Tuning non-linear mechanics in collagen hydrogels modulates three dimensional cellular morphotypes

Collagen networks contribute to tissue architecture and modulate cellular responses in crowded three-dimensional environments. Therefore, it is the most widely used biological polymer in three-dimensional studies of cellular interactions with the extracellular matrix. In-vivo, collagen exists embedded within additional matrix components. Studies have shown that the combination of matrices induces synergistic mechanical interactions, influencing the non-linear mechanical behaviour of collagen networks. However, how cells respond to changes in collagen non-linear elasticity remains largely unknown. By precisely controlling the mechanical behaviour of collagen networks with the biologically inert and semiflexible polymer polyisocyanopeptides, we demonstrate that changes in the non-linear elasticity of collagen induces morphological cell responses that influence how cells migrate, proliferate, and interact with collagen. We found that when collagen rigidifies in the presence of a second component, this induces morphological changes in cell-matrix interactions, resulting in a decrease in migration and the ability of cells to deform collagen matrices. Our results demonstrate that the onset of collagen stiffening is key to inducing intracellular tension which dictates morphological cell responses in three-dimensional collagen networks. We anticipate our findings will prove useful in understanding how cells respond to changes in collagen mechanics when combined in double network systems which better recapitulates tissues in-vivo. ### Competing Interest Statement The authors have declared no competing interest.