Transformations of osteoclast phenotype in ia rats cured of congenital osteopetrosis

The reduced bone resorption characteristic of osteopetrosis is accompanied in the incisors-absent (ia) rat mutation by a significant increase in osteoclasts of inactive (mutant) phenotype. Restoration of bone resorption in ia rats by transfer of spleen cells from normal littermates is preceded by a transformation of osteoclasts from mutant to normal phenotype. In this investigation the proportions of osteoclasts of normal phenotype have been determined by light microscopy in untreated ia and normal rats and in ia rats treated with various cell populations from normal rats. Significant increases in numbers of osteoclasts of normal phenotype were seen in the mutant skeleton soon after cell treatments that eventually restored bone resorption and cured the disease. No changes in osteoclast phenotype were seen after cell transfers that did not cure the disease. These data establish transformation of osteoclast phenotype as an early event in the recovery from osteopetrosis and suggest that determination of osteoclast phenotype is a reliable predictor of the success of normal cell populations to restore bone resorption in this mutation.     

Extensive clear zone and defective ruffled border formation in osteoclasts of osteopetrotic (ia/ia) rats: implications for secretory function.

The cellular distribution of osteoclast integrin subunits alpha(v) and beta(3), the tissue distribution, and level of the apparent ligand osteopontin (OPN) as well as of the putative regulatory enzyme tartrate-resistant acid phosphatase (TRAP) were studied along with the intracellular distribution of the activation marker c-src in osteopetrotic ia/ia (incisors-absent) mutant rats and their normal littermates. In ia/ia rats, the osteoclasts are incapable of bone matrix resorption. Ultrastructurally the cells exhibit extended clear zones at the expense of ordinary ruffled borders. A secretory dysfunction in the mutant is strongly suggested by the absence of detectable extracellular TRAP, concomitant with an accumulation of the enzyme in abundant small cytoplasmic vesicles. Moreover, TRAP mRNA, protein content, as well as enzymatic activity were elevated. Furthermore, increased levels of integrin subunits alpha(v) and beta(3) were detected at the clear zone of mutant osteoclasts. OPN mRNA levels were elevated in long bones from mutants. In ia/ia rats, immunolabeling for OPN was homogeneously distributed at the surface facing osteoclasts, while in normal littermates it was concentrated at the clear zone area and barely detectable at ruffled borders. The absence of OPN labeling in the abundant, putative intracellular secretory vesicles in mutant osteoclasts suggests that these cells do not produce OPN. The osteoclasts of ia/ia rats appeared to produce and translocate the c-src protein to the cell membrane. In ia/ia a defect ruffled border-formation is observed along with extensive clear zone formation and decreased secretory function. The lesion may be due to a signaling defect, but in that case the defect seems to be located downstream to or not involving the c-src pathway. Our results illustrate the close relationship between secretory function and ruffled border formation in osteoclasts, a relationship that appears to be necessary for proper resorptive function.     

Studies of the cellular cure for osteopetrosis by transplanted cells: specificity of the cell type in ia rats.

Spleen cells from normal rats are known to cure osteopetrosis in ia littermates within 3 weeks. In this study cell suspensions from liver, thymus, bone marrow, salivary gland, skeletal muscle and brain from normal rats were tested for their ability to cure osteopetrosis in ia littermates whose ability to reject these cells had been suppressed by whole-body irradiation. Cells from liver, thymus and bone marrow cured the disease as effectively as spleen cells from normal littermates. Mutants that received cells from salivary gland, muscle and brain remained osteopetrotic. These data suggest that some cell found in spleen, liver, thymus and bone marrow of 10-day-old normal rats, such as a lymphoid cell or stem cell, can restore hemopoiesis and bone resorption in osteopetrotic (ia) rats.     

Osteopetrosis in the toothless (t1) rat: presence of osteoclasts but failure to respond to parathyroid extract or to be cured by infusion of spleen or bone marrow cells from normal littermates.

Osteoclast have been observe for the first time in toothless (t1) rats, a mutation with inherits osteopetrosis as an autosomal recessive. The ability of t1 rats to raise the serum calcium concentration after injection of parathyroid extract was severely limited when compared with normal littermates. In addition, osteopetrosis in t1 rats is not cured by radiation and infusion of normal spleen or bone marrow cells from normal littermates, a method know to cure osteopetrosis in mutants of this and other species. This indirect evidence for a reduction in bone resorption as a cause of osteopetrosis in this mutation and the failure of transplanted cells to cure the disease are discussed in relation to the development and function of osteoclasts.     

