Histological and elemental analyses of impaired bone mineralization in klotho-deficient mice

The klotho gene-deficient mouse is known as an animal model for an accelerated gerontic state, mimicking osteoporosis, skin atrophy, ectopic calcification, and gonadal dysplasia. To elucidate the influence of klotho deficiency on bone mineralization, we examined the ultrastructures of osteoblasts and bone matrices in addition to performing the elemental mapping of calcium, phosphorus, and magnesium in the bone. Under anesthesia, 4- and 5-week-old klotho-deficient mice (klotho(-/-)mice) and their wild-type littermates were perfused with either 4% paraformaldehyde for light microscopic observation or 4% paraformaldehyde and 0.0125% glutaraldehyde for electron microscopic observation. The femurs and tibiae were processed for both observations. Paraffin sections were subject to alkaline phosphatase and tartrate resistant acid phosphatase histochemistry. Semithin and ultrathin sections obtained from epoxy resin-embedded specimens were used for detecting mineralization - according to von Kossa's staining method - and for elemental mapping by electron probe micro-analyzer, respectively. Alkaline phosphatase-positive plump osteoblasts adjacent to the growth plate normally developed cell organelles in the klotho(-/-)metaphyses. This, however, contrasted with the flattened osteoblasts covering the metaphyseal trabeculae and accompanied by small tartrate resistant acid phosphatase-positive osteoclasts. The wild-type mice displayed the mineralized matrix at the zone of hypertrophic chondrocyte of the growth plate and well-mineralized metaphyseal trabeculae parallel to the longitudinal axis of the bone. Alternatively, the klotho(-/-)mice demonstrated a thick mineralized matrix from the proliferative zone of the growth plate as well as the large non-mineralized area in the metaphyseal trabeculae. Consistently, electron probe micro-analysis verified sporadic distributions of higher or lower concentrations of calcium and phosphorus in each trabecule of the klotho(-/-)mice. The distribution of magnesium, however, was almost uniform. Under transmission electron microscopy, osteoblasts on the metaphyseal trabeculae displayed less-developed cell organelles in the klotho(-/-)mice. Thus, the klotho deficiency appears not only to reduce osteoblastic population, but also to disturb bone mineralization.     

Histological and immunohistochemical changes in the submandibular gland in klotho-deficient mice

The submandibular gland (SMG) has been regarded as an age-stable organ in spite of reports on its structural changes with aging. Although the klotho gene is involved in aging, little information is available regarding its effects on morphological changes of SMGs. The present study examined the histological and immunohistochemical features of SMGs in klotho-deficient mice--which are well-established aging models--by immunohistochemical and histochemical techniques. Five kinds of cellular markers--against NGF, EGF, Mnand Cu/Zn-SOD, and RITC-conjugated phalloidin--were used for the identification of cell types. In klotho-deficient mice, the SMGs lost their granular ducts and each lobe diminished. The granular duct showed strong immunoreactivities for NGF and EGF in the wild-type mice, but the NGF- and EGF-immunopositive ducts decreased in number remarkably in klotho-deficient mice. Interestingly, instead of a loss of the granular duct, the striated duct located on the distal portion in the homozygous mice came to show NGF- and EGF-immunoreactions. Neither Mn- and Cu/Zn-SOD immunoreactivities in the duct system nor the phalloidin- reaction in the myoepithelial cells differed between the wild-type and klotho-deficient mice. Our findings suggest that the klotho gene inhibited the differentiation of the granular duct from the striated duct due to the repression and/or down-regulation of sexual and growth hormones.     

Some osteocytes released from their lacunae are embedded again in the bone and not engulfed by osteoclasts during bone remodeling

