Jaro Sodek

Bone formation in vitro by stromal cells obtained from bone marrow of young adult rats

SummaryCells from fetal or neonatal skeleton can synthesize bone-like tissue in vitro. In contrast, formation of bone-like tissue in vitro by cells derived from adult animals has rarely been reported and has not been achieved using cells from bone marrow. We have explored development of bone-like tissue in vitro by bone marrow stromal cells. Marrow stromal cells obtained from 40–43-day-old Wistar rats were grown in primary culture for 7 days and then subcultured for 20–30 days. Cells were cultured in either α-minimal essential medium containing 15% fetal bovine serum, antibiotics, and 50 μg/ml ascorbic acid, or the above medium supplemented with either 10 mM Na-β-glycerophosphate, 10-8 M dexamethasone, or a combination of both. Cultures were examined using phase-contrast microscopy, undemineralized and demineralized tissue histology, histochemistry (for alkaline phosphatase activity), immunohistochemistry (for collagen type, osteonectin, and bone Glaprotein), scanning and transmission electron microscopy, energy dispersive X-ray microanalysis, and X-ray diffraction. Collagenous, mineralized nodules exhibiting morphological and ultrastructural characteristics similar to bone were formed in the cultures, but only in the presence of both β-glycerophosphate and dexamethasone. Cells associated with the nodules exhibited alkaline phosphatase activity. The matrix of the nodules was composed predominantly of type-I collagen and both osteonectin and Glaprotein were present. X-ray microanalysis showed the presence of Ca and P, and X-ray diffraction indicated the mineral to be hydroxyapatite. The nodules were also examined for bone morphogenetic protein-like activity. Paired diffusion chambers containing partly demineralized nodules and fetal muscle were implanted intraperitonealy in rats. Induction of cartilage in relation to muscle was observed histologically after 40 days in the chambers. This finding provided further support for the bone-like nature of the nodules. The observations show that bone-like tissue can be synthesized in vitro by cells cultured from young-adult bone marrow, provided that the medium contains both β-glycerophosphate and, particularly, dexamethasone.

Intracellular osteopontin is an integral component of the CD44-ERM complex involved in cell migration.

Osteopontin (OPN) is a secreted glycoprotein with mineral‐ and cell‐binding properties that can regulate cell activities through integrin receptors. Previously, we identified an intracellular form of osteopontin with a perimembranous distribution in migrating fetal fibroblasts (Zohar et al., J Cell Physiol 170:88–98, 1997). Since OPN and CD44 expression are increased in migrating cells, we analyzed the relationship of these proteins with immunofluorescence and confocal microscopy. A distinct co‐localization of perimembranous OPN and cell‐surface CD44 was observed in fetal fibroblasts, periodontal ligament cells, activated macrophages, and metastatic breast cancer cells. The co‐localization of OPN and CD44 was prominent at the leading edge of migrating fibroblasts, where OPN also co‐localized with the ezrin/radixin/moesin (ERM) protein ezrin, as well as in cell processes and at attachment sites of hyaluronan‐coated beads. The subcortical location of OPN in these cells was verified by cell‐surface biotinylation experiments in which biotinylated CD44 and non‐biotinylated OPN were isolated from complexes formed with hyaluronan‐coated beads and identified with immunoblotting. That perimembranous OPN represents secreted protein internalized by endocytosis or phagocytosis appeared to be unlikely since exogenous OPN that was added to cell cultures could not be detected inside the cells. A physical association with OPN, CD44, and ERM, but not with vinculin or α‐actin, was indicated by immunoadsorption and immunoblotting of cell proteins in complexes extracted from hyaluronan‐coated beads. The functional significance of OPN in this complex was demonstrated using OPN−/− and CD−/− mouse fibroblasts which displayed impaired migration and a reduced attachment to hyaluronan‐coated beads. These studies indicate that OPN exists as an integral component of a hyaluronan‐CD44‐ERM attachment complex that is involved in the migration of embryonic fibroblasts, activated macrophages, and metastatic cells. J. Cell. Physiol. 184:118–130, 2000.