Morphological evidence of reduced bone resorption in the osteosclerotic (oc) mouse

Osteopetrosis, a metabolic bone disease characterized by a generalized sclerosis of the skeleton, is inherited as an autosomal recessive in a number of mammalian species. The pathogenesis of congenital osteopetrosis is mediated by a reduction in bone resorption as a result of decreased osteoclast function. This hypothesis is based on both functional and structural evidence of reduced bone resorption in all mutations examined to date. The present study examined the histology of cartilage and bone, the ultrastructure of osteoclasts, and the morphology of mineralized bone surfaces in a lethal osteopetrotic mutation, the osteosclerotic (oc) mouse. Histologically, epiphyseal cartilage growth plates, especially the hypertrophic zone, are markedly thickened in oc mice and metaphyses contain excessive osteoid, features characteristic of rickets. Transmission electron microscopy revealed that less than one-quarter of osteoclasts in oc mice demonstrated evidence of ruffled border formation compared with three-quarters of the osteoclasts in normal littermates. In mutants, ruffled borders were less elaborate and cytoplasmic processes penetrated into bone surfaces, suggesting that bone may be removed by mechanical rather than by enzymatic means. There was little morphological evidence of cartilage degradation and broad laminae limitantes persisted in mutants. Mineralized surfaces that undergo resorption in normal mice showed no evidence of bone resorption by scanning EM in mutants. The presence of a rachitic condition, the observations of reduced bone resorption, and the possible contribution of undermineralized matrices to decreased bone resorption are characteristics of the osteosclerotic mutation which suggest that it is a unique osteopetrotic mutant in which to study both the development and regulation of skeletal metabolism.     

Extensive Clear Zone and Defective Ruffled Border Formation in Osteoclasts of Osteopetrotic (ia/ia) Rats: Implications for Secretory Function

The cellular distribution of osteoclast integrin subunits α_v and β₃, the tissue distribution, and level of the apparent ligand osteopontin (OPN) as well as of the putative regulatory enzyme tartrate-resistant acid phosphatase (TRAP) were studied along with the intracellular distribution of the activation marker c-src in osteopetrotic ia/ia (incisors-absent) mutant rats and their normal littermates. In ia/ia rats, the osteoclasts are incapable of bone matrix resorption. Ultrastructurally the cells exhibit extended clear zones at the expense of ordinary ruffled borders. A secretory dysfunction in the mutant is strongly suggested by the absence of detectable extracellular TRAP, concomitant with an accumulation of the enzyme in abundant small cytoplasmic vesicles. Moreover, TRAP mRNA, protein content, as well as enzymatic activity were elevated. Furthermore, increased levels of integrin subunits α_v and β₃ were detected at the clear zone of mutant osteoclasts. OPN mRNA levels were elevated in long bones from mutants. In ia/ia rats, immunolabeling for OPN was homogeneously distributed at the surface facing osteoclasts, while in normal littermates it was concentrated at the clear zone area and barely detectable at ruffled borders. The absence of OPN labeling in the abundant, putative intracellular secretory vesicles in mutant osteoclasts suggests that these cells do not produce OPN. The osteoclasts of ia/ia rats appeared to produce and translocate the c-src protein to the cell membrane.In ia/ia a defect ruffled border-formation is observed along with extensive clear zone formation and decreased secretory function. The lesion may be due to a signaling defect, but in that case the defect seems to be located downstream to or not involving the c-src pathway. Our results illustrate the close relationship between secretory function and ruffled border formation in osteoclasts, a relationship that appears to be necessary for proper resorptive function.     