It is generally accepted that osteocytes derive from osteoblasts that have secreted the bone around themselves. Osteocytes are cells embedded in the lacunae in the bone, and they are characteristically in contact with other cells by many slender cytoplasmic processes in canaliculi. During bone remodeling, many osteocytes in the bone are released from their lacunae by osteoclasts; however it remains unclear what happens to these released osteocytes. The cortical bone of the rat mandibular body was used in this study. Mandibles were fixed, decalcified, and then embedded in Epon 812. Specimens were sectioned in the frontal direction into serial 0.5 microm-thick semithin or 0.1 microm-thick ultrathin sections, and then examined by light or transmission electron microscopy. Cells that fitted in the osteocytic lacunae with canaliculi extending to the bone were identified as osteocytes in this study. Among many osteocytes released by osteoclasts in cutting cones, there were osteocytes half-released from their lacunae. These cells fitted in their lacunae with canaliculi extending to the bone and showed developed cell organelles in the cytoplasm. In closing cones, many osteocytes were situated in the bone away from cement lines; however, there were half-embedded osteocytes in the bone formed on cement lines. These cells fitted in their lacunae with canaliculi extending to the bone formed below cement lines and showed developed cell organelles in the cytoplasm. These results show that half-embedded osteocytes in closing cones derive from half-released osteocytes in cutting cones. Osteocytes encircled by osteoclasts were sometimes observed on one section, but serial sections showed that these osteocytes fitted in their remaining lacunae in the bone on other sections. This shows that not all osteocytes released from their lacunae are engulfed by osteoclasts. Consequently, the present results suggests that some osteocytes released from their lacunae are embedded again in the bone and not engulfed by osteoclasts during bone remodeling.     

Recent progress in studies on osteocytes--osteocytes and mechanical stress

Although osteocytes are of the most abundant cells in bone, our knowledge about the role of osteocytes in bone metabolism is still poor compared with that about osteoblasts and osteoclasts, both being on the surface of bone. Osteocytes are terminally differentiated bone-forming cells. During bone formation, some of the osteoblasts lining the surface of bone are incorporated into the newly formed osteoid matrix and become osteocytes, while the other osteoblasts remain on the surface as lining cells. During this transition from osteoblasts to osteocytes, the cells lose numerous osteoblastic phenotypes and acquire osteocytic characteristics such as high expression of osteocalcin and particularly their specific morphology. Osteocytes are connected with each other in bone and with osteoblasts on the bone surface through canaliculi, forming cellular networks; and gap-junctions present at the contact sites mediate their intercellular communication. Several roles of osteocytes in bone have been proposed so far. Of them, based on the morphological characteristics of osteocytes, sensation of mechanical stress loaded onto bone is suspected to be one of their functions. One of the mechanical stresses on bone is fluid shear stress. Between the osteocyte's plasma membrane and the bone matrix is the periosteocytic space. This space exists both in the lacunae and in the canaliculi, and it is filled with extracellular fluid (ECF). Application of mechanical stress to bone locally deforms the tissue. This periodical deformation subsequently causes an increase in the flow of ECF in the periosteocytic space, resulting in shear stress on the surface of the osteocytes. Experimental studies demonstrated that bone cells were equivalently or more sensitive to the fluid shear stress than epithelial cells. Osteocytic cells cultured enhanced expression of prostaglandin (PG) G/H synthase-2 (COX-2) mRNA in response to shear stress. PGE2 is a potent regulator of proliferation and function of osteoblasts and osteoclasts. Therefore, a metabolic response by osteoblasts and osteoclasts lining the bone surface may be caused by PGE2 produced by osteocytes in response to shear stress when the prostanoid reaches the surface through the canaliculi. In conclusion, osteocytes play an important role in sensing extracellular mechanical stress, and the mechanical signals mediated by osteocytes may regulate the overall metabolism of cells in bone tissue.     

Immunolocalization of DMP1 and sclerostin in the epiphyseal trabecule and diaphyseal cortical bone of osteoprotegerin deficient mice

