Human mesenchymal stem cells (MSCs) are multipotent stem cells that differentiate into many of the cells resident in musculoskeletal and stromal tissues of the human body, including fibroblasts, chondrocytes, osteoblasts, myocytes, and adipocytes. While differentiation of the MSCs into appropriate lineages may enhance healing of injured tissues, inappropriate lineage specification may be responsible for numerous pathophysiologic processes, including the decreased bone and increased fat in osteoporotic bones, and the calcification of atherosclerotic vessel walls. Regulation of the lineage commitment of MSCs by local microenvironmental cues therefore may be critical to our fundamental understanding of numerous degenerative as well as healing processes. The long term objective of this research is to characterize the cues within the local surrounding microenvironment that drive the lineage specification and differentiation of human mesenchymal stem cells (MSCs), and the molecular pathways involved. The investigator has recently discovered that adhesion of MSCs to fibronectin regulates a commitment switch in the MSCs between adipogenic and osteogenic lineage specification, through a mechanism involving RhoA signaling and cytoskeletal tension. In this proposal, the investigator proposes to further characterize how adhesive and mechanical cues regulate the commitment of MSCs to osteogenic and adipogenic lineages.
Specific Aim 1 will be to investigate the role of integrin-mediated cell adhesion in modulating mesenchymal stem cell commitment by characterizing the binding interactions that drive the MSC lineage commitment switch between osteoblasts and adipocytes.
Specific Aim 2 will be to investigate the coordination of RhoA and cytoskeletal tension in the regulation of stem cell commitment.
Specific Aim 3 will be to investigate the ability of RhoA to regulate stem cell commitment and differentiation in an animal model. Together, these studies will define roles of cell adhesion, RhoA, and cytoskeletal tension in MSC lineage commitment, and establish a molecular basis for the regulation of MSC differentiation by microenvironmental cues. ? ?
| Polacheck, William J; Chen, Christopher S (2016) Measuring cell-generated forces: a guide to the available tools. Nat Methods 13:415-23 |
| Heo, Su-Jin; Driscoll, Tristan P; Thorpe, Stephen D et al. (2016) Differentiation alters stem cell nuclear architecture, mechanics, and mechano-sensitivity. Elife 5: |
| Cohen, Daniel M; Won, Kyoung-Jae; Nguyen, Nha et al. (2015) ATF4 licenses C/EBP? activity in human mesenchymal stem cells primed for adipogenesis. Elife 4:e06821 |
| Baker, Brendon M; Trappmann, Britta; Wang, William Y et al. (2015) Cell-mediated fibre recruitment drives extracellular matrix mechanosensing inĀ engineered fibrillar microenvironments. Nat Mater 14:1262-8 |
| Bellas, Evangelia; Chen, Christopher S (2014) Forms, forces, and stem cell fate. Curr Opin Cell Biol 31:92-7 |
| Desai, Ravi A; Rodriguez, Natalia M; Chen, Christopher S (2014) ""Stamp-off"" to micropattern sparse, multicomponent features. Methods Cell Biol 119:3-16 |
| Blakely, Brandon L; Dumelin, Christoph E; Trappmann, Britta et al. (2014) A DNA-based molecular probe for optically reporting cellular traction forces. Nat Methods 11:1229-32 |
| Breckenridge, Mark T; Desai, Ravi A; Yang, Michael T et al. (2014) Substrates with engineered step changes in rigidity induce traction force polarity and durotaxis. Cell Mol Bioeng 7:26-34 |
| Legant, Wesley R; Choi, Colin K; Miller, Jordan S et al. (2013) Multidimensional traction force microscopy reveals out-of-plane rotational moments about focal adhesions. Proc Natl Acad Sci U S A 110:881-6 |
| Baker, Brendon M; Trappmann, Britta; Stapleton, Sarah C et al. (2013) Microfluidics embedded within extracellular matrix to define vascular architectures and pattern diffusive gradients. Lab Chip 13:3246-52 |
Showing the most recent 10 out of 52 publications