Carbonic anhydrase II and H+-ATPase in osteoclasts of four osteopetrotic mutations in the rat

 Osteopetrosis in laboratory animals is a metabolic bone disease characterized by increased skeletal mass. It is inherited as an autosomal recessive and results from a defect in the development and/or function of osteoclasts. We studied two enzymes essential for bone resorption, carbonic anhydrase II isoenzyme (CA II) and H⁺-ATPase, in osteoclasts from four osteopetrotic mutations in the rat; namely incisors-absent (ia), osteopetrosis (op), toothless (tl), and microphthalmia (mib), to test the hypothesis that reduced bone resorption in one or more of these mutations results from defects in the synthesis or activity of one of these enzymes. CA II was present in most osteoclasts from normal, tl, op, and mib littermates and was homogeneously distributed in cytoplasm. CA II staining in ia osteoclasts was more variable and less intense than in the other mutations. H⁺-ATPase was also present in osteoclasts from normal animals and mutants and immunostaining showed clear polarization to the ruffled border region in all normal rats and mutants except ia, which showed diffuse distribution of staining in the cytoplasm. H⁺-ATPase activity (proton transport) in a related tissue, kidney, was normal in tl and ia rats but increased in op and mib rats compared to their normal littermates. These results suggest that the osteoclasts in osteopetrotic rat mutations are not abnormal with respect to the distribution of CA II and H⁺-ATPase and that the function of these enzymes in the skeleton, while likely normal, needs to be tested directly in bone. Accepted: 25 September 1998     

Ultrastructure of the giant cell infiltrate of subcutaneously implanted bone particles in rats and mice

The giant cells of soft tissues and those of mineralized tissues (osteoclasts) have distinctly different cell surface receptors and ultrastructural characteristics. Recently, the removal of dead bone particles in a subcutaneous environment has been described as a prototype of bone resorption, and a major issue is whether the giant cells that surround these ectopic bone implants and the processes involved in the disruption of bone surfaces are the same as those in the skeleton. We have compared the cytology and ultrastructure of giant cells recruited to subcutaneously implanted isogeneic bone particles with similar features of osteoclasts in metaphyseal bone of young normal rats and mice. Giant cells on surfaces of bone particles 2, 3, and 4 weeks after implantation were multinucleated, had a homogeneous, nonvacuolated cytoplasm, and had a bone surface interface unremarkable by light microscopy. In a few cells randomly distributed, small cytoplasmic vacuoles were present and large vacuoles were noted next to the bone surface at high magnification. By transmission electron microscopy, folded membrane configurations forming extensive interdigitations with adjacent cells were prominent features on most surfaces of giant cells. In instances where these interdigitations abutted bone surfaces, configuration resembling a ruffled border were noted, but these regions were always part of two different cells when examined at lower magnification or in serial sections. Breakdown of bone particles appeared to be by phagocytosis of small pieces and subsequent intracellular digestion in electron-dense cytoplasmic vacuoles. Osteoclasts from these same young animals were smaller with fewer nuclei, had cytoplasmic vacuoles concentrated next to bone surfaces, and had characteristic ruffled borders and clear zones. These results confirm those of others that native osteoclasts and multinucleated giant cells on dead bone particles are distinctly different with respect to both ultrastructure and mechanism of disruption of bone surfaces.     

Calcitonin inhibits accumulation of cyclic AMP in stimulated peritoneal macrophages from normal rats but not from osteopetrotic (incisors-absent) littermates

Macrophages and osteoclasts derive from related cell lines. In osteopetrotic mutants the function of osteoclasts is greatly reduced compared to that in normal animals or children and macrophage function is variably affected depending upon the mutation. To further explore macrophage function in osteopetrosis we examined the regulation of cyclic AMP production in macrophages from mutants and normal littermates of the osteopetrotic stock incisors-absent (ia) in the rat. Surface stimulation by latex particles of elicited peritoneal macrophages from normal or osteopetrotic (ia) mutant rats caused an identical increase in the accumulation of cyclic AMP. This effect was inhibited in normal animals by coincubation of macrophages with calcitonin (CT) but this inhibition was either absent or less marked in macrophages from mutant littermates. In contrast to human monocytes preincubation of rat macrophages with pertussis toxin did not relieve this inhibition. This implies that rat peritoneal macrophages respond to CT by a different mechanism. These results demonstrate altered macrophage function in osteopetrotic animals and may be functionally related to the reduced CT binding previously described in ia osteoclasts. Furthermore, the coexistence of reduced function of macrophages and osteoclasts in the ia mutation suggests that macrophages and osteoclasts share a common progenitor.     

