Manipulating the Bone Marrow Microenvironment to Prevent Survival of AML Cells

The bone marrow microenvironment acts as a protective niche for malignant cells. Within the bone marrow microenvironment is the endosteal niche, which is the area where the ossified surface of the bone and marrow cavity interact. The endosteal niche provides the opportunity for hematological malignancies such as acute myeloid leukemia (AML) of the bone marrow to interact with osteoblasts from the bone. To study the interaction between AML cells and osteoblasts, our lab developed a co‐culture model of osteoblasts (MC3T3 osteoblast cell line) and AML cells (KG1a cell line or patient samples from bone marrow aspirates). AML cells expressing high levels of CXCR4 were cultured alone or with osteoblasts and then challenged with SDF‐1, the ligand to CXCR4 and a chemokine readily abundant in the bone marrow microenvironment that our lab has previously shown actually induces apoptosis in AML cells expressing high levels of CXCR4 and that osteoblasts are able to protect AML cells from SDF‐1 induced apoptosis. Our lab now shows that treating osteoblasts with cyclosporine (CSA) prevents their ability to effectively protect AML cells from SDF‐1 induced cell death as assayed by annexin‐V staining of AML cells by flow cytometry. CSA treatment of osteoblasts decreased protein levels of tissue non‐specific alkaline phosphatase (ALPL), a phosphatase necessary for osteoblast mineralization, compared to vehicle control. As such, osteoblasts were treated with control siRNA or ALPL siRNA. CXCR4 expressing AML cells were then co‐cultured with the transfected osteoblasts and challenged with SDF‐1. siRNA knockdown of ALPL in osteoblasts was sufficient to prevent protection of AML cells from the apoptotic stimuli. These studies indicate that osteoblast differentiation plays a role in mediating the protection of AML cells. Therefore, targeting specific differentiation factors in osteoblasts may help to make to bone marrow microenvironment a more hostile environment for AML cells and aid in better malignancy eradication. Support or Funding Information This study was supported by NIH R21 CA194217 (to K.E.H.). R.M.S. is supported by the Mayo Clinic Medical Scientist Training Program Robert L. Howell Physician‐Scientist Scholarship.