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In Vitro Encapsulation of Functionally Active Abiotic Photosensitizers Inside a Bacterial Microcompartment Shell.

Samuel N SnyderAlexander JussupowMichael F FeigAndrea M PotocnyMarkus SutterCheryl A KerfeldKaren L MulfortLisa M Utschig
Published in: The journal of physical chemistry letters (2024)
Bacterial microcompartments (BMCs) are self-assembling, selectively permeable protein shells that encapsulate enzymes to enhance catalytic efficiency of segments of metabolic pathways through means of confinement. The modular nature of BMC shells' structure and assembly enables programming of shell permeability and underscores their promise in biotechnology engineering efforts for applications in industry, medicine, and clean energy. Realizing this potential requires methods for encapsulation of abiotic molecules, which have been developed here for the first time. We report in vitro cargo loading of BMC shells with ruthenium photosensitizers (RuPS) by two approaches─one involving site-specific covalent labeling and the other driven by diffusion, requiring no specific interactions between cargo molecules and shell proteins. The highly stable shells retain encapsulated cargo over 1 week without egress and preserve RuPS photophysical activity. This study is an important foundation for further work that will converge biological BMC architecture with synthetic chemistry to facilitate biohybrid photocatalysis.
Keyphrases
  • photodynamic therapy
  • clinical trial
  • arabidopsis thaliana
  • randomized controlled trial
  • genome wide identification
  • risk assessment
  • big data
  • human health
  • placebo controlled
  • genome wide analysis