Unravelling the constrained cell growth in engineered living materials

Engineered living materials (ELMs) leverage the integrative advantages of materials science and synthetic biology for advanced functionalities. Predicting and controlling cellular behavior is essential for designing and building ELMs, requiring fundamental understanding of the growth dynamics of encapsulated cells. Here, we interrogate the interference of constrained growth on the engineered functionalities and cellular physiology of cyanobacteria and unveil the dynamic interaction between cell growth and spatial confinements within photosynthetic ELMs. We observed that engineered cyanobacteria within ELMs exhibited compromised performances in growth, uptake of non-natural substrate, and synthesis of customized products, while ELMs could protect encapsulated cells from external stresses. Besides commonly accepted external influences, we identified abnormally high levels of reactive oxygen species and impaired oxygenic photosynthesis inside the cells encapsulated in ELMs. Finally, we illustrated the dynamics of cell growth within the confined spaces enveloped by the material matrices, forming clustered cell aggregates and compressed growth bubbles until the spatial limits. Our study provides a fundamental yet often overlooked connection between cellular behavior and spatial confinements, consolidating the foundation for advanced ELM innovations.