Relationship between porotic changes in alveolar bone and spinal osteoporosis.

Epidemiological studies have shown that post-menopausal women who do not use an estrogen supplement have fewer teeth than those who do. We hypothesized that changes in the dentition of post-menopausal women might be due to alveolar bone alterations by estrogen deficiency. To clarify this, we analyzed the microstructural alveolar bone changes in ovariectomized monkeys and compared these with their lumbar bone mineral density. The % of baseline bone mineral density showed a significant decrease in the ovariectomized group as compared with the controls. The second-molar interradicular septa in ovariectomized monkeys showed a significantly decreased nodes number, cortices number, and an increased structural model index value. More pores were seen in the ovariectomized group at the top of the septa. This study demonstrated that, in such monkeys, estrogen deficiency led to fragility of the trabecular structure of the molar alveolar bone, and such fragility was inversely correlated with lumbar bone mineral density.

Role of stromal cells in osteoclast differentiation in bone marrow.

Bone marrow stromal cells have been considered to play an important role in osteoclast differentiation. However, the interaction of these cells in vivo has not been clearly demonstrated. To clarify this, we examined the distribution of alkaline phosphatase (ALPase) and tartrate-resistant acid phosphatase (TRAPase) activities as markers of osteoblastic and osteoclastic cells, respectively. Rat tibiae were fixed and embedded in Technovit 8100 or paraffin. ALPase and TRAPase activities were detected simultaneously on a plastic section by the azo-dye method. ALPase activity was detected on the plasma membranes of osteoblasts and some bone marrow fibroblastic stromal cells. These ALPase-positive cells were connected to each other by cytoplasmic processes, forming a cellular network in bone marrow. The ALPase activity of fibroblastic stromal cells tended to be stronger in those cells close to the bone surface than in the cells in the center of bone marrow. Reticular fibers in bone marrow were found to form a network. The ALPase-positive fibroblastic stromal cells may be reticular cells, because the localization of those cells was in accord with the localization of reticular fibers. The TRAPase-positive mononuclear cells and osteoclasts were mostly observed to be associated with the intensely ALPase-positive fibroblastic stromal cells. Immunoreactivity of osteoclast differentiation factor (ODF) was found in the fibroblastic stromal cells. These findings suggest that the network of ALPase-positive fibroblastic stromal cells in bone marrow serves as a guide for the migration of osteoclast precursor cells toward the bone surface, and may control the differentiation and activity of osteoclasts.

Expression of osteopontin in gentamicin-induced acute tubular necrosis and its recovery process.

BACKGROUND: There is controversy regarding the exact localization and roles of osteopontin (OPN), a multipotential chemokine, in renal injury. There is little information on the expression and role of OPN in gentamicin-induced acute tubular necrosis (ATN) and its recovery process. METHODS: A severe ATN model was made using male Wistar rats by injecting gentamicin (150 mg/kg/day) for five days and limiting the provision of water. The expression and localization of OPN mRNA and protein, ED1 as a macrophage marker, proliferating cellular nuclear antigen (PCNA), CD44 as an OPN receptor, megalin as a proximal tubule marker, and their relationships to each other were examined from the early tubular necrotic period to the late recovery period by Northern blotting, in situ hybridization, and double immunohistochemical staining. RESULTS: In the gentamicin group, OPN mRNA and protein were expressed in only the PCNA-positive proliferating cortical distal tubules, not in the necrotic proximal tubules, until day 6 after the first administration, but were found markedly in PCNA-positive regenerative proximal and distal tubules on days 10, 15, and 30. The localization of PCNA-positive cells was almost always accompanied with the up-regulated expression of OPN using quantitative analysis (P < 0.01). CD44 expression was markedly up-regulated in the renal cortical tubular epithelium from days 6 to 30. In the control group, no expression of OPN and CD44 in the cortical area was found throughout the experimental period. CONCLUSIONS: These results suggested that OPN is related to the proliferation and regeneration of tubular epithelial cells after tubular damage.

Tensile stress induces bone morphogenetic protein 4 in preosteoblastic and fibroblastic cells, which later differentiate into osteoblasts leading to osteogenesis in the mouse calvariae in organ culture.