Resorption of vital or devitalized bone by isolated osteoclasts in vitro

Summary The maintainance of resorptive capability towards vital or devitalized bone in osteoclasts isolated from the medullary bone of laying hens and cultured for five days in vitro has been investigated morphologically with the aid of light and transmission electron microscopy. Devitalized bone particles ranging in size from 50 to 100 m, added to cultures of osteoclasts, were rapidly surrounded by the osteoclasts which, in transmission electron microscopy, showed ruffled borders and clear zones at the surfaces of contact with bone — features typical of resorptive activity. Alternatively osteoclasts were added onto the endosteal surfaces of vital or devitalized diaphyses of quail femurs after removal of the endosteal and periosteal cell layers. The results indicated that, when the vital or devitalized bone surfaces were devoid of cells, the osteoclasts adhered and resorbed bone (as confirmed by transmission electron microscopy). When vital bone of quail was cultured for 24 h before the addition of osteoclasts a new cell layer was formed; it enveloped all bone surfaces and precluded the access of osteoclasts to bone. The role of these lining cells, ultrastructurally indistinguishable from resting osteoblasts, is discussed.     

The hematogenous origin of osteoclasts: experimental evidence from osteopetrotic (microphthalmic) mice treated with spleen cells from beige mouse donors

The excessive skeletal mass and reduced bone resorption characteristic of osteopetrosis in microphthalmic (mi) mice can be corrected by irradiation and transfer of spleen cells from a normal littermate. Osteoclasts in beige (bg) mice, a mutation without osteopetrosis, have giant lysosomal granules. These two facts were exploited to trace osteoclast lineage. Microphthalmic mice treated with whole-body irradiation and spleen cells from a beige donor resorbed the excessive skeletal mass and recovered from osteopetrosis. Furthermore, osteoclasts in treated mi mice had giant lysosomal granules and resembled those found in bg donors when examined by light and transmission electron microscopy. These data provide direct evidence for a hematogenous origin of osteoclasts in mammals.     

Three-dimensional distribution of the clear zone of migrating osteoclasts on dentin slices in vitro

Osteoclasts are cells that dynamically alternate resorption and migration on bone surfaces, and have the special structure called ruffled borders and clear zones by transmission electron microscopy (TEM). However, TEM features, especially the distribution of the clear zone of osteoclasts during migration, remains unclear. This study aimed to examine osteoclasts cultured on dentin slices by TEM and clarify the features of migrating osteoclasts, especially the three-dimensional distribution of clear zones. Osteoclasts obtained from mice were cultured with dentin slices for 72 h, and then cells were fixed and the tartrate-resistant acid phosphatase (TRAP) activity was detected. Specimens were embedded in Epon, then TRAP-positive cells were serially sectioned by alternating semithin and ultrathin sections. The cells were examined by TEM and the three-dimensional structures were reconstructed by computer. By TEM, most TRAP-positive cells were resorbing osteoclasts with ruffled borders and a clear zone. There were osteoclasts without ruffled borders, and these cells had clear zone-like structures and lamellipodia. The three-dimensional reconstruction showed that resorbing osteoclasts had rounded contours and ring-shaped clear zones encircling ruffled borders, and that osteoclasts without ruffled borders had irregular and flat shapes; the clear zone-like structures showed a dot or patch-like distribution. The presence of lamellipodia of the osteoclasts without ruffled borders shows that the cells are migrating osteoclasts. These results suggest that dot or patch-like distribution is the feature of the clear zone of osteoclasts during migration, and that these structures play the role of focal contacts and adhesion to the dentin surfaces during cell migration.     

Cellular specificity of the cure for neonatal osteopetrosis in the ia rat

Osteopetrosis in the ia/ia rat is known to be the result of reduced bone resorption due to abnormal osteoclasts. Studies in this mutant have shown that mononuclear cells from normal littermates could cure the skeletal sclerosis and result in the formation of normal osteoclasts when transplanted into ia/ia rats. This investigation was pursued in an attempt to determine the cellular source of this cure by transplanting various populations of cells from 21-day-old normal rats to unrelated newborn ia/ia recipients. The effects of treatment were evaluated radiographically and by measuring the size of the tibial marrow cavity. The cellular suspensions that were effective in curing the disease were the Ficoll-Hypaque isolate of spleen, bone marrow, and newborn livers. The Ficoll-Hypaque isolates of lymph node, thymus, and blood, and the adherent pool of peritoneal cells and splenic cells did not produce a cure in the ia/ia recipients. These results suggest that the cellular source of the cure is a stem cell. This conclusion is further substantiated by the finding that Thy 1.1 antigen (a stem cell marker in the rat) is expressed on a majority of the cells from the donor sources that affected a cure.     

