From microbial biofilm communities to multicellular organisms, 3D macroscopic structures develop through poorly understood interplay between cellular processes and mechanical forces. Investigating wrinkled biofilms of Bacillus subtilis, we discovered a pattern of localized cell death that spatially focuses mechanical forces, and thereby initiates wrinkle formation. Deletion of genes implicated in biofilm development, together with mathematical modeling, revealed that ECM production underlies the localization of cell death. Simultaneously with cell death, we quantitatively measured mechanical stiffness and movement in WT and mutant biofilms. Results suggest that localized cell death provides an outlet for lateral compressive forces, thereby promoting vertical mechanical buckling, which subsequently leads to wrinkle formation. Guided by these findings, we were able to generate artificial wrinkle patterns within biofilms. Formation of 3D structures facilitated by cell death may underlie self-organization in other developmental systems, and could enable engineering of macroscopic structures from cell populations.pattern formation | self-assembly | systems dynamics S elf-organization in space and time is a fundamental developmental process, defined by the autonomous formation of 3D macroscopic structures by replicating cell populations (1-3). Such 3D pattern formation underlies the development of all multicellular organisms and cellular communities, and appears to be governed by two principal processes. First, genetic programs control cellular processes, such as growth, death, and differentiation. Second, 3D structure formation involves macroscopic movement of cell populations that are determined by mechanical properties and physical forces (4). Recent studies have investigated each of these processes separately in different biological systems (5-8). However, insight into the direct interplay between cellular and mechanical processes that drives development requires simultaneous measurement of both processes, and thus constitutes a major challenge.Compared with multicellular organisms, microbial biofilms are simpler systems for investigating the interaction between cellular and mechanical aspects of 3D self-organization during development. Interestingly, these microbial communities still exhibit diverse cellular behaviors and complex spatial organization (9-14). For example, biofilms can develop from a single cell and give rise to complex 3D wrinkle structures that are visible to the naked eye, comprising billions of cells (9, 10, 15) (Fig. 1A). Aside from replication, bacterial cells can also exhibit other behaviors, such as genetically controlled cell death (9,16,17) and excretion of ECM components (9,13,(18)(19)(20)(21). In fact, one of the defining features of any biofilm is that cells are embedded within an ECM composed of diverse molecules, such as polysaccharides and amyloid fibers (19-21). The ECM is required for wrinkle formation and appears to provide the biofilm with resilience against environmental extrem...
