Bone formation and calcification by isolated osteoblastlike cells.

Two cell populations were isolated from calvaria of chick embryos: PF cells were liberated by collagenase treatment from the periosteum, OB cells from the periosteum-free calvarium. Both populations were cultured in plastic culture dishes. After 6 d of culture, monolayers of each cell type either were scraped off the culture dishes, transplanted on the chorio-allantoic membrane of 7-d-old quail eggs, and cultured there for 6 d, or were used for biochemical experiments. OB transplants proved capable of producing calcified bone matrix, whereas PF transplants formed only fibrous tissue. Biochemically, OB cells showed high cAMP production in the presence of parathyroid hormone (PTH), whereas cAMP production was not stimulated in PF cultures. Lactate production was stimulated by PTH in both populations although somewhat differently. Citrate decarboxylation was high in OB cells and was inhibited by PTH but was low in PF cells, where it was stimulated by the same hormone. The differences in hormonal response between the two cell types made it possible to conclude that PF cultures are relatively free of OB cells. The PF contamination in OB cultures was more difficult to assess. The experiments described in this report show that the OB population contains osteoblasts or osteoblastlike cells which are, under favorable circumstances, capable of bone formation.

Interleukin-3-dependent hematopoietic stem cell lines capable of osteoclast formation in vitro.

Recently we reported that the osteoclast originates from the pluripotent hematopoietic stem cell. However, a detailed analysis of the progenitor and precursor stages of the osteoclast lineage is hard to perform with primary cultures of stem cells. In the present investigation interleukin-3 (IL-3)-dependent multipotent hematopoietic stem cell lines (FDCP-mix), which have many characteristics in common with freshly isolated hematopoietic stem cell lines (FDCP-mix), which have many characteristics in common with freshly isolated hematopoietic stem cells, were assayed for their osteoclast formation capacity. FDCP-mix cell lines A4, C2GM, and 15S were cocultured with periosteum-free 17-day-old fetal metatarsal bones. The effects of culture time, medium composition, and addition of WEHI-3b-conditioned medium (an unpurified IL-3 preparation) on osteoclast formation were studied. 15S cells never differentiated into osteoclasts. Both A4 and C2GM cells were able to generate osteoclasts. Osteoclast formation was visualized by staining for tartrate-resistant acid phosphatase activity and confirmed by 45Ca release assays and electron microscopic studies. Medium supplemented with fetal calf serum clearly supported osteoclast formation from A4 cells better than medium supplemented with cock serum. The difference between fetal calf serum and horse serum is generally less pronounced. C2GM cells formed osteoclasts more readily and, generally, earlier than A4 under all culture conditions. WEHI-3b-conditioned medium addition increased the numbers of osteoclasts and their resorption activity. The coculture of stripped metatarsal bones with FDCP-mix cell lines therefore offers a model system with many possibilities for the study of osteoclastogenesis and its regulation.

Comparison of direct and indirect radiation effects on osteoclast formation from progenitor cells derived from different hemopoietic sources.

Hemopoietic stem and progenitor cells from different sources differ in radiosensitivity. Recently, we have demonstrated that the multinucleated cell responsible for bone resorption and marrow cavity formation, the osteoclast, is in fact of hemopoietic lineage. In this investigation we have studied the radiosensitivity of osteoclast formation from two different hemopoietic tissues: fetal liver and adult bone marrow. Development of osteoclasts from hemopoietic progenitors was induced by coculture of hemopoietic cell populations with fetal mouse long bones depleted of their own osteoclast precursor pool. During culture, osteoclasts developed from the exogenous cell population and invaded the calcified hypertrophic cartilage of the long bone model, thereby giving rise to the formation of a primitive marrow cavity. To analyze the radiosensitivity of osteoclast formation, either the hemopoietic cells or the bone rudiments were irradiated before coculture. Fetal liver cells were found to be less radiosensitive than bone marrow cells. The D0, Dq values and extrapolation numbers were 1.69 Gy, 5.30 Gy, and 24.40 for fetal liver cells and 1.01 Gy, 1.85 Gy, and 6.02 for bone marrow cells. Irradiation of the (pre)osteoclast-free long bone rudiments instead of the hemopoietic sources resulted in a significant inhibition of osteoclast formation at doses of 4 Gy or more. This indirect effect appeared to be more prominent in the cocultures with fetal than with adult hemopoietic cells. Furthermore, radiation doses of 8.0-10.0 Gy indirectly affected the appearance of other cell types (e.g., granulocytes) in the newly formed but underdeveloped marrow cavity. The results indicate that osteoclast progenitors from different hemopoietic sources exhibit a distinct sensitivity to ionizing irradiation. Radiation injury to long bone rudiments disturbs the osteoclast-forming capacity as well as the hemopoietic microenvironment.

