Osteoclast formation from mononuclear phagocytes: role of bone-forming cells.

In a previous study, using co-cultures of embryonic bone rudiments stripped of periosteum, and mononuclear phagocytes of various sources, we found that multinucleated mineral-resorbing osteoclasts developed in vitro from radiosensitive mouse bone marrow mononuclear phagocytes (BMMP). (Burger, E. H., J. W. M. van der Meer, J. S. van de Gevel, C. W. Thesingh, and R. van Furth, 1982, J. Exp. Med. 156:1604-1614). In the present study, this co-culture technique was used to analyze the influence of bone-forming cells on osteoclast formation and bone resorption by BMMP or peritoneal exudate cells (PEC). BMMP or PEC were co-cultured with liver or dead bone, i.e., in the presence or absence of liver bone-forming cells. Mineral resorption and osteoclast formation were monitored via 45Ca release from prelabeled live or dead bone followed by histology. Osteoclasts developed from precultured BMMP as indicated by [3H]thymidine labeling, but only in live and not in dead bone. They formed readily from BMMP but only erratically, and after a longer culture period, from PEC. Macrophages from BMMP and PEC invaded live and dead bone rudiments but did not resorb the intact mineralized matrix. In contrast, ground bone powder was resorbed avidly by both cell populations, without formation of osteoclasts. We conclude that live bone-forming cells are required for osteoclast formation from progenitors. Live bone is only resorbed by osteoclasts, and not by macrophages. Osteoclast progenitors are abundant in cultures of BMMP but scarce in PEC, which makes a direct descendance of osteoclasts from mature macrophages unlikely.

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.

A Ca(2+)-dependent K(+)-channel in freshly isolated and cultured chick osteoclasts.

Calcium-activated potassium channels were found in embryonic chick osteoclasts using the patch-clamp technique. The activity of the channel was increased by both membrane depolarisation and an increase in intracellular Ca2+ concentration in the range 10(-5) to 10(-3) M. In the cell-attached-patch configuration the channel was only active at extreme depolarising potentials. Ca2+ addition to the cytoplasm via ionomycin increased channel activity at the resting membrane potential of the osteoclast. The channel had a single-channel conductance of 150 pS in the inside-out patch under symmetrical K+ conditions (150 mM) and was selective for potassium ions. During sustained application of increased [Ca2+] at the cytoplasmic side of inside-out patches, channel activity sometimes decreased again after the initial increases (desensitization). The results established the properties of the single channels underlying an outward rectifying K+ conductance in chick osteoclasts described previously by us.

Removal of hematopoietic cells and macrophages from mouse bone marrow cultures: isolation of fibroblastlike stromal cells.

A method is described that permits the removal of hematopoietic cells and macrophages from mouse bone marrow cultures. The method is based on the difference in effect of extracellular ATP4- ions (ATP in the absence of divalent, complexing cations) on cells of hematopoietic origin, including macrophages, and of nonhematopoietic origin, such as fibroblastlike stromal cells. In contrast to fibroblastlike cells, hematopoietic cells and macrophages form under the influence of ATP4- lesions in their plasma membranes, which allows the entrance of molecules such as ethidium bromide (EB) and potassium thiocyanate (KSCN), which normally do not easily cross the membrane. The lesions can be rapidly closed by the addition of Mg2+ to the incubation medium, leaving the EB or KSCN trapped in the cell. This method allows the selective introduction of cell-toxic substances such as KSCN into hematopoietic cells and macrophages. By using this method, fibroblastlike stromal cells can be isolated from mouse bone marrow cultures.

Isolation and purification of osteocytes.

An isolation method for osteocytes is described. After removal of the periostea, bone cells were isolated from calvariae of 18-day-old chicken embryos by alternating treatments with collagenase and EDTA. Osteocytes were purified from the heterogeneous bone cell population with the help of the osteocyte-specific MAb OB 7.3 bound to protein G-conjugated magnetic beads. The purity of the osteocyte population ultimately obtained was more than 95%. Osteocytes were found to adhere rapidly to glass or plastic substrates. They showed numerous processes of various types. These processes could branch and make contact with those of other osteocytes. After 1-2 days of culture, the isolated osteocytes formed a network of apparently interconnected cell processes very similar to the osteocyte network in bone.

