Cellular Tensegrity: Exploring How Mechanical Changes in the Cytoskeleton Regulate Cell Growth, Migration, and Tissue Pattern during Morphogenesis

Abstract

Publisher Summary This chapter focuses on the role of the intracellular cytoskeleton (CSK) in cell shape determination and tissue morphogenesis. The role of mechanical changes in the CSK during embryological development is reviewed. The chapter focuses on the mechanism by which mechanical forces are transmitted across the cell surface and through the CSK, as well as how they regulate cell shape. An analysis of the biomechanical basis of cell shape control addresses two central questions: (1) how do changes in mechanical forces alter CSK organization, and (2) how do changes in CSK structure regulate cell growth and function. The results from recent studies showing that the CSK can respond directly to mechanical stress are also reviewed. The particular type of mechanical response that living cells exhibit is consistent with a theory of CSK architecture that is based on tensional integrity and is known as “tensegrity”. Inherent to the tensegrity model is an efficient mechanism for integrating changes in structure and function at the tissue, cell, nuclear, and molecular levels. The chapter explores the possibility that CSK tensegrity may also provide a mechanical basis for cell locomotion as well as a structural mechanism for coupling mechanical and chemical signaling pathways inside the cell.