Cell shape can mediate the spatial organization of the bacterial cytoskeleton. Author Siyuan Wang, Ned Wingreen Publication Year 2013 Type Journal Article Abstract The bacterial cytoskeleton guides the synthesis of cell wall and thus regulates cell shape. Because spatial patterning of the bacterial cytoskeleton is critical to the proper control of cell shape, it is important to ask how the cytoskeleton spatially self-organizes in the first place. In this work, we develop a quantitative model to account for the various spatial patterns adopted by bacterial cytoskeletal proteins, especially the orientation and length of cytoskeletal filaments such as FtsZ and MreB in rod-shaped cells. We show that the combined mechanical energy of membrane bending, membrane pinning, and filament bending of a membrane-attached cytoskeletal filament can be sufficient to prescribe orientation, e.g., circumferential for FtsZ or helical for MreB, with the accuracy of orientation increasing with the length of the cytoskeletal filament. Moreover, the mechanical energy can compete with the chemical energy of cytoskeletal polymerization to regulate filament length. Notably, we predict a conformational transition with increasing polymer length from smoothly curved to end-bent polymers. Finally, the mechanical energy also results in a mutual attraction among polymers on the same membrane, which could facilitate tight polymer spacing or bundling. The predictions of the model can be verified through genetic, microscopic, and microfluidic approaches. Keywords Cytoskeletal Proteins, Protein Binding, Bacterial Proteins, Protein Conformation, Kinetics, Models, Chemical, Bacteria, Cytoskeleton, Cell Membrane, Protein Multimerization Journal Biophys J Volume 104 Issue 3 Pages 541-52 Date Published 02/2013 Alternate Journal Biophys. J. Google ScholarBibTeXEndNote X3 XML