Cytoskeletal symmetry breaking in animal cells

Symmetry breaking is a crucial step in structure formation and function of all cells, necessary for cell movement, cell division, and polarity establishment. Although the mechanisms of symmetry breaking are diverse, they often share common characteristics. Here we review examples of nematic, polar, and chiral cytoskeletal symmetry breaking in animal cells, and analogous processes in simplified reconstituted systems. We discuss the origins of symmetry breaking, which can arise spontaneously, or involve amplification of a pre-existing external or internal bias to the whole cell level. The underlying mechanisms often involve both chemical and mechanical processes that cooperate to break symmetry in a robust manner, and typically depend on the shape, size, or properties of the cell's boundary.

Automated summary

Symmetry breaking is crucial for the formation of cell structure and function, enabling cell movement, division, and polarity establishment. The mechanisms of symmetry breaking, while diverse, often share common characteristics like nematic, polar, and chiral cytoskeletal symmetry breaking in animal cells. These mechanisms involve both chemical and mechanical processes that cooperate to break symmetry in a robust manner.