Localization of bone sialoprotein (BSP) expression to sites of mineralized tissue formation in fetal rat tissues by In Situ hybridization

Bone sialoprotein (BSP) is a major protein in the mineralized matrix of bone and dentine. To study the relationship between the expression of BSP and the formation of mineralized connective tissues, a cDNA probe to rat BSP was prepared for in situ hybridization analysis of developing fetal rat bones and teeth. When used for Northern hybridization analysis of rat bone marrow cells induced to differentiate into osteogenic cells by dexamethasone, the BSP cDNA revealed a specific induction of 1.6- and 2.0-kb mRNA species of BSP. In tissue sections a strong hybridization signal associated with osteoblasts was observed in areas of endochondral bone formation in the long bone metaphysis and condylar cartilage, and in the intramembranous bone of the calvaria and mandible. Hybridization reflecting a lower degree of expression was evident in cells of the transitional zone of mineralizing cartilage and in odontoblasts forming incisor dentine. Expression of BSP was also demonstrated in the hypertrophic cartilage cells in the long bone and condylar process. In contrast, expression of BSP could not be detected in the reserve or proliferative chondrocytes, fibroblasts and muscle cells. These studies demonstrate that the expression of BSP in bones and teeth is essentially restricted to cells directly involved in the formation of mineralizing connective tissue matrices, indicating that BSP has a specific role in biological mineralization and that it is a useful marker of bone formation.

A comparison of the rates of synthesis and turnover of collagen and non-collagen proteins in adult rat periodontal tissues and skin using a microassay

Abstract The metabolic activity of collagen in rat molar periodontal tissues was measured by following the incorporation of [ 3 H]-proline into hydroxyproline. The sensitivity of the assay method allowed the rates of collagen to be determined in tissue samples taken from individual animals. The rate of synthesis of collagen in periodontal ligament was twice as fast as attached gingiva, four times as fast as skin corium, used as a reference tissue, and six times as fast as alveolar bone. Incorporation of proline label into mature collagen was highest in periodontal ligament, which had a rate five times faster than attached gingiva, six times faster than the bone and 15 times faster than skin. A comparison between the rates of incorporation of label into newly synthesized collagen and into mature collagen in each tissue indicated that newly synthesized collagen in periodontal ligament and bone was quantitatively converted into insoluble collagen, but in attached gingiva and in skin a conversion efficiency of 50 and 33 per cent respectively was found. The half-lives of newly synthesized collagen were calculated as 24 min for alveolar bone, 40 min for periodontal ligament, 80 min for gingiva and 360 min for skin. The half-lives of the turnover of the mature collagen were 1 day in periodontal ligament, 5 days in gingiva, 6 days in alveolar bone and 15 days in skin corium. The mature collagen half-lives were generally shorter than published values and suggest that recycling of labelled amino acids may affect results using conventional methods. The incorporation of [ 3 H]-proline into non-collagenous proteins soluble in 0.45 M sodium chloride showed an overall low metabolic activity for these proteins compared to collagen. However, there is some evidence of highly active non-collagenous proline-containing components insoluble in 0.45 M sodium chloride salt and 0.5 M acetic acid.

Osteopontin Expression Is Required for Myofibroblast Differentiation

Osteopontin (OPN) is a multifunctional cytokine that is strongly expressed in healing wounds and fibrotic lesions, both of which are characterized by the formation of myofibroblasts. We examined the role of OPN in myofibroblast differentiation induced by the profibrotic cytokine transforming growth factor-β1. In cultured cardiac or dermal fibroblasts treated with transforming growth factor-β1, there was a 2- to 5-fold increase in the expression of the myofibroblast markers α-smooth muscle actin and extradomain A fibronectin but no significant increase of these proteins in OPN-null fibroblasts. Phalloidin staining for actin filaments and immunostaining for α-smooth muscle actin and focal adhesion proteins showed reduced stress fibers, focal adhesions, and lamellipodia in OPN-null fibroblasts compared with wild-type cells. OPN-null fibroblasts exhibited 40% to 60% less spreading, 50% less resistance to detachment by shear force, and a ≈3-fold reduction in collagen gel contraction. These defects were partially rescued by ectopic expression of OPN. Mass spectrometric analysis of proteins in focal adhesions formed on collagen type I beads revealed an enrichment of HMGB1 protein in wild-type cells, whereas HMGB1 was not detected in OPN-null cells. Treatment of wild-type cells with small interfering RNA to knock down OPN reduced transforming growth factor-β1–induced α-smooth muscle actin and HMGB1 to levels observed in OPN-null cells. These studies demonstrate that OPN is required for the differentiation and activity of myofibroblasts formed in response to the profibrotic cytokine transforming growth factor-β1.

