Proliferating cells need to cope with extensive cytoskeletal and nuclear remodeling as they prepare to divide. These events are tightly regulated by the nuclear translocation of the cyclin B1-CDK1 complex, that is partly dependent on nuclear tension. Standard experimental approaches do not allow the manipulation of forces acting on cells in a time-resolved manner. Here, we describe a protocol that enables dynamic mechanical manipulation of single cells with high spatial and temporal resolution and its application in the context of cell division. In addition, we also outline a method for the manipulation of substrate stiffness using polyacrylamide hydrogels. Finally, we describe a static cell confinement setup, which can be used to study the impact of prolonged mechanical stimulation in populations of cells.
Key features
• Protocol for microfabrication of confinement devices.
• Single-cell dynamic confinement coupled with high-resolution microscopy.
• Static cell confinement protocol that can be combined with super-resolution STED microscopy.
• Analysis of the mechanical control of mitotic entry in a time-resolved manner.
Graphical overview