Radiation-induced changes in the cell membrane of cultured human endothelial cells.

We investigated the effect of irradiation on the kinetic characteristics of amino acid and glucose transport, and the effect on the activity of the cell membrane-bound enzyme 5'-nucleotidase and on the receptor-mediated stimulation of cyclic adenosine monophosphate synthesis by prostaglandin E1. Irradiation inhibited the sodium-dependent amino acid transport by a reduced binding of the amino acid to the transport unit. The transport of glucose, which appeared to be a sodium-independent process, was temporarily stimulated by increased maximal velocity of the transport. No effect was found on the binding to the transport unit. Irradiation increased the 5'-nucleotidase activity and decreased the prostaglandin E1-stimulated cyclic adenosine monophosphate synthesis 48 h after exposure to 20 Gy. It is concluded that irradiation decreases sodium-dependent transport by impairment of the transport unit, does not impair a sodium-independent process, and has opposite effects on membrane-bound enzyme activity and a receptor-mediated process.

Direct and indirect radiation effects on osteoclast formation in vitro.

An in vitro co-culture system was applied to study the direct and indirect effects of irradiation on osteoclast formation. Osteoclast precursor-free fetal mouse metatarsal bones were employed as osteoclast-forming inductor and periostea dissected from fetal calvaria as source of proliferating progenitor cells. Direct radiation effects on the formation of osteoclasts were assessed in co-cultures of irradiated periostea and non-irradiated bone rudiments. The results showed that the (blood-borne) periosteal progenitors were rather radiosensitive. A radiation 'survival' curve of osteoclast formation in relation to various doses could be constructed yielding a mean lethal dose (Do value) of 0.94 +/- 0.02 Gy and an extrapolation number of 1.67 +/- 0.01. Irradiation of the fetal long bones by low doses, effective for direct elimination of osteoclast progenitor cells, did not indirectly affect osteoclast development from the non-irradiated periosteal progenitor population. However, at relatively high radiation levels, though not lethal for the long bone rudiments, a significant inhibition of osteoclast formation became evident. The results indicate that radiation primarily affects osteoclast formation via a direct action on radiosensitive, proliferating progenitor cells. Injury to long bone models by relatively high radiation doses may also lead to severe disturbance of osteoclast formation kinetics.

Alkaline phosphatase and calcification, correlated or not?

The effects of alkaline phosphatase inhibitors (levamisole, L-bromotetramisole) on the activity of the enzyme and on calcification in vitro were studied, to find out whether there is a relationship between alkaline phosphatase and calcification. Metatarsal bones of 15 1/4-day-old embryonic mice were dissected and cultured for 40 hours in the presence and absence of inhibitor. Levamisole and L-bromotetramisole fully inhibited calcification in vitro when present in concentrations which almost totally inhibited alkaline phosphatase activity, as measured biochemically or histochemically. However, incorporation of 3H-thymidine and 35S-sulphate was also inhibited. Furthermore, D-bromotetramisole, the dextroform of bromotetramisole which has no effect on alkaline phosphatase, inhibited calcification and 3H-thymidine and 35S-sulphate incorporation as well. The results of this study show that these inhibitors cannot be used to study the relationship between alkaline phosphatase and calcification. In addition, they suggest that although alkaline phosphatase may be important for the process of calcification, it is probably not a critical factor.

Differentiation kinetics of osteoclasts in the periosteum of embryonic bones in vivo and in vitro.