Congenitally osteosclerotic (os/os) rabbits are not cured by bone marrow transplantation from normal littermates.

The osteopetrotic (os) rabbit is a lethal mutation of autosomal recessive inheritance characterized by hypocalcemia, hypophosphatemia, fibrosis of marrow spaces, and ultrastructural abnormalities in both osteoclasts and osteoblasts. Procedures involving the transplantation of cells from normal hemopoietic tissues, which are sources of osteoclast precursors, are known to cure osteopetrosis in several mutations including some children. We tested the ability of transplanted bone marrow and/or spleen from normal littermates to reverse the skeletal sclerosis in os rabbits. Treatment of 15 neonatal mutants consisted of immunosuppression by whole-body irradiation followed by transplantation of normal bone marrow and/or spleen cell suspensions. This treatment failed to prolong life span or to cure osteopetrosis judged radiographically and histologically for up to 3 weeks posttreatment, the longest time of survival. These data indicate that transplantation of stem cells from multiple hemopoietic tissues, procedures known to cure osteopetrosis in other mutations, is not effective in the os rabbit. These results support the hypothesis that the skeletal microenvironment is not capable of supporting the development and function of normal osteoclasts in this mutation.     

Osteoclast biology in the osteopetrotic (op) rat

Osteopetrosis is a metabolic bone disease characterized by reduced bone resorption. From experimental studies of various osteopetrotic mutations has emerged the hypothesis that each is unique with respect to mechanisms whereby osteoclast development and/or function are reduced. The osteopetrotic (op) mutation in the rat was discovered in Fatty/ORL stock over a decade ago. The paucity of data about osteoclast biology in this mutation prompted this study of cytological, cytochemical, and ultrastructural features of osteoclasts. In op rats, osteoclasts are significantly reduced in number, but are larger and more vacuolated than in normal littermates. Mutant osteoclasts can form ruffled borders and clear zones, but their ability to fragment and excavate bone surfaces is greatly impaired. Cytoplasmic vacuoles in op osteoclasts are randomly distributed and greatly enlarged, and they stain weakly for two cytochemical characteristics of osteoclasts, tartrate-resistant acid phosphatase and acid ATPase. These findings suggest that an abnormality in the lysosomal/vacuolar system, an important component of the resorptive mechanism, may be involved in the interception of osteoclast function in this mutation.     

Rapid activation of the medullary bone osteoclast cell surface by parathyroid hormone

Quantitative transmission electron microscope methods were used to determine the response of functionally inactive avian medullary bone osteoclasts to parathyroid hormone (PTH). Egg-lying Japanese quail were used during a period of the egg cycle when medullary bone was not being resorbed for egg shell calcification and when medullary bone osteoclasts were functionally inactive. Ruffled borders adjacent to bone surfaces were rarely, if ever, found on these cells. 20 min after the administration of PTH, over 70% of the osteoclast profiles had ruffled borders adjacent to bone surfaces. These ruffled borders were bounded by filamentous-rich "clear zones" and resembled ruffled borders found on functionally active cells. There was also a marked increase in plasma calcium levels after PTH administration. This study demonstrates that PTH stimulates the de novo generation of ruffled borders on osteoclasts in vivo and suggests that osteoclasts may be involved in the acute regulation of calcium metabolism by exogenous PTH.     

Impaired osteoclast differentiation in subcutaneous implants of bone particles in osteopetrotic mutants

Because of its synchrony and relative homogeneity, the subcutaneous model of the resorption of mineral-containing, devitalized bone particles (BPs) is useful to evaluate the recruitment, differentiation, and activity of bone-resorbing, osteoclastic cells. Bone particles were prepared from normal rats or mice and were implanted in normal and osteopetrotic rats (ia, tl, op strains) or mice (mi strain). In addition, particles of microcrystalline hydroxyapatite or polymethylmethacrylate were implanted into tl and op mutants and their unaffected littermates.Non-decalcified histomorphometry of elicited tissues after 12 days revealed significantly less resorption in in each mutant. Enzyme histochemical assays revealed that only normal animals showed tartrate-resistant acid phosphatase-positive cells around the BPs. In agreement with this, only normal animals showed ruffled borders against the BPs. op and tl strains were tested for generation of foreign body giant cells in response to particulate hydroxyapatite or polymethylmethacrylate and no differences were found between mutant and normal animals. These mutants appear to have intact fusion of mononuclear progenitors.These data show impaired recruitment of osteoclasts by BP implants in several rodent strains of osteopetrotic mutants.     