High-conductance anion channels in embryonic chick osteogenic cells.

Patch-clamp measurements done on excised membrane patches obtained from 1-5 day cultured embryonic chick osteoblasts, osteocytes, and periosteal fibroblasts revealed the existence of a high-conductance anion channel: 371 +/- 63 pS when measured under symmetrical 158 mM Cl- conditions. The channel frequently displayed subconductance levels. The ion selectivity of the channel expressed as the (an)ion to chloride permeability ratio was as follows: Cl- (1.0) greater than methylsulfate- (0.71) greater than gluconate- (0.25) greater than glutamate- (0.17) greater than Na+ = K+ (0.10). In addition, the channel had a significant permeability for inorganic phosphate ions. The channel was found in about 1% of the cell-attached patches, which indicates that the channel is under the control of as yet unknown intracellular factors. Once activated by patch excision, the channel was voltage dependent and active at potentials close to 0 mV. At potentials outside the range of +/- 10 mV channel activity decreased. This process proceeded faster at increasing membrane potentials of either polarity. Returning to potentials close to 0 mV caused reopening of the channels within seconds if the preceding voltage step led to complete closure of the channels. Channel activity did not depend noticeably on intracellular and extracellular CA2+ ions. The channel is not unique to (chick) osteogenic cells but has been demonstrated in excised patches obtained from excitable and other nonexcitable cells. Although its presence in a wide variety of cell types suggests that the channel plays a general role in as yet unknown cell physiologic processes, the channel may also have specific functions in osteogenic cells, for example providing a pathway for phosphate ions during mineralization.

Identification of Ca(2+)-activated K+ channels in cells of embryonic chick osteoblast cultures.

Primary cultures of embryonic chick osteoblasts consist of a heterogeneous cell population. Patch clamp measurements were done on 1- to 5-day-old osteoblasts, osteocytes, fibroblastlike cells, and cells that could not be classified on morphologic criteria. The measurements showed the omnipresence of depolarization-activated high-conductance channels in cell-attached patches. The whole-cell experiments showed an outward rectifying conductance activating at positive membrane potentials. Channels underlying the latter conductance were found to be K+ conducting in outside-out membrane patches. The activation potential of the outward rectifying K+ conductance shifted to negative membrane potentials upon increasing the intracellular Ca2+ concentration within the range of 10(-8)-10(-3.2) M. The same happened with the activation potential of the K+ channels found in outside-out patches. Finally, inside-out patch experiments directly demonstrated the dependency of the activation potential of K+ channels on Ca2+ ions. Thus the identity and main characteristics of Ca2(+)-activated K+ channels expressed by the various cell types present in chick osteoblast cultures have now been established. Decreased input resistances were found in cells of cultures more than 2 days old. This is consistent with the establishment of electrical coupling between the cells. Functions in which Ca2(+)-activated K+ channels could play a role are discussed.

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.

Voltage, calcium, and stretch activated ionic channels and intracellular calcium in bone cells.

Embryonic chick bone cells express various types of ionic channels in their plasma membranes for as yet unresolved functions. Chick osteoclasts (OCL) have the richest spectrum of channel types. Specific for OCL is a K+ channel, which activates (opens) when the inside negative membrane potential (Vm) becomes more negative (hyperpolarization). This is consistent with findings of others on rat OCL. The membrane conductance constituted by these channels is called the inward rectifying K+ conductance (GKi), or inward rectifier, because the hyperpolarization-activated channels cause cell-inward K+ current to pass more easily through the membrane than outward K+ current. Besides GKi channels, OCL may express two other types of voltage-activated K+ channels. One constitutes the transient outward rectifying K+ conductance (GKto), which is activated upon making the membrane potential less negative (depolarization) but has a transient nature. This conductance favors transient K+ conduction in the cell-outward direction. The GKto also occurs in a small percentage of cells in osteoblast (OBL) and periosteal fibroblast (PFB) cultures. The other OCL K+ conductance, the GKCa, is activated by both membrane depolarization and a rise in [Ca2+]i. GKCa channels are also present in the other chick bone cell types, that is, OBL, osteocytes (OCY), and PFB. Furthermore, in excised patches of all bone cell types, channels have been found that conduct anions, including Cl- and phosphate ions. These channels are only active around Vm = 0 mV. While searching for a membrane mechanism for adaptation of bone to mechanical loading, we found stretch-activated channels in chick osteoclasts; other investigators have found stretch-activated cation channels (K+ or aselective) in rat and human osteogenic cell lines. In contrast to other studies on cell lines or OBL from other species, we have not found any of the classic macroscopic voltage-activated calcium conductances (GCa) in any of the chick bone cells under our experimental conditions. However, our fluorescence measurements of [Ca2+]i in single cells indicate the presence of Ca2+ conductive pathways through the plasma membrane of osteoblastic cells and osteoclasts, consistent with other studies. We discuss possible roles for GKi, GKCa, and anion channels in acid secretion by OCL and for stretch-activated channels in OCL locomotion.

