RT Journal Article
SR Electronic
T1 An exploratory study on the role of the stiffness of breast cancer cells in their detachment from spheroids and migration in 3D collagen matrices
JF bioRxiv
FD Cold Spring Harbor Laboratory
SP 2021.01.21.427639
DO 10.1101/2021.01.21.427639
A1 Ghodeejah Higgins
A1 Jessica E. Kim
A1 Jacopo Ferruzzi
A1 Tamer Abdalrahman
A1 Thomas Franz
A1 Muhammad H. Zaman
YR 2022
UL http://biorxiv.org/content/early/2022/04/16/2021.01.21.427639.abstract
AB Background Tumour-cell detachment is a critical early event in the metastatic cascade. However, the role of the cell’s mechanical properties in detachment and migration is not well understood. This exploratory study aimed to assess how intracellular stiffness changes these processes.Methods MDA-MB-231 cells were embedded as 10,000-cell spheroids in 2 and 4 mg/ml collagen matrices. Intracellular stiffness was assessed with mitochondria tracking microrheology of cells that migrated distances equivalent to four and six times the cell diameter (dC) from the spheroid and compared to cells at the spheroid surface (0dC), representing medium, high and no migration, respectively.Results and discussion The mitochondrial mean square displacement and intracellular stiffness decreased during detachment and migration for both collagen concentrations (i.e. rigidities). The mean square displacement of 4dC and 6dC cells was similar, whereas cell stiffness was lower for 4dC than for 6dC cells. With increasing matrix rigidity, the intracellular stiffness decreased for 0dC cells and did not change for 4dC and 6dC cells. It is proposed that decreased cell stiffness drives detachment and migration and increased matrix rigidity physically hinders migration, and cells need to become softer or remodel the environment to migrate. The independence of the stiffness of migrated cells from matrix rigidity suggests that cells remodel their environment through matrix proteins cleavage to migrate.Conclusions The study revealed the collective effects of enhanced migratory conditions and increased matrix rigidity on the mechanical properties of the cells. The expression of matrix metalloproteinases and transforming growth factor β and the role of cell volume on detachment and migration in matrices with varying pore sizes are proposed targets for further studies on metastatic cancer cells.Competing Interest StatementThe authors have declared no competing interest.