Developmental Expression of Osteopontin (OPN) mRNA in Rat Tissues: Evidence for a Role for OPN in Bone Formation and Resorption

Osteopontin (OPN) is a 34-kDa, highly-phosphorylated glycoprotein with cell attachment properties that is a prominent constituent of the bone matrix. To aid in elucidating the function of this protein we have studied the cellular expression of OPN mRNA during the formation, growth and maturation of rat calvarial (membranous) and tibial (endochondral) bone. From Northern hybridization analysis OPN expression was demonstrated in the kidney and gravid uterus as well as in bone tissues. Compared to collagen, the expression of OPN was low in early bone formation but increased subsequently and reached peak levels in 14-day-old bone. However, both the collagen and OPN mRNAs decreased markedly thereafter and remained low in young adult bone. From in situ hybridization studies using a [35S]-labelled rat OPN cRNA probe, OPN mRNA was localized to osteoblastic cells in newly-forming calvariae, jaw bones, and in the metaphyseal and periosteal bone of the tibia. In contrast to bone sialoprotein (BSP), which is expressed almost exclusively by osteoblasts at sites of de novo bone formation, OPN transcripts were present in cells lining both endosteal and periosteal bone surfaces, and in osteocytes. Moreover, expression of OPN persisted during the subsequent growth and remodelling of both membranous and endochondral bone and was expressed at particularly high levels by bone cells and hypertrophic chondrocytes at sites of osteoclastic resorption. In the more mature bone of young adult rats OPN expression was significantly reduced but remained detectable in bone cells lining periosteal and endosteal surfaces and in the primary and secondary spongiosa of the tibia. These studies on the developmental expression of OPN support the concept of a multifunctional role for OPN in bone formation and remodelling. Thus, the expression of OPN by osteoblasts early in bone development is consistent with a role for this protein in the formation of bone matrix, whereas the peak expression of OPN later in bone development, together with high expression at sites of rapid remodelling, indicate that OPN deposited on the surface of mineralized connective tissues may provide a template for osteoclastic resorption.

Osteopontin modulates CD44-dependent chemotaxis of peritoneal macrophages through G-protein-coupled receptors: evidence of a role for an intracellular form of osteopontin.

Expression of osteopontin (OPN) by activated T‐cells and macrophages is required for the development of cell‐mediated inflammatory responses. Acting through integrin αvβ3 and CD44 receptors, OPN can promote chemoattraction and pro‐inflammatory cytokine expression by macrophages. In this study, we have used periotoneal macrophages from OPN−/, CD44−/−, and WT mice to study the relationship between OPN and CD44 in macrophage migration. Using confocal microscopy, we show that OPN co‐distributes with CD44 inside macrophages at cell edges and in cell processes in a mutually dependent manner. The existence of an intracellular form of OPN is supported by pulse‐chase studies in which a thrombin‐sensitive, phosphorylated protein immunoprecipitated with OPN antibodies is retained inside macrophages. In OPN−/− and CD44−/− macrophages, the absence of CD44 and OPN, respectively, is associated with the formation of fewer cell processes, reduced cell fusion required to form functional multinucleated osteoclasts in the presence of CSF‐1 and RANKL, and impaired chemotaxis. Whereas the chemotaxis of CD44−/− cells to various chemoattractants is almost completely abrogated, a differential effect is seen with the OPN−/− cells. Thus, OPN−/− cells migrate normally towards CSF‐1 but not towards fMLP and MCP‐1, which signal through G‐protein coupled receptors (GPCRs). That the GPCR‐mediated migration is dependent upon the level of cell‐surface CD44 is indicated by the reduced cell‐surface expression of CD44 in OPN−/− cells and a comparable impairment in the chemotaxis of CD44+/− cells. Although chemotaxis of OPN−/− cells could be rescued by an OPN substratum, or by addition of high levels of OPN in solution, no response is evident with physiological levels of OPN, indicating a requirement for the CD44‐associated intracellular OPN in CD44 cell‐surface expression. These studies indicate, therefore, that the level of cell surface CD44 is critical for GPCR‐mediated chemotaxis by peritoneal macrophages and suggest that a novel intracellular form of OPN may modulate CD44 activities involved in these processes. J. Cell. Physiol. 198: 155–167, 2004.

Colocalization of intracellular osteopontin with CD44 is associated with migration, cell fusion, and resorption in osteoclasts.