Osteoclast progenitors are seeded via the blood stream in the mesenchyme surrounding embryonic long bone models long before the appearance of multinucleated osteoclasts. The proliferation and differentiation of these progenitors in embryonic mouse metatarsal bones was studied with acid phosphatase (AcP) histochemistry and 3H-thymidine autoradiography. In vivo, tartrate-resistant, acid phosphatase-positive, mononuclear cells appear in the periosteum (AcPP-P cells) at the age of 17 days (after conception). On day 18, AcP-positive, multinucleated osteoclasts invade the bone rudiment and start resorbing the calcified cartilage matrix, resulting in the formation of the marrow cavity. The kinetics of osteoclast formation in vitro was studied in metatarsal bones of embryonic mice of different ages cultured in the continuous presence of 3H-thymidine. In young bones (15 days), mainly proliferating, 3H-thymidine-incorporating progenitors gave rise to AcPP-P cell and osteoclast formation. In older bones (16 and 17 days) osteoclasts were progressively more derived from postmitotic, unlabeled precursors. Irradiation of the metatarsal bones with a radiation dose of 5.0 Gy prior to culture resulted in a selective elimination of the proliferating progenitors, whereas the contribution of postmitotic precursors in AcPP-P cell and osteoclast formation remained unchanged. The results demonstrate that in the periosteum of embryonic metatarsal bones a shift occurs from a population composed of proliferating osteoclast progenitors (15 days) to a population composed of postmitotic precursors (17 days) before multinucleated osteoclasts are formed (18 days). Obviously, postmitotic AcP-negative precursors, already present in 16-day-old bones, differentiate into precursors characterized by tartrate-resistant AcP activity, the preosteoclasts (17 days), which in their turn fuse into osteoclasts.

Murine macrophage precursor cell lines are unable to differentiate into osteoclasts: a possible implication for osteoclast ontogeny.

Six murine macrophage precursor cell lines, thought to be arrested around the CFU-GM stage of the myeloid differentiation and shown to be negative for acid phosphatase, F4/80 antigen expression and phagocytosis capacity, were tested for their ability to differentiate into osteoclasts. Their differentiation potential was compared with that of the haemopoietic stem cell line FDCP-mix C2GM. None of the macrophage precursor cell lines could be induced to differentiate into osteoclasts when the cells were cocultured with either periosteum-free metatarsal bones of fetal mice, or monolayers of osteoblast-like cells. In contrast, when the haemopoietic stem cell line FDCP-mix C2GM, murine fetal liver cells or murine spleen cells were used as a source of haemopoietic precursor cells, numerous osteoclasts were formed in both culture systems. During cell culture a small percentage of the macrophage precursor cells attached to the bottom of the culture well. These firmly attached cells acquired acid phosphatase activity, F4/80 antigen expression and phagocytosis capacity. Furthermore, when the cell lines were cultured for 2 or 4 days with 1% DMSO, up to 30% of the precursor cells differentiated into metamyelocytes. These results suggest that the macrophage precursor cell lines are able to acquire macrophage and granulocyte characteristics, but are unable to differentiate into osteoclasts. In contrast, the haemopoietic stem cell line FDCP-mix C2GM is able to differentiate into both macrophages and osteoclasts. We therefore suggest that the osteoclast lineage branches off at an early stage of the myeloid differentiation pathway.

The role of osteoblast density and endogenous interleukin-6 production in osteoclast formation from the hemopoietic stem cell line FDCP-MIX C2GM in coculture with primary osteoblasts.

Osteoclast formation from the hemopoietic stem cell line FDCP-mix C2GM was shown to be strongly dependent on osteoblast density. In cocultures of C2GM cells with fetal mouse osteoblasts seeded at high density (i.e., 2.5 x 10(4) cells/cm2), we found a significantly lower osteoclast formation compared with cocultures with osteoblasts seeded at low density (i.e., 1 x 10(4) cells/cm2). The differentiation state of osteoblasts in high-density cultures resembled more than that of osteoblasts in low-density cultures, the differentiation state of mature osteoblasts, since the cells in the former cultures showed higher alkaline phosphatase (APase) activity than the cells in the latter cultures, and nodules were formed in high-density cultures but not in low-density cultures. Endogenous interleukin-6 (IL-6) production was found to be significantly lower in high-density cultures, which may partly explain the impaired osteoclast formation in high-density cocultures. Addition of IL-6 to the high-density cocultures indeed restored osteoclast formation. There appeared to be no overt difference in IL-6 receptor mRNA expression between high-density and low-density cultures. In conclusion, this paper suggests that mature, highly differentiated osteoblasts are not directly involved in osteoclastogenesis. In contrast, osteoblast-like cells lacking mature osteoblast markers induce osteoclast formation. Whether these low-density osteoblast-like cells represent an immature differentiation state or the lining cell phenotype is unclear.

Effects of ionizing irradiation on formation and resorbing activity of osteoclasts in vitro.

