Bone remodelling in inflammatory arthritis.

The inflammatory arthropathies that include rheumatoid arthritis, the seronegative spondyloarthropathies and systemic lupus erythematosus are characterised by marked alterations in the architecture and structural integrity of peri-articular bone; however, the pattern and natural history of the skeletal changes differs in these conditions. In part, this can be attributed to differences in the primary anatomical site of the inflammation, but also there is evidence that there are differences in the biological properties and products produced by inflammatory tissues. This review will focus on recent advances in the understanding of the cellular and molecular mechanisms that contribute to the differential pattern of articular bone remodelling in these prototypical inflammatory forms of arthritis.

Bone matrix regulates osteoclast differentiation and annexin A8 gene expression.

While attachment to bone is required for optimal osteoclast function, the molecular events that underlie this fact are unclear, other than that the cell requires adhesion to mineralized matrix to assume a fully differentiated phenotype. To address this issue, we cultured murine bone marrow-derived osteoclasts on either cell culture plastic or devitalized mouse calvariae to identify the distinct genetic profile induced by interaction with bone. Among a number of genes previously unknown to be expressed in osteoclasts we found that Annexin A8 (AnxA8) mRNA was markedly up-regulated by bone. AnxA8 protein was present at high levels in osteoclasts present in human tissues recovered from sites of pathological bone loss. The presence of bone mineral was required for up-regulation of AnxA8 mRNA since osteoclasts plated on decalcified bone express AnxA8 at low levels as did osteoclasts plated on native or denatured type I collagen. Finally, AnxA8-regulated cytoskeletal reorganization in osteoclasts generated on a mineralized matrix. Thus, we used a novel approach to define a distinct bone-dependent genetic program associated with terminal osteoclast differentiation and identified Anxa8 as a gene strongly induced late in osteoclast differentiation and a protein that regulates formation of the cell's characteristic actin ring.

PU.1 and NFATc1 mediate osteoclastic induction of the mouse beta3 integrin promoter.

Expression of the alpha(v)beta(3) integrin is required for normal osteoclast function. We previously showed that an evolutionary conserved NFATc1 binding site is required for RANKL induction and NFATc1 transactivation of the human beta(3) promoter. The mechanism conferring specificity for RANKL induction and NFATc1 transduction of the beta(3) gene in osteoclast differentiation is unclear since NFATc1 is expressed and activated in numerous cell types that do not express the beta(3) gene. PU.1 is an ETS family transcription factor in myeloid cells associated with expression of various osteoclast genes. The present study investigates the role of NFATc1 in concert with PU.1 in osteoclast-specific transcription of the mouse beta(3) integrin gene. The mouse beta(3) promoter was transactivated by NFATc1 in RAW264.7 cells and deletion or mutation of either of the conserved NFAT and PU.1 binding sites abrogated transactivation. NFATc1 transactivation of the mouse beta(3) promoter was specifically dependent on co-transfected PU.1 in HEK293 cells, to the exclusion of other ETS family members. Direct binding of NFATc1 and PU.1 to their cognate sequences was demonstrated by EMSA and NFATc1 and PU.1 occupy their cognate sites in RANKL-treated mouse marrow precursors in chromatin immuno-precipitation (ChIP) assays. TAT-mediated transduction with dominant-negative NFATc1 dose-dependently blocked endogenous expression of the mouse beta(3) integrin and the formation of TRAP positive multinucleated cells in RANKL-treated mouse macrophages. These data provide evidence that NFATc1, in concert with PU.1, are involved in regulation of beta(3) integrin expression during osteoclast differentiation and suggest that PU.1 confers specificity to the NFATc1 response to macrophage lineage cells.

A novel promoter regulates calcitonin receptor gene expression in human osteoclasts.

The calcitonin receptor (CTR) is expressed in a wide variety of tissues and cell types. In bone, its expression is restricted to osteoclasts, the cells that mediate bone resorption. The human CTR (hCTR) gene has a complex structural organization that exhibits similarity to the porcine (pCTR) and mouse (mCTR) CTR genes. In these species, alternative splicing of a single gene generates multiple CTR isoforms that are distributed in both tissue-specific and species-specific patterns. However, the structural organization of the 5' putative regulatory region and transcriptional mechanisms responsible for tissue-specific expression of the different CTR isoforms are not fully defined. The present studies were undertaken to characterize the structural organization of the 5'-region of the hCTR and identify the regulatory regions involved in osteoclast-specific transcriptional activation. Analysis of mRNA prepared from human osteoclasts using reverse transcription-polymerase chain reaction (RT-PCR) and transient transfection of hCTR promoter-luciferase reporter constructs identified two regions in the 5'-flanking sequence of the hCTR gene that regulated CTR gene expression in osteoclasts. Both of these putative promoters were responsive to the osteoclast-inducing cytokine, receptor activator of NF-kappaB ligand (RANKL) and demonstrated trans-activation by the RANKL-induced transcription factor nuclear factor of activated T cells (NFATc1), consistent with a role in regulating CTR gene expression in osteoclasts.