Lamellipodial tension, not integrin/ligand binding, is the crucial factor to realise integrin activation and cell migration

Carsten Schulte; Gian Maria Sarra Ferraris; Amanda Oldani; Massimiliano Galluzzi; Alessandro Podestà; Luca Puricelli; Valentina de Lorenzi; Cristina Lenardi; Paolo Milani; Nicolai Sidenius

doi:10.1016/j.ejcb.2015.10.002

Lamellipodial tension, not integrin/ligand binding, is the crucial factor to realise integrin activation and cell migration

Carsten Schulte^*, Gian Maria Sarra Ferraris, Amanda Oldani, Massimiliano Galluzzi, Alessandro Podestà, Luca Puricelli, Valentina de Lorenzi, Cristina Lenardi, Paolo Milani, Nicolai Sidenius

^*Corresponding author for this work

Biomedical Engineering

Research output: Contribution to journal › Article › peer-review

17 Citations (Scopus)

Abstract

The molecular clutch (MC) model proposes that actomyosin-driven force transmission permits integrin-dependent cell migration. To investigate the MC, we introduced diverse talin (TLN) and integrin variants into Flp-In^™ T-Rex^™ HEK293 cells stably expressing uPAR. Vitronectin variants served as substrate providing uPAR-mediated cell adhesion and optionally integrin binding. This particular system allowed us to selectively analyse key MC proteins and interactions, effectively from the extracellular matrix substrate to intracellular f-actin, and to therewith study mechanobiological aspects of MC engagement also uncoupled from integrin/ligand binding. With this experimental approach, we found that for the initial PIP₂-dependent membrane/TLN/f-actin linkage and persistent lamellipodia formation the C-terminal TLN actin binding site (ABS) is dispensable. The establishment of an adequate MC-mediated lamellipodial tension instead depends predominantly on the coupling of this C-terminal TLN ABS to the actomyosin-driven retrograde actin flow force. This lamellipodial tension is crucial for full integrin activation eventually determining integrin-dependent cell migration. In the integrin/ligand-independent condition the frictional membrane resistance participates to these processes. Integrin/ligand binding can also contribute but is not necessarily required.

Original language	English
Pages (from-to)	1-14
Number of pages	14
Journal	European Journal of Cell Biology
Volume	95
Issue number	1
DOIs	https://doi.org/10.1016/j.ejcb.2015.10.002
Publication status	Published - 1 Jan 2016

Funding

This work was supported by research grants from the Italian Association for Cancer Research (AIRC) and the Cariplo foundation hold by NS. VDL was supported by a fellowship from the AIRC. Furthermore, this project has been supported by the Italian Ministry of University and Research, MIUR, through the “National Funding for Basic Research” (FIRB) hold by CL. COST Action TD1002 is acknowledged for providing a stimulating scientific environment for the discussion of AFM-based nanomechanics of cells and soft matter.

Keywords

AFM
Focal adhesion
Mechanotransduction
Molecular clutch
PIP
Talin
UPAR

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title = "Lamellipodial tension, not integrin/ligand binding, is the crucial factor to realise integrin activation and cell migration",

abstract = "The molecular clutch (MC) model proposes that actomyosin-driven force transmission permits integrin-dependent cell migration. To investigate the MC, we introduced diverse talin (TLN) and integrin variants into Flp-In{\texttrademark} T-Rex{\texttrademark} HEK293 cells stably expressing uPAR. Vitronectin variants served as substrate providing uPAR-mediated cell adhesion and optionally integrin binding. This particular system allowed us to selectively analyse key MC proteins and interactions, effectively from the extracellular matrix substrate to intracellular f-actin, and to therewith study mechanobiological aspects of MC engagement also uncoupled from integrin/ligand binding. With this experimental approach, we found that for the initial PIP2-dependent membrane/TLN/f-actin linkage and persistent lamellipodia formation the C-terminal TLN actin binding site (ABS) is dispensable. The establishment of an adequate MC-mediated lamellipodial tension instead depends predominantly on the coupling of this C-terminal TLN ABS to the actomyosin-driven retrograde actin flow force. This lamellipodial tension is crucial for full integrin activation eventually determining integrin-dependent cell migration. In the integrin/ligand-independent condition the frictional membrane resistance participates to these processes. Integrin/ligand binding can also contribute but is not necessarily required.",