Characteristics and properties of osteocytes in culture.

Although the osteocyte is the most abundant among the highly differentiated cells of mature bone (osteocytes, lining cells, osteoblasts, and osteoclasts), its properties and functions are the least known and understood. Here we isolated osteocytes from mixed populations of bone cells liberated from fetal chick calvariae by alternate treatments with collagenase and EDTA. The osteocytes were removed from the bone cell populations by binding them via an osteocyte-specific antibody (MAb OB 7.3) to magnetic beads and removing the beads together with the coupled osteocytes from the population using a magnet. Isolated osteocytes were found to be highly differentiated, postmitotic cells that required their typical stellate morphology in culture. Osteocyte populations had alkaline phosphatase (ALP) activity somewhat lower than that of the osteoblast-like cell populations from which they were separated by the immunodissection procedure. On the single-cell level, the ALP activity was highly variable. Parathyroid hormone (PTH) receptors were found to be present on osteocytes as well as on osteoblast-like cells, but not on fibroblast-like cells of the outer periosteum. In response to PTH, osteocytes increased their intracellular levels of cAMP, as did the osteoblast-like cells. Osteocytes appeared to be somewhat more sensitive to PTH than osteoblasts. When seeded onto dentin slices, osteocytes did not corrode the dentin surface to any appraisable degree. We therefore found no evidence to support the notion that osteocytes play a role in the calcium homeostasis through osteocytic osteolysis. Whether osteocytes play an important role in perceiving and transducing hormonal and/or mechanical stimuli remains open for future research.

Heterogeneity of intracellular calcium responses to parathyroid hormone and thrombin in primary osteoblast-like cells and UMR106-01 cells: correlations with culture conditions, intracellular calcium concentration and differentiation state.

The present study evaluates the effect of parathyroid hormone (PTH) on intracellular calcium. Intracellular calcium ion concentrations ([Ca2+]i) in fetal rat osteoblasts in primary culture (ROB) and in UMR106-01 osteogenic sarcoma cells were monitored as changes in the ratio (R) of Fura-2 fluorescence intensities in single cells as well as populations of cells. In both single ROB and UMR106-01 cells, addition of 10(-7) M rat PTH1-34 and 3 NIH units/ml human thrombin resulted in heterogeneous responses in R values and therefore [Ca2+]i. PTH-induced calcium responsiveness of ROB was dependent on culture conditions, such that response frequencies were positively correlated with the percentage of fetal calf serum in the culture medium. PTH responsive ROB and UMR106-01 cells had significantly higher resting [Ca2+]i than unresponsive cells. PTH- or thrombin-mediated calcium signalling appeared not to be correlated to alkaline phosphatase activity in single ROB. Low percentages of cells responded to PTH in comparison to thrombin suggesting that an increase in [Ca2+]i is not a common PTH signalling pathway in osteoblasts in primary culture. Our data suggest that activation of this signalling pathway by PTH is culture condition dependent, possibly via a cell-cycle related increase in sensitivity of the pathway.

Cell-cell interactions in the osteogenic compartment of bone.

