Jarod Rutledge scite author profile

A notable challenge for the design of engineered living materials (ELMs) is programming a cellular system to assimilate resources from its surroundings and convert them into macroscopic materials with specific functions. Here, an ELM that uses Escherichia coli as its cellular chassis and engineered curli nanofibers as its extracellular matrix component is demonstrated. Cell‐laden hydrogels are created by concentrating curli‐producing cultures. The rheological properties of the living hydrogels are modulated by genetically encoded factors and processing steps. The hydrogels have the ability to grow and self‐renew when placed under conditions that facilitate cell growth. Genetic programming enables the gels to be customized to interact with different tissues of the gastrointestinal tract selectively. This work lays a foundation for the application of ELMs with therapeutic functions and extended residence times in the gut.

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Programmable microbial ink for 3D printing of living materials produced from genetically engineered protein nanofibers

Duraj-Thatte

Manjula-Basavanna

Rutledge

et al. 2021

Nat Commun

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Living cells have the capability to synthesize molecular components and precisely assemble them from the nanoscale to build macroscopic living functional architectures under ambient conditions. The emerging field of living materials has leveraged microbial engineering to produce materials for various applications but building 3D structures in arbitrary patterns and shapes has been a major challenge. Here we set out to develop a bioink, termed as “microbial ink” that is produced entirely from genetically engineered microbial cells, programmed to perform a bottom-up, hierarchical self-assembly of protein monomers into nanofibers, and further into nanofiber networks that comprise extrudable hydrogels. We further demonstrate the 3D printing of functional living materials by embedding programmed Escherichia coli (E. coli) cells and nanofibers into microbial ink, which can sequester toxic moieties, release biologics, and regulate its own cell growth through the chemical induction of rationally designed genetic circuits. In this work, we present the advanced capabilities of nanobiotechnology and living materials technology to 3D-print functional living architectures.

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Cerebrospinal fluid immune dysregulation during healthy brain aging and cognitive impairment

Piehl¹,

Olst²,

Ramakrishnan³

et al. 2022

Cell

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Jarod Rutledge

Measuring biological age using omics data

Genetically Programmable Self‐Regenerating Bacterial Hydrogels

Programmable microbial ink for 3D printing of living materials produced from genetically engineered protein nanofibers

Cerebrospinal fluid immune dysregulation during healthy brain aging and cognitive impairment

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