Mechanical programming to enhance the immunosuppressive function of mesenchymal stem cells for the treatment of graft-versus-host disease.
Johns Hopkins University, Baltimore MD
Investigators
Abstract
SPECIFIC AIMS Mesenchymal stem/stromal cells (MSCs) are potent regulators of immune cells, and their immunosuppressive function is being actively investigated for a number of therapeutic applications. In particular, it has been demonstrated that MSCs can inhibit the proliferation of effector T cells and induce regulatory T-cell differentiation for treating graft versus host disease (GvHD). A few MSC products have been approved by regulatory agencies in countries outside of the U.S. However, MSCs have not always shown consistent efficacy in GvHD clinical trials. This is in part due to the challenges of generating MSCs with consistent, high therapeutic potency. The overarching goal of this project is to develop MSC therapies with enhanced immunosuppressive efficacy for GvHD treatment by identifying and providing optimal microenvironment mechanical cues in MSC production. Mechanical cues from cell microenvironment play important roles in regulating cell behavior. For example, studies have shown that matrix stiffness directs cell activity and fate such as migration, proliferation, and differentiation. However, matrix or material stiffness only describes their static, elastic mechanical property. Instead of being simply elastic, natural extracellular matrix (ECM) and living tissues are viscoelastic, exhibiting stress relaxation over different characteristic time scales (stress relaxes at different rates). We have developed a hydrogel system that can recapitulate the stiffness and viscoelastic behavior of different types of tissues. Using the hydrogels as culture substrates, we discovered that matrix stress relaxation, in addition to stiffness, is an important mechanical factor regulating cellâECM interactions and directing MSC activities including spreading, proliferation, differentiation, and in vivo bone regeneration. In collaboration with Dr. Kyung Sung at FDA, we recently found that substrate stress relaxation also regulates MSC's immunosuppressive capacity and their ability to inhibit T cell proliferation; Interestingly, MSCs retained their mechanical âmemoryâ even after being extracted from the hydrogels (see preliminary data section). In light of these new findings, we hypothesize that biomaterials with tailored stress relaxation properties can provide inducing mechanical cues in MSC production to enhance MSC's immunosuppressive efficacy for GvHD treatment. We will test this hypothesis in the following specific aims: Aim 1: Elucidate the molecular mechanisms by which matrix stress relaxation regulates the immunosuppressive capacity of human MSCs (hMSC) derived from bone marrow. Aim 2: Compare the effect of matrix stress relaxation on hMSCs derived from different tissues or hMSC subpopulations sorted by integrin expression. Aim 3: Evaluate the efficacy of hMSCs primed by viscoelastic hydrogels with different stress relaxation properties for GvHD treatment in an animal model. This project uses multidisciplinary approaches to study hMSC mechanobiology. Successful completion of these aims will have significant impact in understanding how matrix mechanical cues regulates the immunosuppressive capacity of hMSCs, with the findings potentially leading to better treatment for GvHD.
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