Ultrastructural investigations of bone resorptive cells in two types of autosomal dominant osteopetrosis

In order to investigate the ultrastructure of bone resorptive cells in the two types of adult benign human osteopetrosis, iliac crest biopsies were obtained from 11 patients and 10 normal males, who served as a control group. Six patients had the radiological type I (4 women, 2 men, aged 23–58 years, MEAN = 36.5 years), and 5 type II disease (5 men, aged 20–48 years, MEAN = 29.8 years). The normal controls (aged 23–48 years, mean 34.1 years) were recruited from the medical staff. The biopsies were immediately divided. From each patient, half was embedded in paraffin for histochemistry and light microscopy, and half in epon for transmission electron microscopy.

The osteoclasts were markedly reduced in number and size hi Type I disease (0.2 ± .7 cells vs. 2.9 ± 1.0 cells per 2.7 mm² of bone area, p < 0.01) compared to controls, and stained only weakly for tartrate-resistant acid phosphatase (TRAP). At the ultrastructural level, no signs of active bone resorption were identified, whereas numerous mononuclear cells were observed at the bone surfaces.

In type II disease, the osteoclasts were large and highly multi-nucleated, with an increased number (8.3 ± 2.3 cells vs. 2.9 ± 1.0. cells per 2.7 mm² of bone area, p < 0.01) compared to controls. In all patients with this type, but never in type I or in the controls, a smooth, TRAP-positive substance was seen between the osteoclasts and the bone surface. Ultrastructurally, this substance was amorphous, with a condensation along the cell membrane. Neither ruffled borders nor clear zones were identified. Nuclear inclusions resembling tubular structures were observed in some osteoclasts in all patients with type II disease.

It is concluded that characteristic differences exist between the two types of adult human osteopetrosis at the ultrastructural level. Type I is morphologically similar to some murine mutations characterized by defective maturation of bone resorptive cells. In type II, a defect in the resorptive capacity of their giant osteoclasts is proposed. The pathogenetical significance of nuclear inclusions in type II osteoclasts is unknown.     

Infantile Malignant, Autosomal Recessive Osteopetrosis: The Rich and The Poor

Human recessive osteopetrosis (ARO) represents a group of diseases in which, due to a defect in osteoclasts, bone resorption is prevented. The deficit could arise either from failure in osteoclast differentiation or from inability to perform resorption by mature, multinucleated, but nonfunctional cells. Historically, osteopetrosis due to both these mechanisms was found in spontaneous and artificially created mouse mutants, but the first five genes identified in human ARO (CA-II, TCIRG1, ClCN7, OSTM1, and PLEKHM1) were all involved in the effector function of mature osteoclasts, being linked to acidification of the cell/bone interface or to intracellular processing of the resorbed material. Differentiation defects in human ARO have only recently been described, following the identification of mutations in both RANKL and RANK, which define a new form of osteoclast-poor ARO, as expected from biochemical, cellular, and animal studies. The molecular dissection of ARO has prognostic and therapeutic implications. RANKL-dependent patients, in particular, represent an interesting subset which could benefit from mesenchymal cell transplant and/or administration of soluble RANKL cytokine.     

Osteoclasts in human osteopetrosis contain viral-nucleocapsid-like nuclear inclusions

We report the discovery of nuclear inclusions in the osteoclasts of three unrelated patients with benign osteopetrosis that resemble the osteoclast inclusions characteristic of Paget's disease of bone. These inclusions are morphologically and dimensionally identical to the nucleocapsids of a virus of the Paramyxoviridae family. Supporting a possible viral association with benign osteopetrosis in the observation of the presence of antigens of respiratory syncytial virus, measles virus, and/or mumps virus in the cells of all five patients whose paraffin-embedded bone specimens were tested. These included two patients whose osteoclasts contained nuclear inclusions. No patients with the malignant form of the disease have been studied. There is as yet no proof that a virus is causally related to human osteopetrosis even though a virus can produce an avian form of the disease.     

