Vicky Kartsogiannis

Localization of RANKL (receptor activator of NF kappa B ligand) mRNA and protein in skeletal and extraskeletal tissues.

RANKL (receptor activator of NFkappaB ligand) is a membrane-associated osteoblastic molecule, and along with macrophage-colony-stimulating factor, is crucial for osteoclast formation. RANKL is known to be strongly expressed in osteoblasts and lymphoid tissues. We have sought to determine the skeletal and extraskeletal sites of production of RANKL mRNA and protein using the techniques of in situ hybridization and immunohistochemistry. Expression of RANKL mRNA and protein were determined in the developmental progression of endochondral bone formation in mouse, intramembranous bone formation in a rabbit model (mRNA only), in human giant cell tumors of bone, and at extraskeletal sites in the mouse. RANKL mRNA was expressed in prehypertrophic and hypertrophic chondrocytes at day E15 embryonic mouse long bone, and its expression was maintained at these sites throughout development. In newborn and adult mice, high levels of RANKL mRNA were expressed in mesenchymal cells of the periosteum and in mature osteoblasts, while megakaryocytes within the marrow microenvironment expressed RANKL mRNA from 1 week of age. Immunohistochemical analysis revealed a similar localization pattern of RANKL protein at the sites described. In the intramembranous bone formation model, RANKL mRNA was expressed in mesenchymal cells and in actively synthesizing osteoblasts, but not in flattened lining osteoblasts or late osteocytes. Expression of RANKL mRNA and protein in osteoclasts was variable with those within resorption lacunae showing the strongest signal/staining. Likewise, expression varied in osteoclasts from giant cell tumor of bone with a minority of tartrate-resistant acid phosphatase-positive multinucleated cells having no detectable RANKL mRNA or protein. In extraskeletal tissues, RANKL mRNA and protein were detected in the brain, heart, kidney, skeletal muscle, and skin throughout mouse development, suggesting the possibility of several other functions of the molecule. RANKL was also developmentally regulated, as evidenced by its expression in the intestine, liver, and lung at E15 and newborn mouse but not in the adult.

Expression of osteoclast differentiation factor at sites of bone erosion in collagen‐induced arthritis

OBJECTIVE To investigate the cellular mechanism of bone destruction in collagen-induced arthritis (CIA). METHODS After induction of CIA in DA rats, a histologic study of the advanced arthritic lesion was carried out on whole, decalcified joints from the hindpaws of affected animals. To conclusively identify osteoclasts, joint tissue sections were stained for tartrate-resistant acid phosphatase (TRAP) enzyme activity, and calcitonin receptors (CTR) were identified using a specific rabbit polyclonal antibody. The expression of messenger RNA (mRNA) for the osteoclast differentiation factor (also known as receptor activator of nuclear factor kappaB ligand [RANKL]) was investigated using in situ hybridization with a specific riboprobe. RESULTS TRAP-positive and CTR-positive multinucleated cells were invariably detected in arthritic lesions that were characterized by bone destruction. Osteoclasts were identified at the pannus-bone and pannus-subchondral bone junctions of arthritic joints, where they formed erosive pits in the bone. TRAP-positive multinucleated cells were detected within synovium and at the bone erosive front; however, CTR-positive multinucleated cells were present only at sites adjacent to bone. RANKL mRNA was highly expressed in the synovial cell infiltrate in arthritic joints, as well as by osteoclasts at sites of bone erosion. CONCLUSION Focal bone erosion in CIA is attributed to cells expressing definitive features of osteoclasts, including CTR. The expression of RANKL by cells within inflamed synovium suggests a mechanism for osteoclast differentiation and activation at sites of bone erosion. Inhibitors of RANKL may represent a novel approach to treatment of bone loss in rheumatoid arthritis.

Cell lines and primary cell cultures in the study of bone cell biology.

Bone is a metabolically active and highly organized tissue consisting of a mineral phase of hydroxyapatite and amorphous calcium phosphate crystals deposited in an organic matrix. Bone has two main functions. It forms a rigid skeleton and has a central role in calcium and phosphate homeostasis. The major cell types of bone are osteoblasts, osteoclasts and chondrocytes. In the laboratory, primary cultures or cell lines established from each of these different cell types provide valuable information about the processes of skeletal development, bone formation and bone resorption, leading ultimately, to the formulation of new forms of treatment for common bone diseases such as osteoporosis.

