Kim C. Mansky

Microphthalmia Transcription Factor Is a Target of the p38 MAPK Pathway in Response to Receptor Activator of NF-κB Ligand Signaling

Receptor activator of NF-κB ligand (RANKL) activates signaling pathways that regulate osteoclast differentiation, function, and survival. The microphthalmia transcription factor (MITF) is required for terminal differentiation of osteoclasts. To determine whether MITF could be a target of RANKL signaling, a phosphospecific MITF antibody directed against conserved residue Ser307, a potential mitogen-activated protein kinase (MAPK) site, was produced. Using this antibody, we could demonstrate that MITF was rapidly and persistently phosphorylated upon stimulation of primary osteoclasts with RANKL and that phosphorylation of Ser307 correlated with expression of the target gene tartrate-resistant acid phosphatase. MITF phosphorylation at Ser307 also correlated with persistent activation of p38 MAPK, and p38 MAPK could utilize MITF Ser307 as a substratein vitro. The phosphorylation of MITF and activation of target gene expression in osteoclasts were blocked by p38 MAPK inhibitor SB203580. In transient transfections, a constitutively active Rac1 or MKK6 gene could collaborate with MITF to activate the tartrate-resistant acid phosphatase gene promoter dependent on Ser307. Dominant negative p38 α and β could inhibit the collaboration between upstream signaling components and MITF in the transient assays. These results indicate that MITF is a target for the RANKL signaling pathway in osteoclasts and that phosphorylation of MITF leads to an increase in osteoclast-specific gene expression.

MITF and PU.1 Recruit p38 MAPK and NFATc1 to Target Genes during Osteoclast Differentiation

Transcription factors NFATc1, PU.1, and MITF collaborate to regulate specific genes in response to colony-stimulating factor-1 (CSF-1) and receptor activator of NF-κB ligand (RANKL) signaling during osteoclast differentiation. However, molecular details concerning timing and mechanism of specific events remain ill-defined. In bone marrow-derived precursors, CSF-1 alone promoted assembly of MITF-PU.1 complexes at osteoclast target gene promoters like cathepsin K and acid 5 phosphatase without increasing gene expression. The combination of RANKL and CSF-1 concurrently increased the levels of MAPK-phosphorylated forms of MITF, p38 MAPK, and SWI/SNF chromatin-remodeling complexes bound to these target promoters and markedly increased expression of the genes. NFATc1 was subsequently recruited to complexes at the promoters during terminal stages of osteoclast differentiation. Genetic analysis of Mitf and Pu.1 in mouse models supported the critical interaction of these genes in osteoclast differentiation. The results define MITF and PU.1 as nuclear effectors that integrate CSF-1/RANKL signals during osteoclast differentiation to initiate expression of target genes, whereas a complex that includes NFATc1 may act to maintain target gene expression in differentiated cells.

Enhanced Osteoclastogenesis Causes Osteopenia in Twisted Gastrulation-Deficient Mice Through Increased BMP Signaling†‡

The uncoupling of osteoblastic and osteoclastic activity is central to disorders such as osteoporosis, osteolytic malignancies, and periodontitis. Numerous studies have shown explicit functions for bone morphogenetic proteins (BMPs) in skeletogenesis. Their signaling activity has been shown in various contexts to be regulated by extracellular proteins, including Twisted gastrulation (TWSG1). However, experimental paradigms determining the effects of BMP regulators on bone remodeling are limited. In this study, we assessed the role of TWSG1 in postnatal bone homeostasis. Twsg1‐deficient (Twsg1−/−) mice developed osteopenia that could not be explained by defective osteoblast function, because mineral apposition rate and differentiation markers were not significantly different compared with wildtype (WT) mice. Instead, we discovered a striking enhancement of osteoclastogenesis in Twsg1−/− mice, leading to increased bone resorption with resultant osteopenia. Enhanced osteoclastogenesis in Twsg1−/− mice was caused by increased cell fusion, differentiation, and function of osteoclasts. Furthermore, RANKL‐mediated osteoclastogenesis and phosphorylated Smad1/5/8 levels were enhanced when WT osteoclasts were treated with recombinant BMP2, suggesting direct regulation of osteoclast differentiation by BMPs. Increase in detectable levels of phosphorylated Smad 1/5/8 was noted in osteoclasts from Twsg1−/− mice compared with WT mice. Furthermore, the enhanced osteoclastogenesis in Twsg1−/− mice was reversed in vitro in a dose‐dependent manner with exposure to Noggin, a BMP antagonist, strongly suggesting that the enhanced osteoclastogenesis in Twsg1 mutants is attributable to increased BMP signaling. Thus, we present a novel and previously uncharacterized role for TWSG1 in inhibiting osteoclastogenesis through regulation of BMP activity.