Electron microscopy of avian osteopetrosis induced by retrovirus MAV.2-O

Summary Diaphyseal tibial bone of 12.5 – 13-day and 19-day-old embryos and 20-day-old hatched chicks infected with retrovirus MAV.2-O were examined by transmission electron microscopy. The viruses were associated with lining osteoblasts and osteocytes. Whereas the infection of the osteoblast layer seemed to be a transient stage, virus association with osteocytes was a constant and main ultrastructural feature. The viruses were found either in the osteoid or in the periosteocytic space of the bone lacunae. They arose from dense cytoplasmic areas located near the cell plasmalemma via a budding process. The newly budded virus particles often had a large tail or a fine stalk-like process lost in the extracellular space. The viruses underwent calcification by deposition of inorganic material and were incorporated in the bone trabeculae. No production of virus was observed in typical osteoclasts with well-differentiated ruffled borders. The viral-induced avian osteopetrosis seemed to result from increased bone deposition through stimulation of osteoblast and osteocyte activities, whereas osteoclastic bone resorption seemed to be undisturbed.     

Serum creatine kinase isoenzyme BB in mammalian osteopetrosis

In mammalian osteopetrosis the different mutations exemplify reduced bone resorption leading to net accumulation of bone. Recently, high blood levels of creatine kinase-BB have been reported in some human forms, suggesting it as a marker of osteopetrosis. In the current study serum creatine kinase-BB was evaluated in relation to known osteoclastic pathophysiology in two human types of autosomal dominant osteopetrosis at baseline and after stimulation with triiodothyronine and in four different rodent mutations. Creatine kinase-BB was increased markedly in Type 2 autosomal dominant osteopetrosis and in the incisors absent rat, both characterized by large numbers of giant osteoclasts, and did not change significantly after stimulation. Although creatine kinase-BB was unchanged in Type 1 autosomal dominant osteopetrosis at baseline and after stimulation, the rodent counterparts characterized by small osteoclasts, microphthalmic and osteopetrotic mice and toothless rats, had significantly decreased levels. Similar differences were observed in both types of autosomal dominant osteopetrosis compared with controls concerning tartrate resistant acid phosphatase. Creatine kinase-BB in mammalian osteopetrosis is related to osteoclastic number and size, where it probably reflects the differentiation and maturation of inactive bone resorbing cells. The isoenzyme does not seem to be a valuable screening marker for osteopetrosis.     

Variable osteoclast appearance in human infantile osteopetrosis

Summary A light and transmission electron microscopic (TEM) study of iliac crest metaphyseal bone from nine patients with infantile osteopetrosis demonstrates a variable spectrum of osteoclast abnormalities. All bone was obtained at biopsy before treatment. The average age at biopsy was 6 months with a range from 1 to 12 months. Osteoclast number was always increased and the cells were always appropriately positioned in relation to bone and cartilage. Osteoclast number, size, and nucleation varied from mildly to markedly increased. In those with only a mild-to-moderate osteoclast increase, the marrow had an otherwise near-normal appearance with a good complement of hematopoietic cells. In those with markedly increased osteoclasts (hyperosteoclastic state) there were only scanty collections of hematopoietic cells. Light microscopic histomorphometry documented the percentage of bone and cartilage surfaces covered by osteoclasts. Controls from areas of greatest osteoclast presence documented a 5% coverage. One osteopetrotic patient registered a 4.8% value with all others elevated from 7.6 to 27.9%. Quantitative electron microscopy showed the ruffled borderclear zone complex to be absent or markedly diminished in seven of the nine patients. In two, however, osteoclast profiles had abundant ruffled border-clear zone complexes. Patients with the hyperosteoclastic bone marrow were more severely affected clinically. Light and TEM studies of marrow biopsies in initial assessment of osteopetrosis establish a baseline profile, may provide prognostic information, and allow for more meaningful treatment follow-up. This paper is dedicated to the memory of our close colleague Constantine Anast.     

