TY - JOUR
T1 - Cellular Contact Guidance Emerges from Gap Avoidance
AU - Buskermolen, A.B.C. (Gitta)
AU - Ristori, Tommaso
AU - Mostert, Dylan
AU - van Turnhout, Mark C.
AU - Shishvan, Siamak S.
AU - Loerakker, Sandra
AU - Kurniawan, Nicholas A.
AU - Deshpande, V.S.
AU - Bouten, Carlijn V.C.
PY - 2020/5/20
Y1 - 2020/5/20
N2 - In the presence of anisotropic biochemical or topographical patterns, cells tend to align in the direction of these cues—a widely reported phenomenon known as ‘‘contact guidance.’’ To investigate the origins of contact guidance, here, we created substrates micropatterned with parallel lines of fibronectin with dimensions spanning multiple orders of magnitude. Quantitative morphometric analysis of our experimental data reveals two regimes of contact guidance governed by the length scale of the cues that cannot be explained by enforced alignment of focal adhesions. Adopting computational simulations of cell remodeling on inhomogeneous substrates based on a statistical mechanics framework for living cells, we show that contact guidance emerges from anisotropic cell shape fluctuation and ‘‘gap avoidance,’’ i.e., the energetic penalty of cell adhesions on non-adhesive gaps. Our findings therefore point to general biophysical mechanisms underlying cellular contact guidance, without the necessity of invoking specific molecular pathways.
AB - In the presence of anisotropic biochemical or topographical patterns, cells tend to align in the direction of these cues—a widely reported phenomenon known as ‘‘contact guidance.’’ To investigate the origins of contact guidance, here, we created substrates micropatterned with parallel lines of fibronectin with dimensions spanning multiple orders of magnitude. Quantitative morphometric analysis of our experimental data reveals two regimes of contact guidance governed by the length scale of the cues that cannot be explained by enforced alignment of focal adhesions. Adopting computational simulations of cell remodeling on inhomogeneous substrates based on a statistical mechanics framework for living cells, we show that contact guidance emerges from anisotropic cell shape fluctuation and ‘‘gap avoidance,’’ i.e., the energetic penalty of cell adhesions on non-adhesive gaps. Our findings therefore point to general biophysical mechanisms underlying cellular contact guidance, without the necessity of invoking specific molecular pathways.
KW - cell adhesion
KW - cell alignment
KW - cell organization
KW - contact guidance
KW - focal adhesion
KW - microcontact printing
KW - protein patterning
KW - statistical mechanics
KW - stress fibers
KW - substrate anisotropy
UR - http://www.scopus.com/inward/record.url?scp=85087950069&partnerID=8YFLogxK
U2 - 10.1016/j.xcrp.2020.100055
DO - 10.1016/j.xcrp.2020.100055
M3 - Article
C2 - 32685934
SN - 2666-3864
VL - 1
JO - Cell Reports. Physical Science
JF - Cell Reports. Physical Science
IS - 5
M1 - 100055
ER -