The interactions between two different cell populations within the osteogenic compartment have been examined. The proliferation of periosteal fibroblasts (PF) in the presence or absence of osteoblast-like cells (OB), whose proliferative capacity was inhibited by irradiation, was measured. OB stimulated [3H]thymidine incorporation in PF and parathyroid hormone (PTH) enhanced the stimulation. In the reverse situation, however, PF inhibited OB. Irradiated OB also stimulated 3H-thymidine incorporation in OB, and irradiated PF in PF, but both to a lesser extent. Co-culture experiments showed that direct cell-cell contact was a prerequisite for stimulation of PF. Medium mediated contact between physically separated OB and PF did not stimulate, but rather inhibited PF proliferation. These results demonstrate that OB regulate the proliferation of cells in the PF population and can transmit the proliferation stimulating message of PTH to PF. This implies that in vivo the mature osteoblast may play a pivotal role in the (hormonal) regulation of osteoprogenitor cell proliferation and therefore bone formation.

Tartrate-resistant acid phosphatase is not an exclusive marker for mouse osteoclasts in cell culture.

The method of Barka and Anderson was used for the demonstration of tartrate-resistant acid phosphatase (TRAcP) in cultures of bone marrow, spleen, lung, and peritoneal cells of the mouse. The staining was performed either in the usual way by adding both substrate (naphthol-AS-BI-phosphate) and coupler (hexazonium pararosanilin) together (the simultaneous-coupling technique) or by adding first the substrate and then the coupler (the post-coupling technique). We measured TRAcP-activity fluorometrically after extraction of the product naphthol-AS-BI, using the same staining solution as in cytochemical method, but without the coupler. In bone marrow, spleen, lung, and peritoneal cell cultures a biochemically measurable TRAcP-activity was detected. Post-coupling generally gave a higher level of staining and larger numbers of TRAcP-positive cells than simultaneous-coupling. In bone marrow cultures macrophages, identifiable by their ability to phagocytose microspheres, became TRAcP-positive during culture. In lung cell cultures cells capable of phagocytosis of bacteria were shown to be TRAcP-positive. Peritoneal macrophages remained TRAcP-negative in the simultaneous-coupling technique. Using the post-coupling technique a small number stained TRAcP-positive. In spleen cell cultures TRAcP-positive cells containing hemosiderin were visible. In cultures of all four cell types, F4/80 positive cells staining also for TRAcP were present. F4/80 is a well known marker for macrophages, whereas osteoclasts are negative. In conclusion, mouse macrophages originating from various tissues can become TRAcP-positive in vitro. TRAcP activity alone is not a reliable marker for osteoclasts in bone marrow cultures.

Osteoclast formation from human cord blood mononuclear cells co-cultured with mice embryonic metatarsals in the presence of M-CSF.

Investigating the potentiality of cord monocytes to differentiate toward osteoclast-like cells (OCL) in vitro, we previously reported that in the presence of 1,25(OH)2 vitamin D3 (1,25-(OH)2D3), multinucleated-cells generated by cord monocyte cultures though displaying morphological features of OCL failed to resorb devitalized bones. We thus hypothesized that full differentiation of cord monocytes toward bone-resorbing cells may require the presence of factors released from and/or direct interactions with living osteogenic cells. In the present study, we tested these hypotheses using two culture systems supporting the development of bone-resorbing cells in the presence of bone matrix. First, cord mononuclear cells were co-cultured with murine fetal metatarsals depleted of osteoclast progenitor cells (stripped metatarsals) in the presence of 1,25-(OH)2D3. We found that cord mononuclear cells failed to differentiate toward OCL as indicated by the absence of the release of 45Ca previously incorporated in fetal bones and by the absence of formation of TRAP-positive (TRAP[+]) multinucleated cells which have invaded mineralized cartilage during the co-culture period. In the same model, we then investigated the effect of some soluble factors known as stimulators of osteoclast differentiation. Whereas exogenous rhIL6 and rhIL3 were ineffective in this assay, rhM-CSF consistently increased both the number of TRAP(+) multinucleated cells inside the mineralized cartilage and the release of 45Ca into the culture media. The effects of rhM-CSF were time-dependent reaching the maximum after 3 weeks of culture.(ABSTRACT TRUNCATED AT 250 WORDS)

Adhesive properties of isolated chick osteocytes in vitro.

