the EP4 gene in bone marrow cells abrogated OC formation in the cocultures. Furthermore, EP4 RA suppressed OC formation and prevented the increase in receptor activator of nuclear factor kappaB ligand (RANKL) mRNA levels in the cocultures. We conclude that COX-2 in cancer cells is responsible for PGE(2) and OC production in cocultures with MMT060562, while COX-2 in bone marrow cells, not cancer cells, is responsible for PGE(2) and OC production in cocultures with BALB/c-MC, and EP4 receptors are essential for OC formation in both cocultures.

A Third‐Generation Bisphosphonate, YM175, Inhibits Osteoclast Formation in Murine Cocultures by Inhibiting Proliferation of Precursor Cells via Supporting Cell‐Dependent Mechanisms

The theory that bisphosphonates inhibit osteoclast formation through their effects on osteoblastic cells remains controversial. To confirm the inhibitory effect of bisphosphonates on osteoclast formation and gain some insights into the underlying mechanisms, we examined the effect of disodium dihydrogen (cycloheptylamino)‐methylenebisphosphonate monohydrate (YM175) on osteoclast‐like multinucleated cell (OCL) formation in various mouse coculture systems. When different origins of osteoclast precursors (bone marrow, spleen, or nonspecific esterase‐positive cells) were cocultured with the same supporting cells (calvarial osteoblasts), YM175 inhibited OCL formation similarly in all cultures. When the same osteoclast precursors (spleen cells) were cocultured with supporting cells of different origin, the results were variable. YM175 inhibited OCL formation almost completely in cocultures with calvarial osteoblasts or osteoblastic cell line KS4, while it did not, or only slightly, inhibit OCL formation in cocultures with stromal cell lines, ST2 or MC3T3‐G2/PA6. Temporal addition of YM175 in cocultures of spleen cells with osteoblastic cells revealed that YM175 was effective when it was present at an early phase of the culture period. Consistent with this observation, YM175 in the presence of osteoblastic cells inhibited proliferation of preosteoclastic cells, but did not inhibit the fusion of mononuclear prefusion osteoclasts. In conclusion, the inhibitory effect of YM175 on OCL formation was confirmed in various murine coculture systems, but the effect was dependent on the types of bone‐derived cells supporting osteoclastogenesis. The findings suggest that YM175 inhibits osteoclastogenesis by inhibiting the proliferation of osteoclast precursors through its action on supporting cells of osteoblast lineage rather than acting directly on osteoclast precursors.

Mouse mammary carcinoma cell line (BALB/c-MC) stimulates osteoclast formation from mouse bone marrow cells through cell-to-cell contact

We recently reported that numerous osteoclasts (OC) were formed in cocultures of some mouse cancer cell lines and bone marrow cells. In this study, we examined mechanisms by which one of the cell lines, BALB/c-MC, induces OC. BALB/c-MC dose dependently stimulated OC formation in cocultures. In cocultures where direct cell-to-cell contact between BALB/c-MC and bone marrow cells was inhibited by membrane filters, OC formation was not stimulated. The stimulation of OC formation in the coculture was completely abolished by adding 10(-7)-10(-6) mol/L indomethacin. The concentration of prostaglandin E2 (PGE2) in the culture media of cocultures with cell-to-cell contact was higher than that of cocultures without cell-to-cell contact or marrow cultures alone, and it reached levels sufficient to induce OC (11.9 +/- 5.3 ng/mL [about 3.4 x 10(-8) mol/L]). When BALB/c-MC or bone marrow cells were fixed with formalin and then cocultured with bone marrow cells or BALB/c-MC, respectively, the concentration of PGE2 in the culture media of cocultures of fixed BALB/c-MC and bone marrow cells increased, whereas that of cocultures of BALB/c-MC and fixed bone marrow cells did not increase. These results indicate that BALB/c-MC stimulate OC formation through direct cell-to-cell contact with bone marrow cells, and PGE2 released from bone marrow cells through direct cell-to-cell contact are involved in OC formation by the cell line.