Higher osteoclastic demineralization and highly mineralized cement lines with osteocalcin deposition in a mandibular cortical bone of autosomal dominant osteopetrosis type II: ultrastructural and undecalcified histological investigations

In this study we report on histological and ultrastructural investigations of the mandibular cortical bone in a case of autosomal dominant osteopetrosis type II complicated by mandibular osteomyelitis. Histologically, there was a marked increase in the number and size of osteoclasts on the inner bone surface. An undecalcified preparation showed a pair of deeply stained (highly demineralized) and stain-phobic (highly mineralized) layers on the bone surface just beneath the osteoclasts. The layers were incorporated into the bone matrix during the remodeling process as thickened cement lines. A contact microradiogram of the cortical bone revealed highly mineralized layers at the cement lines, which were closely correlated with immunohistochemical evidence of deposition of osteocalcin at the thickened cement lines. Ultrastructural examination showed that the osteoclasts had a typical clear zone, but they were deficient in ruffled border formation and had numerous lysosomal vacuoles containing dense substances. An electron-dense amorphous material layer was present on the bone surface just beneath the osteoclasts as well as at the cement lines. The layer was partly composed of a short fibrillar material, and it partially revealed the lamellar structure. Consequently, an osteoclastic malfunction might be primarily involved in the process of bone matrix resorption rather than demineralization, resulting in higher demineralization and abnormal material deposition on the bone surface and at the cement lines. Furthermore, evidence of active osteoclastic bone resorption with a brush border formation at the bone involved in the inflammatory lesion in this case suggests that the osteoclastic malfunction is influenced and recovered by a microenvironment such as inflammatory cytokines.     

Limited rescue of osteoclast-poor osteopetrosis after successful engraftment by cord blood from an unrelated donor.

We report on a case of osteoclast-poor osteopetrosis who received a hematopoietic stem cell graft and, despite hematological engraftment, showed little signs of response in the skeletal defect. Clinical and laboratory studies supported the concept that the bone microenvironment remained abnormal, thus reducing the clinical response to transplantation. INTRODUCTION: Osteopetrosis is a rare genetic disorder characterized by severely reduced bone resorption resulting from a defect in either osteoclast development (osteoclast-poor osteopetrosis) or activation (osteoclast-rich osteopetrosis). Patients with osteoclast-rich osteopetrosis can be rescued by allogenic hematopoietic stem cell transplantation; however, little information exists concerning the success of transplantation as a treatment for osteoclast-poor osteopetrosis. We report on a child with osteoclast-poor osteopetrosis whose diagnosis was delayed, consequently receiving a cord blood transplant from an unrelated donor at the age of 8 years. Engraftment was deemed successful by peripheral blood genotyping, although >3 years after transplantation there was little rescue of the skeletal defect and anemia, and extramedullary hematopoiesis persisted. MATERIALS AND METHODS: Peripheral blood mononuclear cells from the osteopetrosis patient, before and after transplantation, were used to generate osteoclasts in vitro in the presence of macrophage colony-stimulating factor (M-CSF) and RANKL. RESULTS: Before transplantation few, small mononuclear osteoclasts formed (F-actin ring-positive cells, co-localizing with vitronectin receptor [alphavbeta3 integrin] and TRACP) associated with occasional, small resorption lacunae. Low levels of collagen C-terminal telopeptide (CTx) fragments were released from these cultures as assessed by ELISA (CrossLaps; patient, 12.85 nM; control, 448.6 nM). In contrast, osteoclasts formed in cultures after transplantation formed to a similar degree to control cultures from healthy individuals: large numbers of osteoclasts containing numerous nuclei were present, and approximately 50% of the surface of bone slices was resorbed, associated with intermediate levels of collagen fragment release (116.48 nM). The culture data reflect the histopathology and radiological findings and also support previous studies showing that neither M-CSF nor RANKL rescues osteoclast-poor osteopetrosis. CONCLUSIONS: This is the first case reported in which a successful hematopoietic engraftment failed to correct an osteopetrotic skeletal defect, and this finding may be credited to the age at which the child was transplanted.     