In order to define the osteocytic function in accelerated bone remodeling, we examined the distribution of the osteocytic lacunar-canalicular system (OLCS) and osteocyte-secreting molecules--dentin matrix protein (DMP) 1 and sclerostin--in the epiphyses and cortical bones of osteoprotegerin deficient (OPG(-/-)) mice. Silver impregnation visualized a well-arranged OLCS in the wild-type epiphyses and cortical bone, whereas OPG(-/-) mice had an irregular OLCS in the epiphyses, but well-arranged canaliculi in the cortical bone. DMP1-positive osteocytes were evenly distributed throughout the wild-type epiphyses and cortical bone, as well as the OPG(-/-) cortical bone. However, OPG(-/-) epiphyses revealed weak DMP1-immunoreactivity. Thus, osteocytes appear to synthesize more DMP1 as the OLCS becomes regular. In contrast, sclerostin-immunoreactivity was significantly diminished in the OPG(-/-) epiphyses and cortical bone. In OPG(-/-) epiphyses and cortical bone, triple staining demonstrated few sclerostin-positive osteocytes in the periphery of a thick cell layer of alkaline phosphatase-positive osteoblasts and many tartrate resistant acid phosphatase-positive osteoclasts. Summarizing, the regular distribution of OLCS may affect DMP1 synthesis, while the cellular activities of osteoclasts and osteoblasts rather than the regularity of OLCS may ultimately influence sclerostin synthesis.     

A Morphological Analysis on the Osteocytic Lacunar Canalicular System in Bone Surrounding Dental Implants

Osseointegration is the most preferable interface of dental implants and newly formed bone. However, the cavity preparation for dental implants often gives rise to empty lacunae or pyknotic osteocytes in bone surrounding the dental implant. This study aimed to examine the chronological alternation of osteocytes in the bone surrounding the titanium implants using a rat model. The distribution of the osteocytic lacunar canalicular system (OLCS) in bone around the titanium implants was examined by silver impregnation according to Bodian's staining. We also performed double staining for alkaline phosphatase (ALP) and tartrate‐resistant acid phosphatase (TRAP), as well as immunohistochemistry for fibroblast growth factor (FGF) 23—a regulator for the serum concentration of phosphorus—and sclerostin, which has been shown to inhibit osteoblastic activities. Newly formed bone and the injured bone at the early stage exhibited an irregularly distributed OLCS and a few osteocytes positive for sclerostin or FGF23, therefore indicating immature bone. Osteocytes in the surrounding bone from Day 20 to Month 2 came to reveal an intense immunoreactivity for sclerostin. Later on, the physiological bone remodeling gradually replaced such immature bone into a compact profile bearing a regularly arranged OLCS. As the bone was remodeled, FGF23 immunoreactivity became more intense, but sclerostin became less so in the well‐arranged OLCS. In summary, it seems likely that OLCS in the bone surrounding the dental implants is damaged by cavity formation, but later gradually recovers as bone remodeling takes place, ultimately inducing mature bone. Anat Rec,, 2011. © 2011 Wiley‐Liss, Inc.     

Detailed Process of Bone Remodeling After Achievement of Osseointegration in a Rat Implantation Model

Osseointegration is regarded as the most appropriate implant‐bone interface in dental implantation. However, damaged bone with empty osteocytic lacunae driven by implant cavity preparation remains even after the completion of osseointegration. Although previous studies have suggested the occurrence of bone remodeling around implants, information on its detailed process is meager. Our study aimed to examine the fate of bone around titanium implants after the establishment of osseointegration on an animal model using the rat maxilla. Titanium implants were inserted into prepared bone cavities of the rat maxilla. Bone formation and maturation processes were evaluated by double staining for alkaline phosphatase and tartrate‐resistant acid phosphatase, immunohistochemistry for bone matrix proteins, vital staining with calcein, and elemental mapping with an electron probe microanalyzer. Bone with empty osteocytic lacunae or pyknosis remained between the intact preexisting and newly formed woven bones at post 1 month. It gradually decreased to disappear completely by active bone remodeling with a synchronized coordination of alkaline phosphatase‐positive osteoblasts and tartrate‐resistant acid phosphatase‐reactive osteoclasts at post 3 months, thickening to be replaced by compact bone. Dynamic labeling showed two clear lines in the newly formed bone around the implant through this experimental period. Electron probe microanalyzer analysis demonstrated chronologically increased levels of Ca and P in the newly formed bone identical to those in the surrounding bone at post 2.5 months. These findings indicate that continuous bone remodeling after the achievement of osseointegration causes replacement of the damaged bone by compact bone as well as an improvement in bone quality. Anat Rec, 2009. © 2008 Wiley‐Liss, Inc.     

Light- and electron-microscopic evaluation of the effects of 1,25-dihydroxyvitamin D3 on bone of thyroparathyroidectomized rats.