keywords = "AFM, Focal adhesion, Mechanotransduction, Molecular clutch, PIP, Talin, UPAR",

author = "Carsten Schulte and Ferraris, \{Gian Maria Sarra\} and Amanda Oldani and Massimiliano Galluzzi and Alessandro Podest{\`a} and Luca Puricelli and \{de Lorenzi\}, Valentina and Cristina Lenardi and Paolo Milani and Nicolai Sidenius",

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AU - Schulte, Carsten

AU - Ferraris, Gian Maria Sarra

AU - Oldani, Amanda

AU - Galluzzi, Massimiliano

AU - Podestà, Alessandro

AU - Puricelli, Luca

AU - de Lorenzi, Valentina

AU - Lenardi, Cristina

AU - Milani, Paolo

AU - Sidenius, Nicolai

PY - 2016/1/1

Y1 - 2016/1/1

N2 - The molecular clutch (MC) model proposes that actomyosin-driven force transmission permits integrin-dependent cell migration. To investigate the MC, we introduced diverse talin (TLN) and integrin variants into Flp-In™ T-Rex™ HEK293 cells stably expressing uPAR. Vitronectin variants served as substrate providing uPAR-mediated cell adhesion and optionally integrin binding. This particular system allowed us to selectively analyse key MC proteins and interactions, effectively from the extracellular matrix substrate to intracellular f-actin, and to therewith study mechanobiological aspects of MC engagement also uncoupled from integrin/ligand binding. With this experimental approach, we found that for the initial PIP2-dependent membrane/TLN/f-actin linkage and persistent lamellipodia formation the C-terminal TLN actin binding site (ABS) is dispensable. The establishment of an adequate MC-mediated lamellipodial tension instead depends predominantly on the coupling of this C-terminal TLN ABS to the actomyosin-driven retrograde actin flow force. This lamellipodial tension is crucial for full integrin activation eventually determining integrin-dependent cell migration. In the integrin/ligand-independent condition the frictional membrane resistance participates to these processes. Integrin/ligand binding can also contribute but is not necessarily required.

AB - The molecular clutch (MC) model proposes that actomyosin-driven force transmission permits integrin-dependent cell migration. To investigate the MC, we introduced diverse talin (TLN) and integrin variants into Flp-In™ T-Rex™ HEK293 cells stably expressing uPAR. Vitronectin variants served as substrate providing uPAR-mediated cell adhesion and optionally integrin binding. This particular system allowed us to selectively analyse key MC proteins and interactions, effectively from the extracellular matrix substrate to intracellular f-actin, and to therewith study mechanobiological aspects of MC engagement also uncoupled from integrin/ligand binding. With this experimental approach, we found that for the initial PIP2-dependent membrane/TLN/f-actin linkage and persistent lamellipodia formation the C-terminal TLN actin binding site (ABS) is dispensable. The establishment of an adequate MC-mediated lamellipodial tension instead depends predominantly on the coupling of this C-terminal TLN ABS to the actomyosin-driven retrograde actin flow force. This lamellipodial tension is crucial for full integrin activation eventually determining integrin-dependent cell migration. In the integrin/ligand-independent condition the frictional membrane resistance participates to these processes. Integrin/ligand binding can also contribute but is not necessarily required.

KW - AFM

KW - Focal adhesion

KW - Mechanotransduction

KW - Molecular clutch

KW - PIP

KW - Talin

KW - UPAR

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M3 - Article

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AN - SCOPUS:84983190345

SN - 0171-9335

VL - 95

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EP - 14

JO - European Journal of Cell Biology

JF - European Journal of Cell Biology

IS - 1

ER -

Lamellipodial tension, not integrin/ligand binding, is the crucial factor to realise integrin activation and cell migration

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