Congenitally osteopetrotic (op/op) mice are not cured by transplants of spleen or bone marrow cells from normal littermates

Congenital mammalian osteopetrosis is characterized by a generalized skeletal sclerosis due to reduced bone resorption by osteoclasts. This condition can be cured in several mutant strains of mice and rats by transplantation of spleen or bone marrow cells from normal littermates. The ability of this regimen to cure osteopetrosis in op/op mice was examined in 23 mice treated with spleen or bone marrow cells from normal littermates and followed for up to 80 days. In no instance was there radiographic or histologic evidence of removal of the excessive skeletal mass characteristic of the disease. These data show that spleen or bone marrow cells do not cure osteopetrosis in this mutation. Recent demonstrations that not all children with congenital osteopetrosis are cured by bone marrow transplants from HLA-matched donors suggest that the op/op mouse mutation may be a useful model system in which to develop alternate treatments.     

Osteoblast-like Cells Complete Osteoclastic Bone Resorption and Form New Mineralized Bone Matrix <Emphasis Type="Italic">In Vitro</Emphasis>

Bone remodeling involves old bone resorption by osteoclasts and new bone formation by osteoblasts. However, the precise cellular mechanisms underlying these consecutive events remain obscure. To address this question in vitro, we have established a cell culture model in which the resorption lacunae are first created by osteoclasts and osteoblast-like cells accomplish the subsequent bone formation. We isolated osteoclasts from rat bone marrow and cultured them on bovine bone slices for 48 hours to create resorption lacunae. After removing osteoclasts, confluent differentiated primary osteoblast cultures were trypsinized and the cells were replaced on the resorbed bone slices for up to 14 days. The cultures were then examined by confocal microscopy, field emission scanning electron microscopy (FESEM), and transmission electron microscopy (TEM). Our data suggest that after osteoclastic bone resorption, osteoblast-like cells, not macrophages, remove the remaining organic matrix in the lacuna. After cleaning the lacuna, osteoblast-like cells deposit new collagen fibrils at the bottom of the lacuna and calcify the newly formed matrix only, as visualized by labeled tetracycline accumulation merely in the lacuna during the osteoblast culture. Furthermore, an electron-dense layer rich in osteopontin separates the old and new matrices suggesting formation of the cement line. Since the morphology of the newly formed matrix is similar to the natural bone with respect to the cement line and osteoid formation as well as matrix mineralization, the present method provides for the first time a powerful in vitro method to study the cellular mechanisms leading to bone remodeling also in vivo.     

鸡破骨细胞分离培养方法的建立

为了寻找一种获得大量、纯化、有活力的破骨细胞的方法，我们对已经建立的兔破骨细胞体外分离培养方法的基础上加以改进。利用冲洗的方法，从２８天的鸡的长骨中得到细胞团１破骨细胞后，又对鸡的长骨相继进行胶原酶和胰蛋白酶的消化，得到细胞团２和细胞团３破骨细胞。将这些分离的细胞与盖玻片或骨磨片共同培养，通过相差显微镜观察到：这些分离的多核巨细胞能够运动，并能在骨磨片上形成吸收陷窝。另外，这些细胞对酸性磷酸酶染色呈阳性反应，而酸性磷酸酶是鉴别破骨细胞的标志。表明此分离培养鸡破骨细胞的实验技术是成功的。通过此方法获得的鸡破骨细胞比用以往方法获得的兔破骨细胞量多，且活力强。本方法的建立，为进一步研究骨吸收机理奠定了基础。     

Study of immunoelectron microscopic localization of cathepsin K in osteoclasts and other bone cells in the mouse femur