Different functions have been proposed for osteocytes over time, but it is now generally accepted that their most important task lies in the sensing of strain caused by mechanical loading on bone. The fact that mechanical strain can be sensed as deformation of the extracellular matrix or as fluid shear stress along the cell, in the space between cell membrane and extracellular matrix, requires that osteocytes have close (specialized) contact with the bone matrix. We studied to which extracellular matrix proteins isolated chicken osteocytes adhere and whether this adhesion is mediated by specific cell adhesion receptors called integrins. The adhesive properties of the osteocytes were compared with that of osteoblasts. Osteocytes (and osteoblasts) adhere to the same substrates (i.e., collagen types I and II, collagen fibers, osteopontin, osteonectin, fibronectin, fibrinogen, thrombospondin, and laminin). Cell spreading varied between substrates, from all cells rounded on thrombospondin to all cells fully spread out on osteopontin, osteonectin, vitronectin, fibronectin, fibrinogen, and laminin. The percentage of osteocytes adhered was equivalent to that of osteoblasts adhered on all substrates except osteopontin and vitronectin, where osteocytes adhered less. The adhesion of osteocytes and osteoblasts to osteopontin, osteonectin, vitronectin, and fibrinogen was strongly inhibited, and to fibronectin and laminin moderately, by an RGD peptide. No RGD inhibition was found on collagen. An antibody against chicken integrin alpha v beta 3, the monoclonal antibody (MAb) 23C6, did not interfere with the adhesion of osteocytes and osteoblasts to matrix proteins, whereas an MAb against chicken integrin subunit beta 1 (CSAT) strongly inhibited adhesion to all substrates. Labeling with osteocyte-specific MAbs (OB7.3, OB37.4, and OB37.11) also did not hinder the adhesion of osteocytes to collagen type I, vitronectin, and osteopontin. Adhesion sites on osteocytes were small compared with the large adhesion plaques of osteoblasts, as demonstrated by interference reflection microscopy and immunocytochemically by staining for vinculin. Osteocyte adhesion is analogous to osteoblast adhesion with regard to the range of extracellular matrix proteins to which they adhere. The adhesion is mediated by the integrin subunit beta 1, but other integrins or nonintegrin adhesion receptors are also involved. Osteocytes make contact with the extracellular matrix via small attachment points which colocalize with vinculin. This connection between the bone matrix and the cytoskeleton may be important for osteocytic sensing of mechanical strain, as it supplies a transduction route of extracellular (mechanical) signals into intracellular messages.

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.

The effect of verapamil on the action of parathyroid hormone on embryonic bone in vitro.

Short term in vitro experiments showed that, added alone, verapamil inhibited both glycolysis and Ca uptake in embryonic chicken and rat bone cells. Added together with PTH, verapamil (0.02 MM) enhanced cAMP production, had no effect on lactate production, but significantly inhibited citrate, calcium and phosphate release from embryonic rat and mouse calvaria incubated under hypocalcemic conditions. The depression by verapamil of PTH-stimulated demineralization was confirmed histologically. It is concluded that in addition to cAMP, Ca plays a key role in the action of PTH on bone.

Effect of therapeutic ultrasound on endochondral ossification.

The effect of therapeutic doses of ultrasound was tested on endochondral ossification of in vitro developing metatarsal long bone rudiments of 16- and 17-day-old fetal mice. Bone growth, calcification and resorption following exposure to several doses of pulse-wave (PW) or continuous-wave (CW) ultrasound were examined. PW was applied at intensities between 0.1 W cm-2 and 0.77 W cm-2 (Isatp) and CW intensities were 0.1 W cm-2 or 0.5 W cm-2 (Isata). After 1 week of culture, the metatarsal long bone rudiments were fixed and paraffin sections were prepared for histological evaluation and for measurement of the relative contribution of the various cartilage zones to the total bone length. In contrast to treatment with CW ultrasound, treatment of 16-day-old metatarsal long bone rudiments with PW ultrasound resulted after 4 days of culture in significantly increased longitudinal growth. Histology revealed a significant increased length of the proliferative zone, whereas the length of the hypertrophic cartilage zone was unaltered. This might indicate that proliferation of the cartilage cells is stimulated without influence on cell differentiation.