TY - JOUR
T1 - Inference of long-range cell-cell force transmission from ECM remodeling fluctuations
AU - Nahum, Assaf
AU - Koren, Yoni
AU - Ergaz, Bar
AU - Natan, Sari
AU - Miller, Gad
AU - Tamir, Yuval
AU - Goren, Shahar
AU - Kolel, Avraham
AU - Jagadeeshan, Sankar
AU - Elkabets, Moshe
AU - Lesman, Ayelet
AU - Zaritsky, Assaf
N1 - Funding Information:
This work was supported by the Israeli Council for Higher Education (CHE) via Data Science Research Center, Ben-Gurion University of the Negev, Israel (to A.Z.), by the Wellcome Leap Delta Tissue program (to A.Z.), the Israel Science Foundation (1474/16, to A.L.), the Israel Science Foundation- Israeli Centers for Research Excellence (1902/12, to A.L.), and the Zimin Institute for Engineering Solutions Advancing Better Lives (to A.L.). We thank Oren Tchaicheeyan, Nir Gov and Meghan Driscoll for critically reading the manuscript. We thank Jean-Yves Tinevez and Dmitry Ershov from Institut Pasteur for training AN in image acquisition and analysis, this training was made possible thanks to NEUBIAS (COST Action, CA15124) Short Term Scientific Mission (STSM).
Funding Information:
This work was supported by the Israeli Council for Higher Education (CHE) via Data Science Research Center, Ben-Gurion University of the Negev, Israel (to A.Z.), by the Wellcome Leap Delta Tissue program (to A.Z.), the Israel Science Foundation (1474/16, to A.L.), the Israel Science Foundation- Israeli Centers for Research Excellence (1902/12, to A.L.), and the Zimin Institute for Engineering Solutions Advancing Better Lives (to A.L.). We thank Oren Tchaicheeyan, Nir Gov and Meghan Driscoll for critically reading the manuscript. We thank Jean-Yves Tinevez and Dmitry Ershov from Institut Pasteur for training AN in image acquisition and analysis, this training was made possible thanks to NEUBIAS (COST Action, CA15124) Short Term Scientific Mission (STSM).
Publisher Copyright:
© 2023, Springer Nature Limited.
PY - 2023/12/1
Y1 - 2023/12/1
N2 - Cells sense, manipulate and respond to their mechanical microenvironment in a plethora of physiological processes, yet the understanding of how cells transmit, receive and interpret environmental cues to communicate with distant cells is severely limited due to lack of tools to quantitatively infer the complex tangle of dynamic cell-cell interactions in complicated environments. We present a computational method to systematically infer and quantify long-range cell-cell force transmission through the extracellular matrix (cell-ECM-cell communication) by correlating ECM remodeling fluctuations in between communicating cells and demonstrating that these fluctuations contain sufficient information to define unique signatures that robustly distinguish between different pairs of communicating cells. We demonstrate our method with finite element simulations and live 3D imaging of fibroblasts and cancer cells embedded in fibrin gels. While previous studies relied on the formation of a visible fibrous ‘band’ extending between cells to inform on mechanical communication, our method detected mechanical propagation even in cases where visible bands never formed. We revealed that while contractility is required, band formation is not necessary, for cell-ECM-cell communication, and that mechanical signals propagate from one cell to another even upon massive reduction in their contractility. Our method sets the stage to measure the fundamental aspects of intercellular long-range mechanical communication in physiological contexts and may provide a new functional readout for high content 3D image-based screening. The ability to infer cell-ECM-cell communication using standard confocal microscopy holds the promise for wide use and democratizing the method.
AB - Cells sense, manipulate and respond to their mechanical microenvironment in a plethora of physiological processes, yet the understanding of how cells transmit, receive and interpret environmental cues to communicate with distant cells is severely limited due to lack of tools to quantitatively infer the complex tangle of dynamic cell-cell interactions in complicated environments. We present a computational method to systematically infer and quantify long-range cell-cell force transmission through the extracellular matrix (cell-ECM-cell communication) by correlating ECM remodeling fluctuations in between communicating cells and demonstrating that these fluctuations contain sufficient information to define unique signatures that robustly distinguish between different pairs of communicating cells. We demonstrate our method with finite element simulations and live 3D imaging of fibroblasts and cancer cells embedded in fibrin gels. While previous studies relied on the formation of a visible fibrous ‘band’ extending between cells to inform on mechanical communication, our method detected mechanical propagation even in cases where visible bands never formed. We revealed that while contractility is required, band formation is not necessary, for cell-ECM-cell communication, and that mechanical signals propagate from one cell to another even upon massive reduction in their contractility. Our method sets the stage to measure the fundamental aspects of intercellular long-range mechanical communication in physiological contexts and may provide a new functional readout for high content 3D image-based screening. The ability to infer cell-ECM-cell communication using standard confocal microscopy holds the promise for wide use and democratizing the method.
UR - http://www.scopus.com/inward/record.url?scp=85166547599&partnerID=8YFLogxK
U2 - 10.1038/s42003-023-05179-1
DO - 10.1038/s42003-023-05179-1
M3 - Article
C2 - 37537232
AN - SCOPUS:85166547599
SN - 2399-3642
VL - 6
JO - Communications Biology
JF - Communications Biology
IS - 1
M1 - 811
ER -