The localization of cathepsin K protein in mouse osteoclasts was examined by immunolight and immunoelectron microscopy using the avidin-biotin-peroxidase complex method with anti-cathepsin K (mouse) antibody. With light microscopy, a strong immunoreaction for cathepsin K was found extracellularly along the bone and cartilage resorption lacunae and detected intracellularly in vesicles, granules, and vacuoles throughout the cytoplasm of multinuclear osteoclasts and chondroclasts attached to the surface of the bone or cartilage. Mononuclear cells, probably preosteoclasts, some distance from the bone also contained a few cathepsin K-positive vesicles and granules. Cathepsin K was sometimes found in the cisternal spaces of the rough endoplasmic reticulum and vesicles of the Golgi apparatus with electron microscopy of the basolateral region of the osteoclasts. Cathepsin K-positive vesicles and granules as lysosomal compartments were present in various stages of fusion with vacuoles as endosomal compartments that contained fragmented cathepsin K-negative fibril-like structures. Some of the vacuoles (endolysosomes), which seemed to be formed by this process of fusion, contained cathepsin K-positive vesicles and fibril-like structures that did not show the regular cross striation of type I collagen fibrils. In the apical region of the osteoclasts, cathepsin K-positive vesicles and pits had already fused with or were in the process of fusing with the ampullar extracellular spaces. There were large deposits of cathepsin K on fragmented fibril-like structures without regular cross striation in the extracellular spaces, as well as on and between the cytoplasmic processes of the ruffled border. There were also extensive deposits of cathepsin K on the type I collagen fibrils with cross striation in the bone resorption lacunae. Osteoblasts and osteocytes were negative for cathepsin K. In the immunocytochemical controls, no immunoreaction was found in the osteoclasts or preosteoclasts, or on the collagen fibrils in the resorption lacunae. The results indicate that cathepsin K is produced in mature osteoclasts attached to the bone and secreted into the bone resorption lacunae. The findings suggest that cathepsin K participates in the extracellular degradation of collagen fibrils in the resorption lacunae and in the subsequent degradation of the fragmented fibrils in the endolysosomes. It is also suggested that cathepsin K degrades the organic cartilage matrix.     

Osteoclasts derive from hematopoietic stem cells according to marker, giant lysosomes of beige mice

To ascertain the origin of multinucleated osteoclasts from hematopoietic stem cells, giant lysosomes peculiar to cells of beige mice (bg bg) were used as marker cells of that provenance. Radiation chimeras were established reciprocally between bg bg mice and osteopetrotic mi mi mice with defective osteoclasts. As a result, all the derivative cells of the hematopoietic stem cell would depend on the donor's cell line, whereas osteogenesis would remain the province of the host. It was affirmed in the chimeras mi mi/bg bg that the osteopetrosis was cured within six weeks. Thereafter the definitive osteoclasts of the chimeras contained giant lysosomes attributable to the beige cell line. However, the cure was well advanced before donor osteoclasts were prominent, for which several reasons are offered. In the mouse chimeras, bg bg/mi mi, there was a delay of some six weeks before osteopetrosis became evident, histologically before radiologically, at the major metaphyseal growth centers. During the period one to two months after establishment, osteoclasts appeared to be a mixture of two cell lines according to quantitative assessments for giant lysosomes. Assessments consisted of measurements of the percentage area of osteoclasts occupied by lysosomes over 1 micrometer diameter. The means were 0.018% +/- 0.008% for nonbeige stock and 2.09% +/- 0.58% for beige stock.     

Adult osteosclerosis

Quantitative bone histology was carried out in five osteosclerotic adults. The bone was extremely hard in all patients, and open biopsy was usually required. One patient, aged 18 years, presented with hypoplastic anemia, and the most probable explanation for the osteosclerosis is a marrow stem cell defect leading to defective osteoclasts. Another had the dominant form of osteopetrosis. Her bone contained cartilage remnants, and there were many large, morphologically abnormal osteoclasts, which lacked normal cytoplasmic acid phosphatase activity. The third patient had chronic renal failure and osteomalacia; here the increased bone mass might have resulted from an inability of normal osteoclasts to resorb bone, due to the surface coating of osteoid, though an earlier increase of bone formation cannot be excluded. The fourth patient, who suffered from systemic mastocytosis, had high turnover bone, with greatly, increased bone formation. The fifth patient, with fluorosis of bone, also had increased bone formation and resorption, the process being much more pronounced in the head of her pathologically fractured femur than it was in the iliac crest. In this patient some osteoclasts had reduced acid phosphatase activity and long cytoplasmic extensions, both changes similar to those observed in diphosphonate-treated animals. Very diverse processes can result in the increased cancellous bone mass producing the radiographic appearance of diffuse osteosclerosis.     

