Bone-stimulatory therapeutics include bone morphogenetic proteins (e.g. BMP2), parathyroid hormone, and antibody-based suppression of WNT antagonists. Inhibition of the epigenetic enzyme enhancer of zeste homolog 2 (EZH2) is both bone anabolic and osteoprotective. EZH2 inhibition stimulates key components of bone-stimulatory signaling pathways, including the BMP2 signaling cascade. Because of high costs and adverse effects associated with BMP2 use, here we investigated whether BMP2 dosing can be reduced by co-treatment with EZH2 inhibitors. Co-administration of BMP2 with the EZH2 inhibitor GSK126 enhanced differentiation of murine (MC3T3) osteoblasts, reflected by increased alkaline phosphatase activity, Alizarin Red staining, and expression of bone-related marker genes (e.g. Bglap and Phospho1). Strikingly, co-treatment with BMP2 (10 ng/ml) and GSK126 (5 μm) was synergistic and was as effective as 50 ng/ml BMP2 at inducing MC3T3 osteoblastogenesis. Similarly, the BMP2-GSK126 co-treatment stimulated osteogenic differentiation of human bone marrow-derived mesenchymal stem/stromal cells, reflected by induction of key osteogenic markers (e.g. Osterix/SP7 and IBSP). A combination of BMP2 (300 ng local) and GSK126 (5 μg local and 5 days of 50 mg/kg systemic) yielded more consistent bone healing than single treatments with either compound in a mouse calvarial critical-sized defect model according to results from μCT, histomorphometry, and surgical grading of qualitative X-rays. We conclude that EZH2 inhibition facilitates BMP2-mediated induction of osteogenic differentiation of progenitor cells and maturation of committed osteoblasts. We propose that epigenetic priming, coupled with bone anabolic agents, enhances osteogenesis and could be leveraged in therapeutic strategies to improve bone mass.
Skeletal development is controlled by epigenetic mechanisms that regulate chromatin compaction and suppress access to gene regulatory sequences. Post‐translational modifications in the N‐termini of histone 3 (H3), including tri‐methylated H3 lysine 9 (H3K9Me3) or lysine 27 (H3K27Me3) represent repressive chromatin marks that are recognized by a family of heterochromatin‐associated Chromobox (Cbx) proteins (i.e., Cbx1 to Cbx8). We show using RNA‐seq analysis that each of these Cbx isoforms is actively expressed in bone and osteoblasts with variable expression of distinct members (between 1 and 100 reads per million). The most prominently expressed Cbx member is Cbx3, which encodes a member of the heterochromatin protein 1 (HP1) family that interacts with H3K9me3. Cbx3 is known to be important for normal development while promoting neurogenesis, as well as renal and smooth muscle development. Therefore, we postulated that CBx3 may perform a similar role in osteoblastogenesis. We tested this hypothesis by both transient and stable knock‐down of Cbx3 by respectively siRNA or shRNA. RNA interference in MC3T3 osteoblasts effectively decreases Cbx3 mRNA levels by 2 to 5 fold, while increasing expression of bone‐related markers by RT‐qPCR (e.g., Alpl/alkaline phosphatase, Ibsp/bone sialoprotein, Bglap/osteocalcin, and Col1a1/Collagen Type I α1 chain). In addition, Cbx3 depletion increases mineral deposition as measured by Alizarin Red staining. Thus, Cbx3 normally appears to suppress osteoblastic differentiation, unlike its essential function in the neuronal differentiation. Because Cbx3 recognizes H3K9me3, we examined whether Cbx3 controls the levels of this histone mark. Loss of Cbx3 did not affect total H3K9me3 levels unless Cbx1 and Cbx5 were simultaneously depleted by siRNA. We propose that Cbx3 may suppress osteoblastogenesis by controlling select loci with H3K9me3 marks.
The bone marrow microenvironment harbors and protects leukemic cells from apoptosis-inducing agents via mechanisms that are incompletely understood. We previously showed SDF-1 (CXCL-12), a chemokine readily abundant within the bone marrow microenvironment, induces apoptosis in acute myeloid leukemia (AML) cells that express high levels of the SDF-1 receptor CXCR4. However, differentiating osteoblasts found within this niche protect cocultured AML cells from apoptosis. Additionally, this protection was abrogated upon treatment of the differentiating osteoblasts with histone deacetylase inhibitors (HDACi). In this study, we begin to characterize and target the molecular mechanisms that mediate this osteoblast protection. Quantitative RT-PCR revealed that HDACi treatment of differentiating osteoblasts (mouse MC3T3 osteoblast cell line) reduced expression of multiple genes required for osteoblast differentiation, including genes important for producing mineralized bone matrix. Interestingly, pretreating differentiating osteoblasts with cyclosporine A, a drug known to inhibit osteoblast differentiation, similarly impaired osteoblast-mediated protection of cocultured AML cells (KG1a and U937 human AML cell lines). Both HDACi and cyclosporine A reduced osteoblast expression of the key mineralization enzyme tissue-nonspecific alkaline phosphatase (TNAP; encoded by Alpl). Moreover, specifically reducing TNAP expression or activity in differentiating osteoblasts significantly impaired the ability of the osteoblasts to protect cocultured AML cells. Together, our results indicate that inhibiting osteoblast matrix mineralization by specifically targeting TNAP is sufficient to significantly impair osteoblast-mediated protection of AML cells. Therefore, designing combination therapies that additionally target the osteoblast-produced mineralized bone matrix may improve treatment of AML by reducing the protection of leukemic cells within the bone marrow microenvironment.