1,25-Dihydroxyvitamin D3 (1,25-[OH]2D3) was administered in doses of 1 (65 picomoles) or 5 (325 picomoles) units daily for 7 days to adult thyroparathyroidectomized rats fed a normal rodent diet. Both dose levels significantly increased serum calcium, decreased serum phosphorus, and increased urinary calcium and phosphorus concentrations. Numbers of osteoblasts were significantly increased in rats given 5 units 1,25-(OH)2D3. Ultrastructurally, these osteoblasts were larger and interpreted to be more active in bone matrix synthesis and mineralization, compared with osteoblasts in control rats. The number of osteoblasts in rats given 1 unit 1,25-(OH)2D3 was not increased, compared with controls, but they were morphologically similar to the osteoblasts in rats given 5 units 1,25-(OH)2D3. A granular electron-dense material, interpreted to be mineral, was present in the pericellular space of osteocytes in rats given 1 and 5 units 1,25-(OH)2D3. The size of osteocytes, organellar development, and contour of osteocytic lacunae were not affected by 1,25-(OH)2D3. The number of osteoclasts was not significantly elevated in 1,25-(OH)2D3-treated rats and their morphology was similar to that of osteoclasts in controls. It is concluded that in metaphyseal bone 1,25-(OH)2D3 increased the number and synthetic activity of osteoblasts without significantly enhancing osteoclasis or osteocytic osteolysis. This response was independent of parathyroid hormone and calcitonin in rats fed a normal diet.     

An electron microscopic investigation of human familial bone dysplasia. Inhibition of osteocytic osteolysis and induction of osteocytic formation of elastic fibers following calcitonin treatment.

Familial bone dysplasia with hyperphosphatasemia is characterized by excessive bone resorption early in life with resulting severe skeletal deformity. The disease can be ameliorated by treatment with human calcitonin. We have the studied the ultrastructure of bone from diseased patients before treatment and at intervals during 1 year of treatment with calcitonin. Pretreatment osteoblasts, osteoclasts, and osteocytes exhibited mitochondria which contained vast amounts of dense microcrystal deposits. Osteocytes were also distinguished by minimal organellar development. Osteoclasts were rare. Calcitonin treatment included a progressive development of a more normal bone structure. Intramitochondrial crystal deposits were absent in mitochondria of osteocytes and osteoclasts but were still present in mitochondria of osteoblasts. Surprisingly, the developing bony matrix during calcitonin treatment exhibited large numbers of elastic fibers. These appeared to develop normally in alignment with the surface membrane of osteocytes. Calcitonin treatment caused a proliferation of osteocyte organellar development. It is concluded that familial bone dysplasia is primarily a disease of osteocytes and that osteocytic activity is influenced by calcitonin.     

Histological identification of osteocytes in the allegedly acellular bone of the sea breams Acanthopagrus australis,Pagrus auratus and Rhabdosargus sarba (Sparidae,Perciformes, Teleostei)

The bone of advanced teleost fishes such as those of the family Sparidae is said to lack osteocytes or to be acellular. Acellularity has been determined by apparent lack of osteocyte lacunae. This study questions the validity of this criterion. Scanning electron and light microscopy of paraffin and resin sections were used to show that the sides of sea bream mandibles consist of laminar parallel-fibred bone that we call tubular bone, because it contains tubules, and localised regions of Sharpey fibre bone. Osteocytes lie along the walls of tubules that also contain collagen fibril bundles (T-fibres), or in the lumens of tubules that do not contain T-fibres. We show that the osteocytes are derived from osteoblasts. The T-fibre system is different from other fibre systems that have been described. The tubules enclose wide T-fibres (lenticular in cross-section, maximum width about 8 μm) that taper at their ends and continue as thin T-fibres (round in crosssection, about 2 μm wide). The T-fibres originate in the periosteum. In mature tubular bone, spaces of increasing size develop around the osteocytes. Osteocytes are released from the bone matrix and become postosteocytes or bone-lining cells. Secondary bone lines the largest spaces. In Sharpey fibre bone, small osteocytes in small lacunae (about 2 μm wide) are found in columns parallel to the Sharpey fibres. Large osteocytes are found in large round spaces and are much larger than comparable osteocytes in lacunae in the bone of the salmon Salmo salar. We conclude that an absence of visible or conventional osteocyte lacunae does not mean that the cells themselves are absent. There are cells and two types of collagen fibre bundle in the tubules. The cells are osteocytes derived from osteoblasts, and these osteocytes apparently resorb bone with the result that large amounts of bone are destroyed. “Acellular” tubular and Sharpey fibre bone are types of cellular bone that differ from each other and from conventional cellular bone.     

