Single-cell migration along and against confined haptotactic gradients
Fortunato IC, Brückner D, Grosser S, Nautiyal R, Rossetti L, Bosch-Padrós M, Trebicka J, Roca-Cusachs P, Sunyer R, Hannezo EB, Trepat X. 2025. Single-cell migration along and against confined haptotactic gradients. Nature Physics.
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Author
Fortunato, Isabela Corina;
Brückner, DavidISTA 
;
Grosser, Steffen;
Nautiyal, Rohit;
Rossetti, Leone;
Bosch-Padrós, Miquel;
Trebicka, Jonel;
Roca-Cusachs, Pere;
Sunyer, Raimon;
Hannezo, Edouard ISTA ;
Trepat, Xavier
;
Grosser, Steffen;
Nautiyal, Rohit;
Rossetti, Leone;
Bosch-Padrós, Miquel;
Trebicka, Jonel;
Roca-Cusachs, Pere;
Sunyer, Raimon;
Hannezo, Edouard ISTA ;
Trepat, XavierCorresponding author has ISTA affiliation
Department
Abstract
Haptotaxis is the process of directed cell migration along gradients of extracellular matrix density and is central to morphogenesis, immune responses and cancer invasion. It is commonly assumed that cells respond to these gradients by migrating directionally towards the regions of highest ligand density. In contrast with this view, here we show that cells exposed to micropatterned fibronectin gradients exhibit a wide range of complex trajectories, including directed haptotactic migration up the gradient but also linear oscillations and circles with extended periods of migration down the gradient. To explain this behaviour, we developed a biophysical model of haptotactic cell migration based on a coarse-grained molecular clutch model coupled to persistent stochastic polarity dynamics. Although initial haptotactic migration is explained by the differential friction at the front and back of the cell, the observed complex trajectories over longer timescales arise from the interplay between differential friction, persistence and physical confinement. Overall, our study reveals that confinement and persistence modulate the ability of cells to sense and respond to haptotactic cues and provides a framework for understanding how cells navigate complex environments.
Publishing Year
Date Published
2025-09-26
Journal Title
Nature Physics
Publisher
Springer Nature
Acknowledgement
We thank all the members of our groups for discussions and support. We thank A. Menéndez, S. Usieto, M. Purciolas and E. Coderch for technical assistance. We thank G. Charras (London Centre for Nanotechnology, UK) and M. Sheetz (Columbia University, USA) for sharing cells used in this work. We thank J. Ivaska (University of Turku, Finland) for sharing integrin α5-GFP DNA plasmid. We thank P. Guillamat for technical advice and A. Labernardie for providing the microfluidic channels. We thank M. Gómez-González for sharing the 2D traction microscopy algorithm. Finally, we thank P. Guillamat, J. Abenza, G. Ceada, L. Faure, E. Dalaka, M. Matejčić, A. Beedle, I. Granero, O. Baguer, A. Albajar and N. Chahare for discussions. This paper was funded by the Generalitat de Catalunya (Grant Nos. AGAUR SGR-2017-01602 to X.T. and 2021 SGR 00523 to R.S. and the CERCA Programme and ICREA Academia awards to P.R.-C.), the Spanish Ministry for Science and Innovation MICCINN/FEDER (Grant Nos. PID2021-128635NB-I00, MCIN/AEI/10.13039/501100011033 and ERDF-EU A way of making Europe to X.T., PID2021-128674OB-I00 and CNS2022-135533 to R.S. and PID2019-110298GB-I00 to P.R.-C.), the European Research Council (Grant Nos. 101097753 to P.R.-C. and Adv-883739 to X.T.), Fundació la Marató de TV3 (Project Award 201903-30-31-32 to X.T.), the European Commission (Grant No. H2020-FETPROACT-01-2016-731957 to P.R.-C. and X.T.) and La Caixa Foundation (Grant No. LCF/PR/HR20/52400004 to P.R.-C. and X.T.). R.S. is a Serra-Hunter fellow. D.B.B. was supported by the NOMIS foundation as a NOMIS fellow, by the European Molecular Biology Organization (Postdoctoral Fellowship ALTF 343-2022) and by the Austrian Academy of Sciences through an APART-MINT Fellowship. I.C.F. acknowledges support from the European Foundation for the Study of Chronic Liver Failure. IBEC is recipient of a Severo Ochoa Award of Excellence from MINECO.
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IST-REx-ID
Cite this
Fortunato IC, Brückner D, Grosser S, et al. Single-cell migration along and against confined haptotactic gradients. Nature Physics. 2025. doi:10.1038/s41567-025-03015-3
Fortunato, I. C., Brückner, D., Grosser, S., Nautiyal, R., Rossetti, L., Bosch-Padrós, M., … Trepat, X. (2025). Single-cell migration along and against confined haptotactic gradients. Nature Physics. Springer Nature. https://doi.org/10.1038/s41567-025-03015-3
Fortunato, Isabela Corina, David Brückner, Steffen Grosser, Rohit Nautiyal, Leone Rossetti, Miquel Bosch-Padrós, Jonel Trebicka, et al. “Single-Cell Migration along and against Confined Haptotactic Gradients.” Nature Physics. Springer Nature, 2025. https://doi.org/10.1038/s41567-025-03015-3.
I. C. Fortunato et al., “Single-cell migration along and against confined haptotactic gradients,” Nature Physics. Springer Nature, 2025.
Fortunato IC, Brückner D, Grosser S, Nautiyal R, Rossetti L, Bosch-Padrós M, Trebicka J, Roca-Cusachs P, Sunyer R, Hannezo EB, Trepat X. 2025. Single-cell migration along and against confined haptotactic gradients. Nature Physics.
Fortunato, Isabela Corina, et al. “Single-Cell Migration along and against Confined Haptotactic Gradients.” Nature Physics, Springer Nature, 2025, doi:10.1038/s41567-025-03015-3.
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