Cellular response to ectopically implanted silk sutures and osteopetrotic bone

Summary Faulty osteoclasts, characteristic of the incisors-absent (ia) rat mutation of osteopetrosis, cause a resorptive defect which results in the persistence of immature, highly mineralized bone matrix. We implanted osteopetrotic bone subcutaneously into normal andia rats to determine ifia bone could induce functionally active and morphologically identifiable osteoclasts at the implant surface. Assays of⁴⁵Ca released from the preparations showed that normal andia recipients were capable of equivalent cell-mediated release of Ca over a 2-week implant period, indicating that theia resorptive defect was not reproduced at the subcutaneous site. Freeze-thawed osteopetrotic bone released twice as much⁴⁵Ca as normal bone. This difference was eliminated by collagenase treatment. Cellular profiles were similar in both normal andia animals regardless of the implant preparation. At 3 days after implantation, both bone and suture were surrounded by mononuclear cells. By 14 days, multinucleated cells appeared at the implant surfaces. Morphological comparison of implant-induced multinucleated cells and tibial osteoclasts indicated that bone-elicited multinucleated cells lacked the ruffled borders characteristic of normal osteoclasts or the extensive clear zones typical ofia osteoclasts, but more closely resembled suture-induced macrophage-polykaryons. We conclude that ectopically implantedia bone as compared to normal bone elicits a different functional response from structurally similar cell populations. Bone-elicited multinucleated cells could not be classified as active osteoclasts despite evidence of release of⁴⁵Ca. Release of labeled Ca was probably due to the action of mononuclear phagocytes and macrophage-polykaryons rather than to osteoclastic resorption.     

Loss of the ClC-7 chloride channel leads to osteopetrosis in mice and man

Chloride channels play important roles in the plasma membrane and in intracellular organelles. Mice deficient for the ubiquitously expressed ClC-7 Cl(-) channel show severe osteopetrosis and retinal degeneration. Although osteoclasts are present in normal numbers, they fail to resorb bone because they cannot acidify the extracellular resorption lacuna. ClC-7 resides in late endosomal and lysosomal compartments. In osteoclasts, it is highly expressed in the ruffled membrane, formed by the fusion of H(+)-ATPase-containing vesicles, that secretes protons into the lacuna. We also identified CLCN7 mutations in a patient with human infantile malignant osteopetrosis. We conclude that ClC-7 provides the chloride conductance required for an efficient proton pumping by the H(+)-ATPase of the osteoclast ruffled membrane.     

Osteoclast cell-surface changes during the egg-laying cycle in Japanese quail

The medullary bone serves as a source of labile calcium mobilized during calcification of the egg shell in birds. Quantitative histological methods demonstrate that the numbers of medullary bone osteoclasts and nuclei per osteoclast remain unchanged during the egg cycle in the Japanese quail (Coturnix). Therefore, cyclic changes in bone resorption cannot be explained by modulations of osteoclasts from and into other bone cells, a mechanism previously suggested for certain species of birds. Rather, dramatic changes in osteoclast cell-surface features occur during the egg cycle, which might account for cyclic variations in resorptive activity. During egg shell calcification, osteoclasts with ruffled borders are closely apposed to bone surfaces; the cytoplasm is rich in vacuoles that contain mineral crystals and seem to derive from the ruffled border. At the completion of egg shell calcification, the ruffled borders and vacuoles move away from the bone surface, although the osteoclast remains attached to the bone along the filamentous or "clear" zone. Associated with the disappearance of the ruffled borders is the appearance of extensive interdigitated cell processes along the peripheral surface of the osteoclast away from the bone. These unusual structures, which may serve as a reservoir of membrane, largely disappear when ruffled borders and associated structures reappear. Therefore, in these hens, the osteoclasts modulate their cell surface rather than their population during the egg cycle.