Premature aging in klotho mutant mice: cause or consequence?

Suitable mammalian models for aging with a wide range of age-associated pathology are desirable to study molecular mechanisms of human aging. Recent studies have identified that fibroblast growth factor 23 (Fgf-23) null mice and klotho hypomorphs could generate multiple premature aging-like features, including shortened lifespan, infertility, kyphosis, atherosclerosis, extensive soft tissue calcifications, skin atrophy, muscle wasting, T cell dysregulation, pulmonary emphysema, osteoporosis/osteopenia, abnormal mineral ion metabolism, and impaired vitamin-D homeostasis. The strikingly similar in vivo phenotypes of two separate genetically altered mouse lines implicate that the premature aging-like features may be partly regulated through a common signaling pathway involving both Fgf-23 and klotho; such speculation is experimentally supported by the observation that Fgf-23 requires klotho as a cofactor to exert its functions. Despite about 2000-fold higher serum levels of Fgf-23 in klotho mutants (compared to wild-type animals), these mice show physical, biochemical and morphological features similar to Fgf-23 null mice, but not as Fgf-23 transgenic mice; these observations suggest that widely encountered premature aging-like features in klotho mutant mice are due to the inability of Fgf-23 to exert its bioactivities in absence of klotho. The results of recent studies showing klotho as a cofactor in Fgf-23 signaling consequently explains that the premature aging-like features in klotho-deficient mice is not a primary cause, rather a consequence of lacking Fgf-23 activity. These understandings will help us to redefine the role of klotho as an aging factor.     

Dentine matrix protein 1 (DMP-1) is a marker of bone-forming tumours

Dentin matrix protein 1 (DMP-1) is highly expressed by osteocytes and is a non-collagenous matrix protein found in dentin and bone. In this study, we determined the expression of DMP-1 in mature and immature human bone and examined whether DMP-1 is useful in distinguishing osteoid/bone-forming tumours from other primary and secondary bone tumours. DMP-1 expression was immunohistochemically determined in paraffin sections of a wide range of benign and malignant primary bone tumours and tumour-like lesions (n?=?353). DMP-1 mRNA expression was also examined in osteosarcoma and fibrosarcoma cell lines as well as bone tumour specimens (n?=?5) using real-time PCR. In lamellar and woven bone, DMP-1 was expressed in the matrix around osteocyte lacunae and canaliculi; osteoblasts and other cell types in the bone were negative. Matrix staining of the osteoid and bone was seen in bone-forming tumours including osteoma, osteoid osteoma, osteoblastoma and osteosarcoma. DMP-1 staining was also seen in fibrous dysplasia, osteofibrous dysplasia and chondroblastoma and in reactive bone in solitary bone cysts and aneurysmal bone cysts. DMP-1 was not expressed in the tumour component of other bone neoplasms including Ewing sarcoma, chondrosarcoma, leiomyosarcoma, fibrosarcoma, giant cell tumour of bone and metastatic carcinoma. DMP-1 mRNA was expressed in osteosarcoma cell lines and tumour samples. DMP-1 is a matrix marker expressed around osteocytes in human woven and lamellar bone and is useful in identifying osteosarcoma and other bone-forming tumours.     

From bone lining cell to osteocyte—an SEM study

We describe the SEM appearance of the rat endosteal bone lining cell (BLC) population, and the sequence of morphological changes of these cells as they self-incorporate into unmineralized bone matrix (osteoid), establish intercellular connections, and construct lacunae. The osteoblast/nascent osteocyte series was progressively unsheathed by gentle digestion of the osteoid with 0.25% collagenase. The osteoblasts which leave the polygonally packed BLC compartment rapidly develop numerous complexly branched processes that contact the processes elaborated by previous generations of maturing and mature osteocytes. As osteoblasts mature and approach the mineralization front, they appear to lose processes. The mature cells begin to form osteocyte lacunae by depositing an asymmetric perimeter of woven collagen fibrils, such that as the cells roof-over, the lacunae appear as pocketlike constructions. The collagen fibrils on the perilacunar matrix are oriented in a tangential or circular pattern, while those in the more distal matrix are arranged in a parallel pattern. With the completion of a lacuna, its wall appears to mineralize quickly, for lacunae could be recognized only when they are forming.     

