Synthetic biology in biofilms: Tools, challenges, and opportunities
Abstract
The field of synthetic biology seeks to program living cells to perform novel functions with applications ranging from environmental biosensing to smart cell‐based therapeutics. Bacteria are an especially attractive chassis organism due to their rapid growth, ease of genetic manipulation, and ability to persist across many environmental niches. Despite significant progress in bacterial synthetic biology, programming bacteria to perform novel functions outside the well‐controlled laboratory context remains challenging. In contrast to planktonic laboratory growth, bacteria in nature predominately reside in the context of densely packed communities known as biofilms. While biofilms have historically been considered environmental and biomedical hazards, their physiology and emergent behaviors could be leveraged for synthetic biology to engineer more capable and robust bacteria. Specifically, bacteria within biofilms participate in complex emergent behaviors such as collective organization, cell‐to‐cell signaling, and division of labor. Understanding and utilizing these properties can enable the effective deployment of engineered bacteria into natural target environments. Toward this goal, this review summarizes the current state of synthetic biology in biofilms by highlighting new molecular tools and remaining biological challenges. Looking to future opportunities, advancing synthetic biology in biofilms will enable the next generation of smart cell‐based technologies for use in medicine, biomanufacturing, and environmental remediation.
Document Details
- Document Type
- Pub Defense Publication
- Publication Date
- Jan 22, 2021
- Source ID
- 10.1002/btpr.3123
Entities
People
- Arthur Prindle
- Peter Tran
Organizations
- Army Research Office
- Burroughs Wellcome Fund
- David and Lucile Packard Foundation
- Northwestern University
- The Pew Charitable Trusts