The effects of ionizing irradiation on the differentiation and activity of the osteoclast were investigated. Embryonic mouse metatarsal bones of different ages (14, 15, 16, 17 days) in which no osteoclasts had as yet been formed were irradiated with various x-ray doses and cultured until a marrow cavity became visible in the nonirradiated paired control bones. Bone growth and calcification were followed microscopically during culture. Irradiation caused a dose-dependent stunting of the longitudinal growth. Calcification was inhibited by high radiation doses (10 to 20 Gray (Gy), whereas a dose of 2.5 Gy stimulated the process in the early stages of long bone development. Histologic examination revealed complete inhibition of osteoclast formation in the 14- and 15-day-old bones after irradiation with 2.5 Gy or more. The number of osteoclasts in cultured older bones (16 days) was significantly reduced by irradiation, but osteoclast formation could not be completely prevented even by high dosages. Irradiation of explanted bone rudiments which were in a stage 1 day prior to the appearance of osteoclasts in vivo (17 days) did not significantly influence the formation of osteoclasts. Autoradiographic experiments using young bones showed that differentiation of osteoclast precursors into multinucleated osteoclasts is preceded by one or more divisions of the precursors in the periosteum. Furthermore, it was established from continuous 3H-thymidine-labeling experiments that in older bones (16 days) a part of the osteoclast nuclei originated from postmitotic osteoclast precursors. Irradiation mainly inhibited the appearance of labeled osteoclast nuclei in these bones. The results indicate that the osteoclast precursor, already present in the periosteum at an early stage of embryonic development, first proliferates and then differentiates into a mononuclear postmitotic preosteoclast. The proliferation is probably highly radiosensitive. Subsequently, the preosteoclasts fuse into multinucleated osteoclasts and invade the calcified hypertrophic cartilage zone. The resorbing activity of the osteoclast is less radiosensitive but can be inhibited by 5.0 Gy or more, as was established by morphometric and biochemical methods.

Osteoclast development in the coculture system of periostless metatarsal bones and hemopoietic cells studied by in situ hybridization with a probe for Y chromosomes.

In the coculture system of periostless metatarsal bones of 17-day-old fetal mice and osteoclast progenitors, osteoclasts will develop. Our goal in the present report was to provide further evidence that in the coculture system of fetal metatarsal bone rudiments with hemopoietic cells, the osteoclasts developing inside the bone rudiments are exclusively derived from the cells suspended in the plasma clot and not from endogenous precursor cells of the bone explants themselves, by using the technique of in situ hybridization with a probe for the mouse Y chromosome. Osteoclast formation in unstripped male metatarsal rudiments, occurring after 3-4 days of culture, was compared with osteoclast formation in cocultures of female metatarsal rudiments and male bone marrow cells, occurring after 5-6 days of culture. Osteoclasts were recognized by their tartrate-resistant acid phosphatase activity. In paraffin sections of cultured male metatarsals, the mean percentage of microscopically identifiable osteoclast nuclei, in which the Y chromosome could be detected, was 43.1 +/- 4.2% (n = 12). For cocultures of female metatarsal bones and male bone marrow cells this mean percentage was 40.9 +/- 5.7% (n = 17). Statistical comparison by means of the two sample t-test indicated no significant difference in the percentages of osteoclast nuclei containing the Y chromosome for both groups. We concluded that the osteoclasts do derive from cocultured cells and not from precursor cells in the bone explant itself.(ABSTRACT TRUNCATED AT 250 WORDS)

Osteoclast formation from cloned pluripotent hemopoietic stem cells.

In the present report osteoclast formation from cloned pluripotent hemopoietic stem cells (PHSC) is described. Populations enriched in hemopoietic stem cells were cloned (1 cell/well) and cultured in the presence of different colony-stimulating factors, or combinations of these growth factors. In cultures containing interleukin-3 (Il-3) or pregnant mouse uterus extract (PMUE) alone, cloning efficiency was low. Cultures containing Il-3 and Il-1 or Il-3 and PMUE showed a somewhat higher cloning efficiency, whereas cultures containing Il-3, Il-1 and PMUE had the highest cloning efficiency. All colonies of cloned PHSC, tested for their osteoclast formation capability in cocultures with periosteum-free metatarsal bones of fetal mice, gave rise to osteoclast formation. Other hemopoietic cells could also be demonstrated. In control cultures in which the bones were kept without stem cells, no osteoclast formation was observed. In conclusion, we have demonstrated that the osteoclast is derived from the pluripotent hemopoietic stem cell. A combination of various growth factors is important for stem cell proliferation in vitro.