Osteoclast populations in congenital 0steopetrosis: Additional evidence of heterogeneity

Osteopetrosis is a metabolic bone disease characterized by excessive accumulation of skeletal mass due to a reduction in bone resorption. The pathogenesis of osteopetrosis is reduced osteoclast function. Reports of osteoclast numbers in several mammalian mutations exhibiting osteopetrosis have shown them to be increased, decreased, or normal in numbers. The present investigation quantitated the osteoclast populations and examined the cytology of osteoclasts by light microscopy in calvarial and tibial sites in one rabbit and two mouse mutations and compared them with their normal littermates.Our observations show that osteoclast numbers are, depending: on the particular mutation, increased, decreased, or comparable to those found in normal littermates. In each mutation, however, osteoclasts fail to exhibit the cytoplasmic vacuolization next to bone surfaces seen in normal osteoclasts. These data provide additional evidence of heterogeneity in the congenital mammalian osteopetroses and suggest that these mutations may be significant sources of new information about the biology of osteoclasts.     

Osteopetrosis

Osteopetrosis is a rare skeletal condition characterized by skeletal sclerosis caused by aberrant osteoclast-mediated bone resorption. Three clinically distinct forms of osteopetrosis are recognized--the infantile malignant autosomal recessive form, the intermediate autosomal recessive form, and the adult benign autosomal dominant form. The disease represents a spectrum of clinical variants because of the heterogeneity of genetic defects resulting in osteoclast dysfunction. The pathogenic defects may be intrinsic to either the osteoclast-monocyte lineage or the mesenchymal cells that constitute the microenvironment that supports osteoclast ontogeny and activation. Implicated factors include specific proto-oncogenes, growth factors, and immune regulators. A subset of patients with the intermediate autosomal recessive form has been characterized with carbonic anhydrase II isoenzyme deficiency. Management of patients with osteopetrosis requires a comprehensive approach to characteristic clinical problems including hematologic and metabolic abnormalities, fractures, deformity, back pain, bone pain, osteomyelitis, and neurologic sequelae. Medical treatment of osteopetrosis is based on efforts to stimulate host osteoclasts or provide an alternative source of osteoclasts. Stimulation of host osteoclasts has been attempted with calcium restriction, calcitrol, steroids, parathyroid hormone, and interferon. Bone marrow transplant has been used with cure for infantile malignant osteopetrosis. As osteopetrosis likely represents a spectrum of underlying etiologies resulting in osteoclast dysfunction, effective therapies most likely need to be individualized.     

Visualizing mineral binding and uptake of bisphosphonate by osteoclasts and non-resorbing cells

Bisphosphonates (BPs) target bone due to their high affinity for calcium ions. During osteoclastic resorption, these drugs are released from the acidified bone surface and taken up by osteoclasts, where they act by inhibiting the prenylation of small GTPases essential for osteoclast function. However, it remains unclear exactly how osteoclasts internalise BPs from bone and whether other cells in the bone microenvironment can also take up BPs from the bone surface. We have investigated this using a novel fluorescently-labelled alendronate analogue (FL-ALN), and by examining changes in protein prenylation following treatment of cells with risedronate (RIS). Confocal microscopic analysis showed that FL-ALN was efficiently internalised from solution or from the surface of dentine by resorbing osteoclasts into intracellular vesicles. Accordingly, unprenylated Rap1A accumulated to the same extent whether osteoclasts were cultured on RIS-coated dentine or with RIS in solution. By contrast, J774 macrophages internalised FL-ALN and RIS from solution, but took up comparatively little from dentine, due to their inability to resorb the mineral. Calvarial osteoblasts and MCF-7 tumour cells internalised even less FL-ALN and RIS, both from solution and from the surface of dentine. Accordingly, the viability of J774 and MCF-7 cells was drastically reduced when cultured with RIS in solution, but not when cultured on dentine pre-coated with RIS. However, when J774 macrophages were co-cultured with rabbit osteoclasts, J774 cells that were adjacent to resorbing osteoclasts frequently internalised more FL-ALN than J774 cells more distant from osteoclasts. This was possibly a result of increased availability of BP to these J774 cells due to transcytosis through osteoclasts, since FL-ALN partially co-localised with trancytosed, resorbed matrix protein within osteoclasts. In addition, J774 cells occupying resorption pits internalised more FL-ALN than those on unresorbed surfaces. These data demonstrate that osteoclasts are able to take up large amounts of BP, due to their ability to release the BP from the dentine surface during resorption. By contrast, non-resorbing cells take up only small amounts of BP that becomes available due to natural desorption from the dentine surface. However, BP uptake by non-resorbing cells can be increased when cultured in the presence of resorbing osteoclasts.     