Mechanical stress is an important factor controlling bone remodeling, which maintains proper bone morphology and functions. However, the mechanism by which mechanical stress is transduced into biological stimuli remains unclear. Therefore, the purpose of this study is to examine how gene expression changes with osteoblast differentiation and which cells differentiate into osteoblasts. Tensile stress was applied to the cranial suture of neonatal mouse calvaria in a culture by means of helical springs. The suture was extended gradually, displaying a marked increase in cell number including osteoblasts. A histochemical study showed that this osteoblast differentiation began in the neighborhood of the existing osteoblasts, which can be seen by 3 h. The site of osteoblast differentiation moved with time toward the center of the suture, which resulted in an extension of osteoid. Scattered areas of the extended osteoid were calcified by 48 h. Reverse-transcription polymerase chain reaction (RT-PCR) revealed that tensile stress increased bone morphogenetic protein 4 (BMP-4) gene expression by 6 h and it remained elevated thereafter. This was caused by the induction of the gene in preosteoblastic cells in the neighborhood of osteoblasts and adjacent spindle-shaped fibroblastic cells. These changes were evident as early as 3 h and continued moving toward the center of the suture. The expression of Cbfa1/Osf-2, an osteoblast-specific transcription factor, followed that of BMP-4 and those cells positive with these genes appeared to differentiate into osteoblasts. These results suggest that BMP-4 may play a pivotal role by acting as an autocrine and a paracrine factor for recruiting osteoblasts in tensile stress-induced osteogenesis.

[The effects of calcitonin on osteoclasts morphology].

Calcitonin causes acute and dramatic morphological changes in bone resorbing osteoclasts. The most striking change is the destruction of clear zones and ruffled borders. These structures are formed by the interaction of cytoskeletons and signals transduced from cell-matrix adhesion complexes. Further studies on the structures of cytoskeleton and adhesion complexes in osteoclasts are necessary to elucidate the effects of calcitonin on the morphology of osteoclasts.

Tensile stress induced osteoblast differentiation and osteogenesis in mouse calvarial suture in culture: possible involvement of BMP-4 and other genes.

Mechanical stress is one of the most potent inducer of bone formation. The mechanism by which cells receive and transduce the signal into osteogenesis, however, remains unknown. Previous studies have demonstrated that mechanical stress causes changes in expression levels of many genes in osteoblasts and osteocytes both in vivo and in vitro. However, none of these changes are specific to bone cells. Moreover it is not clear which types of cells contributed to the increased osteoblasts induced by mechanical stress. The purpose of this study, therefore, was to identify which cells differentiate into osteoblasts and to examine how the expression of genes that are specific to osteogenic cells changes.

Effects of continuous calcitonin treatment on osteoclast-like cell development and calcitonin receptor expression in mouse bone marrow cultures.

Continuous treatment with calcitonin (CT) to inhibit osteoclastic bone resorption results in acquired resistance. The mechanisms of this "escape" phenomenon are not yet established. The aim of this study was to examine the effects of continuous treatment with CT on the generation of osteoclasts and calcitonin receptor (CTR) expression in mouse bone marrow cultures. This was done by daily CT treatment of mouse bone marrow cultures from day 0, when only undifferentiated mononuclear precursors of osteoclast-like cells were present, or commencing from day 6, when differentiated osteoclast-like cells were abundant. The response to CT treatment was determined by quantitation of cells positive for tartrate-resistant acid phosphatase (TRAP) and binding of 125I-salmon CT. Calcitonin receptor and TRAP mRNA levels were determined using semi-quantitative reverse transcription/polymerase chain reaction. When cultures were treated with CT from day 0, TRAP-positive multinucleated cells appeared. These cells expressed only very low levels of CTR or CTR mRNA and were morphologically indistinguishable from osteoclast-like cells formed in control cultures. They also displayed the ability to resorb bone. Continuous CT treatment of cultures from day 6 rapidly reduced the CTR mRNA levels, with a t1/2 of 6 to 12 h, and these levels remained low thereafter. 125I-salmon CT binding capacity, as determined by autoradiography, was lost in parallel. These effects were specific for the CTR since there was no consistent effect on TRAP mRNA levels. Based on these data, we suggest that the "escape" phenomenon may result from a prolonged CT-induced loss of CT responsiveness due, at least in part, both to reduced synthesis of CTR, and to the appearance in bone of CTR-deficient osteoclasts.

Short treatment of osteoclasts in bone marrow culture with calcitonin causes prolonged suppression of calcitonin receptor mRNA.