Bone morphogenic protein 2 directly enhances differentiation of murine osteoclast precursors.

Previous studies found that bone morphogenic proteins (BMPs) support osteoclast formation, but it is not clear whether this is a direct effect on osteoclasts or mediated indirectly through osteoblasts. We have shown that a mouse deficient for the BMP antagonist Twisted gastrulation suggested a direct positive role for BMPs on osteoclastogenesis. In this report, we further determine the significance of BMP signaling on osteoclast formation in vitro. We find that BMP2 synergizes with suboptimal levels of receptor activator of NF‐κB ligand (RANKL) to enhance in vitro differentiation of osteoclast‐like cells. The enhancement by BMP2 is not a result of changes in the rate of proliferation or survival of the bone marrow‐derived cultures, but is accompanied by an increase in expression of genes involved in osteoclast differentiation and fusion. Treatment with BMP2 did not significantly alter expression of RANKL or OPG in our osteoclast cultures, suggesting that the enhancement of osteoclastogenesis is not mediated indirectly through osteoblasts or stromal cells. Consistent with this, we detected phosphorylated SMAD1,5,8 (p‐SMAD) in the nuclei of mononuclear and multinucleated cells in osteoclast cultures. Levels of p‐SMAD, BMP2, and BMP receptors increased during differentiation. RNAi suppression of Type II BMP receptor inhibited RANKL‐stimulated formation of multinuclear TRAP‐positive cells. The BMP antagonist noggin inhibited RANKL‐mediated osteoclast differentiation when added prior to day 3, while addition of noggin on day 3 or later failed to inhibit their differentiation. Taken together, these data indicate that osteoclasts express BMP2 and BMP receptors, and that autocrine BMP signaling directly promotes the differentiation of osteoclasts‐like cells. J. Cell. Biochem. 109: 672–682, 2010.

Tenofovir treatment of primary osteoblasts alters gene expression profiles: Implications for bone mineral density loss

There is strong clinical evidence that implicates tenofovir in the loss of bone mineral density during treatment of human immunodeficiency virus infection. In this study, we sought to test the hypothesis that tenofovir treatment of osteoblasts causes changes in the gene expression profile that would impact osteoblast function during bone formation. Primary osteoblasts were isolated and then treated with the tenofovir prodrug, tenofovir disoproxil fumarate (TDF). Total RNA from TDF-treated and untreated osteoblasts were extracted and used for microarray analysis to assess TDF-associated changes in the gene expression profile. Strikingly, the changes in gene expression profiles involved in cell signaling, cell cycle and amino acid metabolism, which would likely impact osteoblast function in bone formation. Our findings demonstrate for the first time that tenofovir treatment of primary osteoblasts results in gene expression changes that implicate loss of osteoblast function in tenofovir-associated bone mineral density loss.

The microphthalmia transcription factor and the related helix-loop-helix zipper factors TFE-3 and TFE-C collaborate to activate the tartrate-resistant acid phosphatase promoter

The microphthalmia transcription factor (MITF) regulates different target genes in several distinct cell types, including osteoclasts. The role of the closely related factors TFE3 and TFEC in MITF action was studied. The TFE3 and TFEC proteins were expressed in osteoclast‐like cells, and both could be immunoprecipitated in a complex with MITF. In transient transfection assays, TFE3 and TFEC could collaborate with MITF to superactivate the tartrate resistant acid phosphatase (TRAP) promoter, a target for MITF in osteoclasts. Although TFEC had been thought to act as a repressor, we could demonstrate that TFEC acted as a transactivator when fused to the gal4 DNA‐binding domain in a yeast one‐hybrid‐type assay. Additionally, two mRNA isoforms of MITF, MITF‐M and MITF‐A, were detected in primary osteoclast‐like cells by RT‐PCR. In transient transfection assays, the MITF‐A and MITF‐M isoforms activated the promoter of the TRAP gene to the same extent, and both forms could collaborate equally well with TFE3 to activate the TRAP promoter. These results indicate that although different isoforms of MITF appear to be functionally similar, the TFE3 and TFEC proteins may collaborate with MITF to efficiently regulate expression of target genes in osteoclasts.