Abstract The catalytic subunit of DNA‐dependent protein kinase (DNA‐PKcs) is a pleiotropic enzyme involved in DNA repair, cell cycle control, and transcription regulation. A potential role for DNA‐PKcs in the regulation of osteoblastogenesis remains to be established. We show that pharmacological inhibition of DNA‐PKcs kinase activity or gene silencing of Prkdc (encoding DNA‐PKcs) in murine osteoblastic MC3T3‐E1 cells and human adipose‐derived mesenchymal stromal cells markedly enhanced osteogenesis and the expression of osteoblast differentiation marker genes. Inhibition of DNA‐PKcs inhibited cell cycle progression and increased osteogenesis by significantly enhancing the bone morphogenetic protein 2 response in osteoblasts and other mesenchymal cell types. Importantly, in vivo pharmacological inhibition of the kinase enhanced bone biomechanical properties. Bones from osteoblast‐specific conditional Prkdc ‐knockout mice exhibited a similar phenotype of increased stiffness. In conclusion, DNA‐PKcs negatively regulates osteoblast differentiation, and therefore DNA‐PKcs inhibitors may have therapeutic potential for bone regeneration and metabolic bone diseases.
Abstract The hematological malignancy acute myeloid leukemia (AML) interacts closely with osteoblasts within the protective bone marrow microenvironment. The bone marrow microenvironment protects tumor cells from chemotherapies, which can prevent sufficient eradication of tumor cells. To study the role of osteoblasts in the bone marrow microenvironment, our lab utilized a co-culture model of osteoblasts (MC3T3 osteoblast cell line) and acute myelogenous leukemia cells (KG1a AML cell line or AML patient samples from bone marrow aspirates). Osteoblasts were cultured with AML cells, or AML cells were cultured alone; AML cells were challenged with the standard chemotherapeutic agent cytarabine (Ara-C) at doses of 0µM, 0.1µM, 0.5µM, 1µM, 5µM, or 10µM in the presence or absence of osteoblasts; and AML cells were assayed by flow cytometry to assess cell death via annexin-V staining. Our lab has previously found that differentiating osteoblasts protect AML cells from an apoptosis inducing agent naturally present in the bone marrow. We now show that osteoblasts are also capable of protecting AML cells from the standard chemotherapeutic cytarabine. In addition, we have found that treatment of osteoblasts with the histone deacetylase inhibitor (HDACi) suberoylanilide hydroxamic acid (SAHA) prevents these treated osteoblasts from protecting AML cells from cytarabine treatment, which is consistent with our lab’s previous findings that HDACi treatment inhibits protection of AML cells from an apoptosis inducing agent naturally present in the bone marrow. We have preliminary data that indicates that TAZS89A over-expression, a constitutively active form of TAZ, which is a transcriptional modulator that regulates osteoblast differentiation, may be sufficient to inhibit osteoblast mediated protection of AML cells from cytarabine. This finding would be consistent with the HDACi manipulated Nherf1-protein phosphatase 1α-TAZ signaling pathway that we have previously found to be sufficient to inhibit protection of AML cells from an apoptosis inducing agent naturally present in the bone marrow. Overall, these studies have delivered insights into the role of osteoblasts in protecting AML cells from chemotherapy in the bone marrow microenvironment and begun the characterization of mechanisms and targets responsible for the protective effects of osteoblasts. Manipulating differentiating osteoblasts within the bone marrow microenvironment therapeutically could aid in more complete destruction of the tumor cell burden and improve patient survival. Citation Format: Rosalie M. Sterner, Kimberly N. Kremer, Amel Dudakovic, Jennifer J. Westendorf, Andre J. van Wijnen, Karen E. Hedin. Osteoblasts protect AML cells from cytarabine-induced death [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 5930. doi:10.1158/1538-7445.AM2017-5930
Anterior cruciate ligament (ACL) injuries are frequent, as >200,000 injuries occur in the United States alone each year. Owing to the risks for associated meniscus and cartilage damage, ACL injuries are a significant source of both orthopedic care and research. Given the extended recovery course after ACL injury, which often lasts 1-2 years, and is associated with limited participation in sports and activities of daily living for patients, there is a critical need for the evolution of new and improved methods for ACL repair. Subsequently, animal models of ACL reconstruction (ACLR) play a key role in the development and initial trialing of novel ACL interventions. This article provides a clear operative description and associated illustrations for a validated, institutional animal care and use committee, and veterinarian approved and facile model of ACLR to serve researchers investigating ACLR.