From bone lining cell to osteocyte--an SEM study

We describe the SEM appearance of the rat endosteal bone lining cell ( BLC ) population, and the sequence of morphological changes of these cells as they self-incorporate into unmineralized bone matrix (osteoid), establish intercellular connections, and construct lacunae. The osteoblast/nascent osteocyte series was progressively unsheathed by gentle digestion of the osteoid with 0.25% collagenase. The osteoblasts which leave the polygonally packed BLC compartment rapidly develop numerous complexly branched processes that contact the processes elaborated by previous generations of maturing and mature osteocytes. As osteoblasts mature and approach the mineralization front, they appear to lose processes. The mature cells begin to form osteocyte lacunae by depositing an asymmetric perimeter of woven collagen fibrils, such that as the cells roof-over, the lacunae appear as pocketlike constructions. The collagen fibrils on the perilacunar matrix are oriented in a tangential or circular pattern, while those in the more distal matrix are arranged in a parallel pattern. With the completion of a lacuna, its wall appears to mineralize quickly, for lacunae could be recognized only when they are forming.     

Histological identification of osteocytes in the allegedly acellular bone of the sea breams Acanthopagrus australis, Pagrus auratus and Rhabdosargus sarba (Sparidae, Perciformes, Teleostei)

The bone of advanced teleost fishes such as those of the family Sparidae is said to lack osteocytes or to be acellular. Acellularity has been determined by apparent lack of osteocyte lacunae. This study questions the validity of this criterion. Scanning electron and light microscopy of paraffin and resin sections were used to show that the sides of sea bream mandibles consist of laminar parallel-fibred bone that we call tubular bone, because it contains tubules, and localised regions of Sharpey fibre bone. Osteocytes lie along the walls of tubules that also contain collagen fibril bundles (T-fibres), or in the lumens of tubules that do not contain T-fibres. We show that the osteocytes are derived from osteoblasts. The T-fibre system is different from other fibre systems that have been described. The tubules enclose wide T-fibres (lenticular in cross-section, maximum width about 8 m) that taper at their ends and continue as thin T-fibres (round in crosssection, about 2 m wide). The T-fibres originate in the periosteum. In mature tubular bone, spaces of increasing size develop around the osteocytes. Osteocytes are released from the bone matrix and become postosteocytes or bone-lining cells. Secondary bone lines the largest spaces. In Sharpey fibre bone, small osteocytes in small lacunae (about 2 m wide) are found in columns parallel to the Sharpey fibres. Large osteocytes are found in large round spaces and are much larger than comparable osteocytes in lacunae in the bone of the salmon Salmo salar. We conclude that an absence of visible or conventional osteocyte lacunae does not mean that the cells themselves are absent. There are cells and two types of collagen fibre bundle in the tubules. The cells are osteocytes derived from osteoblasts, and these osteocytes apparently resorb bone with the result that large amounts of bone are destroyed. Acellular tubular and Sharpey fibre bone are types of cellular bone that differ from each other and from conventional cellular bone.     

A model of osteoblast-osteocyte kinetics in the development of secondary osteons in rabbits

