Intercellular signaling through secreted proteins induces free-energy gradient-directed cell movement
Abstract
Controlling cell migration is important in tissue engineering and medicine. Cell motility depends on factors such as nutrient concentration gradients and soluble factor signaling. In particular, cell–cell signaling can depend on cell–cell separation distance and can influence cellular arrangements in bulk cultures. Here, we seek a physical-based approach, which identifies a potential governed by cell–cell signaling that induces a directed cell–cell motion. A single-cell barcode chip (SCBC) was used to experimentally interrogate secreted proteins in hundreds of isolated glioblastoma brain cancer cell pairs and to monitor their relative motions over time. We used these trajectories to identify a range of cell–cell separation distances where the signaling was most stable. We then used a thermodynamics-motivated analysis of secreted protein levels to characterize free-energy changes for different cell–cell distances. We show that glioblastoma cell–cell movement can be described as Brownian motion biased by cell–cell potential. To demonstrate that the free-energy potential as determined by the signaling is the driver of motion, we inhibited two proteins most involved in maintaining the free-energy gradient. Following inhibition, cell pairs showed an essentially random Brownian motion, similar to the case for untreated, isolated single cells.
Additional Information
© 2016 National Academy of Sciences. Edited by Michael L. Klein, Temple University, Philadelphia, PA, and approved March 31, 2016 (received for review February 8, 2016). Published online before print May 2, 2016. We acknowledge helpful discussions with Dr. David A. Nathanson and Lisa Ta. This work was funded by National Cancer Institute Grant 1U54CA199090-01 [to J.R.H., principal investigator (PI)], the Ben and Catherine Ivy Foundation (J.R.H.), the Jean Perkins Foundation (J.R.H., PI), the Korean-American Scientists and Engineers Association (Y.S.S., PI), the Phelps Family Foundation (Y.S.S.), and European Commission FP7 Future and Emerging Technologies–Open Project BAMBI 618024 (to R.D.L.). N.K.-B. was supported by an EMBO postdoctoral fellowship. Author contributions: N.K.-B., Y.S.S., R.D.L., and J.R.H. designed research; N.K.-B. performed theoretical research; Y.S.S. performed experimental research; N.K.-B., Y.S.S., A.S., R.D.L., and J.R.H. contributed new reagents/analytic tools; N.K.-B., Y.S.S., R.D.L., and J.R.H. analyzed data; and N.K.-B., Y.S.S., R.D.L., and J.R.H. wrote the paper. N.K.-B. and Y.S.S. contributed equally to this work. The authors declare no conflict of interest. This article is a PNAS Direct Submission. This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10.1073/pnas.1602171113/-/DCSupplemental.Attached Files
Published - PNAS-2016-Kravchenko-Balasha-5520-5.pdf
Supplemental Material - pnas.201602171SI.pdf
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Additional details
- PMCID
- PMC4878481
- Eprint ID
- 66602
- Resolver ID
- CaltechAUTHORS:20160503-072858145
- 1U54CA199090-01
- National Cancer Institute
- Ben and Catherine Ivy Foundation
- Jean Perkins Foundation
- Korean-American Scientists and Engineers Association
- Phelps Family Foundation
- 618024
- European Research Council (ERC)
- European Molecular Biology Organization (EMBO)
- Created
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2016-05-03Created from EPrint's datestamp field
- Updated
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2022-04-28Created from EPrint's last_modified field