Temporal expression of PTHrP during endochondral bone formation in mouse and intramembranous bone formation in an in vivo rabbit model

Expression of parathyroid hormone-related protein (PTHrP) messenger RNA (mRNA) and protein was investigated throughout the developmental progression of endochondral bone formation in mouse and intramembranous bone formation in an in vivo model in rabbit, using in situ hybridization and immunohistochemistry. Endochondral bone formation was investigated in a developing embryo, newborn, and adult mouse. In fetal long bones through to newborn (day 7), PTHrP mRNA and protein were consistently expressed in chondrocytes within the proliferative, transitional, and hypertrophic zones. In addition, high levels of PTHrP were also detected in osteoblasts on the surface of trabecular bone surfaces. Similarly, at the adult stage (week 7), PTHrP mRNA and protein were consistently expressed in chondrocytes at epiphyseal ends of the subarticular cartilage, within cortical periosteum, as well as in osteoblasts located at the metaphyseal trabecular bone surfaces. Using an in vivo intramembranous bone formation model in rabbits, expression of PTHrP mRNA and protein was demonstrated in preosteoblasts prior to trabecular bone formation (1-week bone harvest). As bone formed (2-, 3-, and 4-week bone tissue harvests), PTHrP mRNA and protein were highly expressed in actively synthesizing osteoblasts and in those osteocytes embedded within the superficial layers of the bone matrix. Lining osteoblasts and osteocytes buried deeply in the bone matrix displayed weak or no signal for PTHrP. The pattern of spatial and temporal expression of PTHrP demonstrated in cartilage cells and osteoblasts in the two systems suggests an important role of PTHrP in both endochondral and intramembranous bone formation.

Calcitonin Receptor Antibodies in the Identification of Osteoclasts

Osteoclasts are the cells responsible for bone resorption, and their number and rate of formation are critical in determining bone mass. To identify and quantify osteoclasts, as well as to study their formation in bone and in osteoclastogenic cultures, osteoclast-specific cell markers are required. Only the calcitonin receptor (CTR) expression unambiguously identifies osteoclasts and distinguishes them from macrophage polykaryons. However, present autoradiographic methods for CTR detection are cumbersome and time consuming. We have developed rabbit polyclonal antibodies specific for the C-terminal intracellular domain of the mouse and rat Cla CTR. These antibodies labeled HEK-293 cells stably transfected with CTR (but not untransfected HEK-293 cells). This labeling is abrogated by preabsorbing the antibodies with the recombinant antigen. The antibodies immunostained primary mouse and rat osteoclasts as well as osteoclasts in sections of mouse bone. Osteoclasts (both mononuclear and multinucleated) formed from mouse bone marrow or spleen cells cocultured with osteoblasts in the presence of 1,25 dihydroxyvitamin D3 and prostaglandin E2 were also specifically immunostained by the CTR antibodies. Cocultures incubated under conditions that did not allow osteoclastogenesis (i.e., omission of mediators or osteoblasts, or culture for less than 4 days) were not immunostained by CTR antibodies. Autoradiographic detection of 125I-labeled salmon calcitonin combined with CTR immunohistochemistry showed that both methods labeled the same cells. A CTR polyclonal antibody and monoclonal antibody F4/80 were used in combination to show immunofluorescence labeling of murine osteoclasts and macrophage populations, respectively, in marrow/osteoblast cocultures. These results indicate that simple and rapid CTR antibody-based methods can be used to identify osteoclasts, and can be used to characterize the antigenic profile of osteoclasts by using double immunofluorescence analysis.

Osteoclast Inhibitory Lectin, a Family of New Osteoclast Inhibitors

We have identified two novel type II membrane-bound C-lectins, designated mOCILrP1 and mOCILrP2, of 218 and 217 amino acids, respectively, that share substantial identity with the murine osteoclast inhibitory lectin (OCIL). The extracellular domains of mOCILrP1 and mOCILrP2 share 83 and 75% identity, respectively, with the extracellular domain of mOCIL. When the extracellular domains were expressed as recombinant proteins, each inhibited osteoclast formation in murine bone marrow cultures treated with M-CSF and RANKL with similar potencies to mOCIL (IC50 of 0.2 ng/ml). Distinct but highly related genes encoded the three OCIL family members, with mOCIL and mOCILrP2 controlled by an inverted TATA promoter, and mOCILrP1 by a TTAAAA promoter. However only mOCIL was robustly regulated by calciotropic agents, while mOCILrP1 was not expressed, and mOCILrP2 was constitutively expressed in osteoblasts. Immunohistochemistry using antipeptide antibodies to the intracellular domain of mOCILrP1/mOCILrP2 and to mOCIL demonstrated that mOCIL and mOCILrP1/mOCILrP2 were concordantly expressed in osteoblasts, chondrocytes, and in extraskeletal tissues. Further, their cellular distribution was identical to that of RANKL. The identification of three distinct genes that were functionally related implies redundancy for OCIL, and their concordant expression with that of RANKL suggests that the RANKL:OPG axis may be further influenced by OCIL family members.

Isolation of a human homolog of osteoclast inhibitory lectin that inhibits the formation and function of osteoclasts.

Osteoclast inhibitory lectin (OCIL) is a newly recognized inhibitor of osteoclast formation. We identified a human homolog of OCIL and its gene, determined its regulation in human osteoblast cell lines, and established that it can inhibit murine and human osteoclast formation and resorption. OCIL shows promise as a new antiresorptive.

