Boundary crossing in epithelial wound healing
- Creators
- Fong, Eileen
- Tzlil, Shelly
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Tirrell, David A.
Abstract
The processes of wound healing and collective cell migration have been studied for decades. Intensive research has been devoted to understanding the mechanisms involved in wound healing, but the role of cell-substrate interactions is still not thoroughly understood. Here we probe the role of cell-substrate interactions by examining in vitro the healing of monolayers of human corneal epithelial (HCE) cells cultured on artificial extracellular matrix (aECM) proteins. We find that the rate of wound healing is dependent on the concentration of fibronectin-derived (RGD) cell-adhesion ligands in the aECM substrate. The wound closure rate varies nearly sixfold on the substrates examined, despite the fact that the rates of migration and proliferation of individual cells show little sensitivity to the RGD concentration (which varies 40-fold). To explain this apparent contradiction, we study collective migration by means of a dynamic Monte Carlo simulation. The cells in the simulation spread, retract, and proliferate with probabilities obtained from a simple phenomenological model. The results indicate that the overall wound closure rate is determined primarily by the rate at which cells cross the boundary between the aECM protein and the matrix deposited under the cell sheet.
Additional Information
© 2010 National Academy of Sciences. Edited by Steven Boxer, Stanford University, Stanford, CA, and approved September 7, 2010 (received for review June 11, 2010). We acknowledge Drs. Julie Liu, Paul Nowatzki, and Stacey Maskarinec for help with protein expression and cell culture. We also thank Dr. Zhen-Gang Wang for useful advice on the simulation model. E.F. is supported by the Nanyang Overseas Scholarship, Singapore; S.T. is supported by the Human Frontier Science Program Cross-Disciplinary fellowship. This work is funded by the National Science Foundation Center for the Science and Engineering of Materials at Caltech and by National Institutes of Health Grant EB1971. Author contributions: E.F., S.T., and D.A.T. designed research; E.F. and S.T. performed research; E.F., S.T., and D.A.T. analyzed data; and E.F., S.T., and D.A.T. wrote the paper.Attached Files
Published - Fong2010p11981P_Natl_Acad_Sci_Usa.pdf
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Supplemental Material - pnas.1008291107_SI.pdf
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Additional details
- PMCID
- PMC2984212
- Eprint ID
- 21191
- Resolver ID
- CaltechAUTHORS:20101206-122849107
- Nanyang Overseas Scholarship
- Human Frontier Science Program
- NSF
- EB1971
- NIH
- Created
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2010-12-14Created from EPrint's datestamp field
- Updated
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2021-11-09Created from EPrint's last_modified field