Cells exhibiting osteoclast characteristics of calcitonin receptors (CTRs) and tartrate-resistant acid phosphatase (TRAP) histochemistry are formed in murine bone marrow cultures treated with 1 alpha,25-dihydroxyvitamin D3 [1,25-(OH)2D3]. We have previously demonstrated that CTR mRNA is highly expressed in these cultures. The aim of this study was to investigate homologous regulation of the CTR, and regulation of TRAP expression in osteoclast-like cells after brief treatment with salmon CT (sCT). Murine bone marrow cells were cultured in 9 cm dishes in the presence of 10 nmol/L 1,25-(OH)2D3. On day 6 of culture, when multinucleated cells were abundant, the cells were treated with 1 nmol/L sCT for 1 h. Both control and treated cells were then harvested at intervals up to 72 h posttreatment, and both CTR and TRAP mRNA levels assessed by reverse-transcription PCR (RT-PCR). In parallel cultures, cells with CTR expression detectable by autoradiography, and TRAP positivity by histochemistry, were counted. The effects of brief sCT treatment could be seen 6 h after treatment when the CTR RT-PCR product was markedly reduced. Total recovery of CTR mRNA levels had not occurred even after 72 h. Calcitonin treatment had little effect on TRAP mRNA levels. There was no difference in the numbers of multinucleated TRAP(+) osteoclast-like cells between treated and control cells. These results indicate that brief sCT treatment, while not influencing multinucleated osteoclast-like cell number, causes specific, acute reduction of CTR mRNA in bone marrow culture-derived osteoclasts. The prolonged decrease in CTR mRNA levels suggests that recovery may require new osteoclast formation, and indicates that regulation of the CTR in cells of the osteoclast lineage is different from that in nonosteoclastic cells and tissues.

Heterogeneity of the calcitonin receptor: functional aspects in osteoclasts and other sites.

The recent cloning of the calcitonin receptor reveals it as a member of a new family of 7-transmembrane, G protein-linked receptors. Data from rat, mouse and human receptor cloning reveal that in each of these species the receptor exists in more than one form, most likely the result of alternate, splicing. In the rat, the two forms are C1a and C1b, the latter differing from C1a in that it contains a 37-amino acid insert in the second extracellular domain. The two receptor isoforms differ in their distribution in vivo, with the C1b predominantly in the central nervous system and C1a in other tissues. Both forms have been shown to be present in mature and developing osteoclasts, with the C1a isoform predominating. The two isoforms differ in their kinetics and pharmacological properties, with C1b being virtually unable to bind the human and rat calcitonins but readily binding salmon calcitonin. It will be important to elucidate the physiological significance of the structural heterogeneity of the calcitonin receptor.

Calcitonin receptor isoforms in mouse and rat osteoclasts.

Calcitonin receptors (CTRs) from several species have recently been cloned and shown to belong to the 7 transmembrane domain class of receptor. We have identified two CTR isoforms in the rat, termed C1a and C1b, identical except for a 37-amino-acid insert in the putative second extracellular domain of C1b. To examine the CTR isoforms expressed in rat and mouse osteoclasts and the time course of their appearance in culture, bone marrow cells were cultured from C57/Bl6J mice and osteoclasts were isolated from newborn rat long bones. CTR-bearing cells were detected by autoradiography of 125I-salmon CT binding, and cultures were stained for tartrate-resistant acid phosphatase (TRAP). RNA was extracted from parallel cultures, and CTR mRNA was detected by Northern blot analysis, using a rat digoxigenin-labeled riboprobe. Characterization of mRNA for the CTR isoforms was by reverse transcription-polymerase chain reaction (RT-PCR) using primer sets and oligonucleotide probes specific for the two rat receptor isoforms. In mouse marrow cultures, TRAP positive mononucleated cells were present by day 2 of culture at which time CTR positive cells were few. Multinucleated cells with both these markers were seen only from day 4 and later. By Northern analysis of total RNA, a band of approximately 4 kb could be detected in day 4 and later cultures. RT-PCR showed that mouse homologs of both C1a and C1b mRNA species were expressed early in cultures of mouse osteoclasts, although at each time C1a appeared to predominate.(ABSTRACT TRUNCATED AT 250 WORDS)

Histochemical and autoradiographic studies on elcatonin internalization and intracellular movement in osteoclasts.

The binding sites and chronologic localization of elcatonin (eCT) in osteoclasts were examined by autoradiography using [125I]elcatonin (125I-eCT). In addition to the structural changes induced by calcitonin (CT) reported so far, changes were also observed in the structure of Golgi apparatus. These changes continued until 48-72 h after incubation with eCT. Developed silver grains of 125I-eCT were localized into multinucleated osteoclasts and mononuclear cells that were ultrastructurally defined as "preosteoclasts." The silver grains located on plasma membranes of those cells and were then internalized; they accumulated, especially in the Golgi apparatus, and remained for 48-72 h. A few silver grains were also detected in lysosomes and small vesicles. The decrease in the number of silver grains in the Golgi apparatus accompanied the recovery of osteoclast structures--Golgi apparatus and then ruffled borders. These findings suggest that (1) CT especially inhibits the sorting function of Golgi apparatus in osteoclasts, resulting in prolonged retention of CT in this organelle. (2) The CT in Golgi apparatus may keep its activity and cause the prolonged effect of CT on osteoclast activity.