Localization of parathyroid hormone-related protein in osteoclasts by in situ hybridization and immunohistochemistry

Using immunohistology with two specific antisera raised against N-terminal parathyroid hormone-related protein (PTHrP) and in situ hybridization (riboprobe to common coding exon), evidence is provided for the expression of PTHrP by mouse, rabbit, and human osteoclasts derived from several in vitro and in vivo sources. In cocultures of mouse bone marrow and calvarial cells treated with 1,25-dihydroxyvitamin D3, the generated osteoclasts expressed both PTHrP messenger RNA (mRNA) and protein. In addition, PTHrP was detected in the majority of actively resorbing osteoclasts in sections of newborn and adult mouse long bones. Using an in vivo intramembranous bone formation model in rabbits, expression of PTHrP mRNA and protein was demonstrated in osteoclasts at active bone resorption sites as well as in actively synthesizing osteoblasts and bone lining cells. Localization of PTHrP was also demonstrated in osteoclast-like cells of human giant cell tumors from bone. In some of these tumors, a small proportion of the multinucleated cells expressed tartrate resistant acid phosphatase (TRAP), but not PTHrP mRNA or protein. Finally, both mRNA and protein for PTHrP were expressed in osteoclasts in sections of bone or joints from patients with Pagets disease, rheumatoid arthritis, and osteoarthritis. These observations raise the possibility that PTHrP might participate in osteoclast function.

Thalassemia bone disease: a 19-year longitudinal analysis.

Thalassemia is an inherited disorder of alpha or beta globin chain synthesis leading to ineffective erythropoiesis requiring chronic transfusion therapy in its most severe form. This leads to iron overload, marrow expansion, and hormonal complications, which are implicated in bone deformity and loss of bone mineral density (BMD). In this 19‐year retrospective longitudinal study, the relationships between BMD (determined by dual‐energy X‐ray absorptiometry) and risk factors for osteoporosis in 277 subjects with transfusion‐dependent thalassemia were examined. The mean age at first review was 23.2 ± 11.9 years and 43.7% were male. Hypogonadism was present in 28.9%. Fractures were confirmed in 11.6% of subjects and were more frequent in males (16.5%) compared with females (7.7%). Lumbar spine (LS), femoral neck (FN), and total body (TB) Z‐scores were derived. Patients with transfusion‐dependent thalassemia had a significant longitudinal decline in BMD at the FN and TB. In the linear mixed‐model analysis of BMD and risk factors for bone loss, FN Z‐score was more significantly associated with risk factors compared with the LS and TB. The rate of decline at the FN was 0.02 Z‐score per year and was 3.85‐fold greater in males. The decline in FN Z‐score over the last 5 years (years 15 to 19) was 2.5‐fold that of the previous 7 years (years 8 to 14) and coincided with a change in iron chelator therapy from desferrioxamine to deferasirox. Hemoglobin (Hb) levels positively correlated with higher TB and LS Z‐scores. In conclusion, the FN is the preferred site for follow‐up of BMD. Male patients with β‐thalassemia experienced a greater loss of BMD and had a higher prevalence of fractures compared with females. Transfusing patients (particularly males) to a higher Hb target may reduce the decline in BMD. Whether deferasirox is implicated in bone loss warrants further study.

Osteoclast Inhibitory Lectin, an Immune Cell Product That Is Required for Normal Bone Physiology in Vivo

Osteoclast inhibitory lectin (OCIL or clrb) is a member of the natural killer cell C-type lectins that have a described role mostly in autoimmune cell function. OCIL was originally identified as an osteoblast-derived inhibitor of osteoclast formation in vitro. To determine the physiological function(s) of OCIL, we generated ocil-/- mice. These mice appeared healthy and were fertile, with no apparent immune function defect, and phenotypic abnormalities were limited to bone. Histomorphometric analysis revealed a significantly lower tibial trabecular bone volume and trabecular number in the 10- and 16-week-old male ocil-/- mice compared with wild type mice. Furthermore, ocil-/- mice showed reduced bone formation rate in the 10-week-old females and 16-week-old males while Static markers of bone formation showed no significant changes in male or female ocil-/- mice. Examination of bone resorption markers in the long bones of ocil-/- mice indicated a transient increase in osteoclast number per unit bone perimeter. Enhanced osteoclast formation was also observed when either bone marrow or splenic cultures were generated in vitro from ocil-/- mice relative to wild type control cultures. Loss of ocil therefore resulted in osteopenia in adult mice primarily as a result of increased osteoclast formation and/or decreased bone formation. The enhanced osteoclastic activity led to elevated serum calcium levels, which resulted in the suppression of circulating parathyroid hormone in 10-week-old ocil-/- mice compared with wild type control mice. Collectively, our data suggest that OCIL is a physiological negative regulator of bone.