Electron microscopy of avian osteopetrosis induced by retrovirus MAV.2-O

Diaphyseal tibial bone of 12.5-13-day and 19-day-old embryos and 20-day-old hatched chicks infected with retrovirus MAV.2-O were examined by transmission electron microscopy. The viruses were associated with lining osteoblasts and osteocytes. Whereas the infection of the osteoblast layer seemed to be a transient stage, virus association with osteocytes was a constant and main ultrastructural feature. The viruses were found either in the osteoid or in the periosteocytic space of the bone lacunae. They arose from dense cytoplasmic areas located near the cell plasmalemma via a budding process. The newly budded virus particles often had a large tail or a fine stalk-like process lost in the extracellular space. The viruses underwent calcification by deposition of inorganic material and were incorporated in the bone trabeculae. No production of virus was observed in typical osteoclasts with well-differentiated ruffled borders. The viral-induced avian osteopetrosis seemed to result from increased bone deposition through stimulation of osteoblast and osteocyte activities, whereas osteoclastic bone resorption seemed to be undisturbed.     

Administration of colony stimulating factor-1 corrects some macrophage, dental, and skeletal defects in an osteopetrotic mutation (toothless, tl) in the rat.

The toothless (tl/tl) mutation in the rat results in a paucity of osteoclasts and osteopetrosis that cannot be corrected by bone marrow transplantation. In the present study we demonstrate that tl/tl rats also have profound deficiencies of femoral, peritoneal, and pleural cavity macrophages. Furthermore, the macrophage colony stimulating activity of post-endotoxin sera from tl/tl rats is substantially reduced, suggesting that, as in the case of the op mutation in mice, the basis of the tl mutation is a deficiency of the macrophage growth factor, colony stimulating factor-1 (CSF-1). Consistent with this suggestion, treatment of tl/tl rats from birth for up to six weeks with CSF-1 reduced the osteopetrosis, increased body weight, and permitted tooth eruption. In addition, CSF-1 treatment induced large numbers of osteoclasts in tl/tl bones and macrophages in the peritoneal cavity and bone marrow. Persistence of metaphyseal sclerosis, however, indicated that the disease was not totally corrected by this treatment. These studies indicate that the basis of the tl mutation is most likely another CSF-1 deficiency, and further emphasize the role of this growth factor in osteoclast differentiation.     

Familial expansile osteolysis: a morphological, histomorphometric and serological study.

Biopsies from the diseased bones of patients with familial expansile osteolysis (FEO) were examined by light and electron microscopy. Focal concentrations of multinuclear osteoclasts were present, and these contained viral-like microcylindrical inclusions which appeared exclusive to their nuclei. No consistent relationship was found between osteoclast size and the number of osteoclast nuclei containing microcylindrical inclusions. Quantitative histomorphometry showed evidence of increased bone remodelling with high bone cell densities and a decrease of the reversal period in bone remodelling. The lesions contained prominent woven bone and fibrovascular tissue, together with mononuclear cells and adipocytes. Little bone was found in the most radiolucent lesions, which were almost totally occupied by adipocytes and fibrovascular tissue. Serology did not reveal any significant differences between the viral antibody titres of patients and their age- and sex-matched controls. The present study suggests that intranuclear viral-like microcylindrical inclusions of osteoclasts are not a specific feature of Paget's disease, and are found in other disorders of osteoclast function, including pycnodysostosis, osteopetrosis, giant cell tumours, and familial expansile osteolysis.