Engineering Bacillus subtilis for the formation of a durable living biocomposite material

Engineered living materials (ELMs) are a fast-growing area of research that combine approaches in synthetic biology and material science. Here, we engineer B. subtilis to become a living component of a silica material composed of self-assembling protein scaffolds for functionalization and cross-linking of cells. B. subtilis is engineered to display SpyTags on polar flagella for cell attachment to SpyCatcher modified secreted scaffolds. We engineer endospore limited B. subtilis cells to become a structural component of the material with spores for long-term storage of genetic programming. Silica biomineralization peptides are screened and scaffolds designed for silica polymerization to fabricate biocomposite materials with enhanced mechanical properties. We show that the resulting ELM can be regenerated from a piece of cell containing silica material and that new functions can be incorporated by co-cultivation of engineered B. subtilis strains. We believe that this work will serve as a framework for the future design of resilient ELMs. Despite the advances in engineered living materials (ELMs), the diversity of ELMs especially those that are capable of autonomous self-fabrication and regeneration, is low. Here, the authors engineer a resilient ELM biocomposite using Bacillus subtilis and secreted EutM proteins as selfassembling scaffold building blocks.

Automated summary

Engineered living materials (ELMs) are a rapidly growing research area that combines synthetic biology and material science methods. Researchers have engineered a resilient ELM biocomposite using Bacillus subtilis and secreted EutM proteins as self-assembling scaffold building blocks.