Mechanical strain modulates Min patterning and division in E. coli filaments

Bacteria often encounter physico-chemical stresses that disrupt division, leading to filamentation, where cells elongate without dividing. While this adaptive response enhances survival, it also exposes filaments to significant mechanical strain, raising questions about the mechanochemical feedback in bacterial systems. In this study, we investigate how mechanical strain influences the Min oscillatory system, a reaction-diffusion network central to division in Escherichia coli . Through a multidisciplinary approach combining quantitative fluorescence microscopy, biophysical modeling, microfluidics, and patterned growth substrates, we demonstrate that filamentous E. coli undergoes growth-induced buckling instability. This phenomenon alters the diffusivity of membrane proteins and modulates the spatiotemporal patterning of the Min system. Moreover, we show that this mechanochemical interplay determines division site positioning after stress relief, effectively creating a mechanical “memory” for cytokinesis. Our findings underscore the critical role of mechanical forces in bacterial filamentation and provide new insights into the functional implications of mechanobiology in microbial systems.