Although osteopontin (OPN) is recognized generally as a secreted protein, an intracellular form of osteopontin (iOPN), associated with the CD44 complex, has been identified in migrating fibroblastic cells. Because both OPN and CD44 are expressed at high levels in osteoclasts, we have used double immunofluorescence analysis and confocal microscopy to determine whether colocalization of these proteins has functional significance in the formation and activity of osteoclasts. Analysis of rat bone marrow‐derived osteoclasts revealed strong surface staining for CD44 and β1‐ and β3‐integrins, whereas little or no staining for OPN or bone sialoprotein (BSP) was observed in nonpermeabilized cells. In permeabilized perfusion osteoclasts and multinucleated osteoclasts, staining for OPN and CD44 was prominent in cell processes, including filopodia and pseudopodia. Confocal microscopy revealed a high degree of colocalization of OPN with CD44 in motile osteoclasts. In cells treated with cycloheximide (CHX), perinuclear staining for OPN and BSP was lost, but iOPN staining was retained within cell processes. In osteoclasts generated from the OPN‐null and CD44‐null mice, cell spreading and protrusion of pseudopodia were reduced and cell fusion was impaired. Moreover, osteoclast motility and resorptive activity were significantly compromised. Although the area resorbed by OPN‐null osteoclasts could be rescued partially by exogenous OPN, the resorption depth was not affected. These studies have identified an intracellular form of OPN, colocalizing with CD44 in cell processes, that appears to function in the formation and activity of osteoclasts.

Immunohistochemical localization of bone sialoprotein in foetal porcine bone tissues: comparisons with secreted phosphoprotein 1 (SPP-1, osteopontin) and SPARC (osteonectin).

SummaryBone sialoprotein (BSP) is a prominent component of bone tissues that is expressed by differentiated osteoblastic cells. Affinity-purified antibodies to BSP were prepared and used in combination with biotin-conjugated peroxidase-labeled second antibodies to demonstrate the distribution of this protein in sections of demineralized foetal porcine tibia and calvarial bone. Staining for BSP was observed in the matrix of mineralized bone and also in the mineralized cartilage and associated cells of the epiphysis, but was not observed in the hypertrophic zone nor in any of the soft tissues including the periosteum. In comparison, SPP-1 (osteopontin) and SPARC (osteonectin), which are also major proteins in porcine bone, were observed in the cartilage as well as in the mineralized bone matrix, In addition, SPARC was also present in soft connective tissues. Although SPP-1 distribution was more restricted than SPARC, hypertrophic chondrocytes, periosteal cells and some stromal cells in the bone marrow spaces were stained in addition to osteoblastic cells. The variations in the distribution and cellular expression of BSP, SPARC and SPP-1 in bone and mineralizing cartilage indicate these proteins perform different functions in the formation and remodelling of mineralized connective tissues.

Role of integrins in regulation of collagen phagocytosis by human fibroblasts

Phagocytosis of collagen fibrils by fibroblasts is an important pathway for degradation of extracellular matrix in mature connective tissues. To study regulatory mechanisms in phagocytosis, 2‐μm fluorescent beads coated with either collagen (COL) or bovine serum albumin (BSA) were incubated with human gingival fibroblasts in vitro. For these studies single cell suspensions were prepared by trypsinization, and bead internalization and collagen receptor expression were assessed by flow cytometry. After 3‐h incubations, up to 8‐fold more cells internalized COL beads than BSA‐coated beads. Increased collagen coating concentration was associated with elevated proportions of cells that internalized COL beads, and was observed also in the presence of competing fibronectin‐coated beads. The number of beads per cell and the percent of phagocytic cells increased proportionally with higher bead loadings. At > 4 beads per cell a maximum of ∼︁80% of cells were phagocytic. Cells reacted with mAbs against the α1, α2, and α3 integrin subunits were, respectively, 5%, 98% and 93% positively stained above background controls. All cells that internalized COL beads exhibited α2 staining but there were large proportions of phagocytic cells that were not stained for α1. In unfixed cells, bead internalization caused an immediate reduction of surface staining of membrane‐bound α2 by ∼︁55% which returned to control levels within 3 h, indicating that cell‐surface α2 was internalized by phagocytosis. Preincubation of cells with up to 8 COL beads per cell reduced the proportion of phagocytic cells and the number of internalized beads after a second COL bead incubation 4 h later. To assess the relationship between the percent of phagocytic cells and α2 integrin levels, serum starvation and cycloheximide experiments were conducted. Compared to controls, serum starvation for 24 h induced a 3.2‐fold increase of cells internalizing COL beads but did not alter α2 staining levels. In contrast, 3 h cycloheximide treatment reduced α2 staining to 60% of control levels and this treatment also inhibited COL bead internalization. GRGDTP peptide as well as mAbs against the α1 and α2 subunits significantly reduced internalization of COL beads by 1.8 to 2.6‐fold, whereas GRGESP peptide and α3 mAb exerted no effect. Internalization of BSA beads was not affected by any of these treatments. Collectively, these data indicate that the α2 integrin, along with other, as yet unidentified components, is likely involved in COL bead internalization. The α2 integrin subunit is rapidly recycled or synthesized following a phagocytic load. In contrast, the α1 integrin is not directly required for phagocytosis but may regulate the internalization step.