Tenofovir-associated bone density loss

Clinical observations have revealed a strong correlation between loss of bone density in HIV-infected individuals, particularly in conjunction with the antiretroviral drug tenofovir, a nucleotide analog that inhibits HIV reverse transcriptase. The most compelling correlations have been observed in clinical studies involving young children and adolescents. These observations strongly suggest that bone density is being affected during active bone growth and development, implicating a role for tenofovir in bone loss. Here we discuss the literature and potential mechanisms for how tenofovir-associated bone loss may arise, which likely involves perturbation of cellular DNA synthesis and gene expression. Elucidation of the mechanism(s) involved in tenofovir-mediated bone loss will help in developing adjuvant therapies to reduce tenofovir-associated bone density loss.

HDAC3 and HDAC7 Have Opposite Effects on Osteoclast Differentiation

Histone deacetylases (HDACs) are negative regulators of transcription. Endochondral bone formation including chondrocyte and osteoblast maturation is regulated by HDACs. Very little is known about the role HDACs play in osteoclast differentiation. It has been previously reported that HDAC inhibitors, trichostatin A and sodium butyrate, suppress osteoclast differentiation through multiple mechanisms. In this study, we report that suppression of HDAC3 expression similar to HDAC inhibitors inhibits osteoclast differentiation, whereas osteoclasts suppressed for HDAC7 expression had accelerated differentiation when compared with control cells. Mitf, a transcription factor, is necessary for osteoclast differentiation. We demonstrate that Mitf and HDAC7 interact in RAW 264 cells and osteoclasts. The transcriptional activity of Mitf is repressed by HDAC7. Lastly, we show that either the amino or the carboxyl terminus of HDAC7 is sufficient for transcriptional repression and that the repression of HDAC7 is insensitive to trichostatin A, indicating that HDAC7 represses Mitf at least in part by deacetylation-independent mechanism.

Downregulation of Gnas, Got2 and Snord32a following tenofovir exposure of primary osteoclasts

Clinical observations have implicated the antiretroviral drug tenofovir with bone density loss during the management of HIV infection. The goal of this study was to investigate the in vitro effects of tenofovir exposure of primary osteoclasts in order to gain insights into the potential mechanisms for the drug-induced bone density loss. We hypothesized that tenofovir may alter the expression of key genes involved in osteoclast function. To test this, primary osteoclasts were exposed to physiologically relevant concentrations of the prodrug tenofovir disoproxil fumarate (TDF), then intensive microarray analysis was done to compare tenofovir-treated versus untreated cells. Specific downregulation of Gnas, Got2 and Snord32a were observed in the TDF-treated cells. The functions of these genes help to explain the basis for tenofovir-associated bone density loss. Our studies represent the first analysis of the effects of tenofovir on osteoclast gene expression and help to explain the basis of tenofovir-associated bone density loss in HIV-infected individuals.

The microphthalmia transcription factor (MITF) contains two N-terminal domains required for transactivation of osteoclast target promoters and rescue of mi mutant osteoclasts

The microphthalmia transcription factor (MITF) regulates gene expression during differentiation of several distinct cell types, including osteoclasts. A structure/function analysis was performed to determine whether transcription activation domains were important for MITF action in osteoclasts. In addition to a previously characterized acidic activation necessary for melanocyte differentiation, the analysis defined a second potential activation domain located between amino acids 140 and 185. This second domain is required for MITF transactivation of two probable targets, the E‐cadherin promoter and the tartrate‐resistant acid phosphatase promoter, in transient transfection assays. An intact MITF gene rescued differentiation when introduced into osteoclasts derived from mi/mi mice using a retrovirus vector. In parallel experiments, an MITF gene lacking the acidic‐activation domain rescued differentiation twofold less efficiently than wild type, and a gene lacking the region between amino acid residues 140 and 185 rescued differentiation tenfold less efficiently than wild type. The results indicate that the N‐terminal region of MITF is necessary for activation of gene expression in osteoclasts and provides one mechanism by which this factor regulates distinct target genes in different cell types.