The kinetics of osteogenic cells within secondary osteons have been examined within a 2-D model. The linear osteoblast density of the osteons and the osteocyte lacunae density were compared with other endosteal lamellar systems of different geometries. The cell density was significantly greater in the endosteal appositional zone and was always flatter than the central osteonal canals. Fully structured osteons compared with early structuring (cutting cones) did not show any significant differences in density. The osteoblast density may remain constant because some of them leave the row and become embedded within matrix. The overall shape of the Haversian system represented a geometrical restraint and it was thought to be related to osteoblast-osteocyte transformation. To test this hypothesis of an early differentiation and recruitment of the osteoblast pool which completes the lamellar structure of the osteon, the number and density of osteoblasts and osteocyte lacunae were evaluated. In the central canal area, the mean osteoblast linear density and the osteocyte lacunae planar density were not significantly different among sub-classes (with the exclusion of the osteocyte lacunae of the 300-1000 μm(2) sub-class). The mean number of osteoblasts compared with osteocyte lacunae resulted in significantly higher numbers in the two sub-classes, no significant difference was seen in the two middle sub-classes with the larger canals, and there were significantly lower levels in the smallest central canal sub-class. The TUNEL technique was used to identify the morphological features of apoptosis within osteoblasts. It was found that apoptosis occurred during the late phase of osteon formation but not in osteocytes. This suggests a regulatory role of apoptosis in balancing the osteoblast-osteocyte equilibrium within secondary osteon development. The position of the osteocytic lacunae did not correlate with the lamellar pattern and the lacunae density in osteonal radial sectors was not significantly different. These findings support the hypothesis of an early differentiation of the osteoblast pool and the independence of the fibrillar lamellation from osteoblast-osteocyte transformation.     

Evaluation of the expression of collagen type I in porous calcium phosphate ceramics implanted in an extra-osseous site

The aim of the present study is to demonstrate the newly formed tissue in calcium phosphate (Ca/P) ceramics after extra-osseous implantation by histological and immunohistochemistry (IHC) methods. Synthesis porous Ca/P ceramics without adding any growth factor and living cell were implanted in the dorsal muscle of dogs for 1 and 2 months. Undecalcified and decalcified sections were stained by hematoxylin and eosin (H&E), and IHC, respectively. The histological results showed the beginning of osteogenesis and angiogenesis after being implanted for 1 month and the obvious new bone formation after being implanted for 2 months. IHC were conducted via the avidin-biotin peroxidase complex (ABC) method and the primary antibody was collagen type I. IHC results indicated that collagen type I was expressed within osteoblast-like cells and newly formed bone-like tissue in Ca/P ceramics after 1 month, and in the mineralized matrix of newly formed bone and osteoblasts, some osteocytes and some lacunae after 2 months. No cartilage and chondrocytes were observed in the histological and IHC-stained sections. Evidence of intramembranous osteogenesis was confirmed.     

Expression of podoplanin and classical cadherins in salivary gland epithelial cells of klotho-deficient mice

We have recently shown that salivary gland myoepithelial cells express podoplanin. Podoplanin indirectly binds the actin filament network which links classical cadherins. The study here is aimed to investigate the expression of podoplanin and cadherins on salivary gland myoepithelial cells and the changes in the aging cells using klotho-deficient (kl/kl) mice. The submandibular glands of kl/kl mouse lack granular ducts which express klotho in wild type mice, suggesting that klotho may be a gene responsible for granular duct development. Although aging resulted in growth suppression of myoepithelial cells because of the sparse distribution of the cells in kl/kl mouse salivary glands, the expression of podoplanin and E-cadherin was shown in aging myoepithelial cells. It is thought that podoplanin participates in the actin-E-cadherin networks which are maintained in aging myoepithelial cells. It was also shown that granular ducts were filled with P-cadherin, and that the P-cadherin amount was larger in the wild type mouse submandibular glands than in the sublingual and parotid glands of wild type mouse, and in the submandibular glands of kl/kl mouse. These findings suggest that the granular duct is an organ secreting soluble P-cadherin into the saliva.     

Retrovirus-induced osteopetrosis in mice. Ultrastructural evidence of early virus production in osteoblasts and osteocytes.

Newborn female strain NMRI mice were given injections of a mouse retrovirus (OA MuLV) known to induce osteopetrosis, osteoma, and lymphoma. Femur metaphyses and lumbar vertebrae were investigated ultrastructurally 3 d, 7 d and 28 d after infection. Budding, immature and mature virus was observed associated with osteoblasts and osteocytes, but not with osteoclasts or chondrocytes, 28 d after infection with the virus. No production of virus particles was observed in bone-tissue in mock-treated controls. Thus, the primary target cell for OA virus in bone appears to belong to the osteoblastic/osteocytic cell lineage.