Login / Signup

Combinatorial High-Throughput Screening of Complex Polymeric Enzyme Immobilization Supports.

Héctor Sánchez-MoránJoel L KaarDaniel K Schwartz
Published in: Journal of the American Chemical Society (2024)
Recent advances have demonstrated the promise of complex multicomponent polymeric supports to enable supra-biological enzyme performance. However, the discovery of such supports has been limited by time-consuming, low-throughput synthesis and screening. Here, we describe a novel combinatorial and high-throughput platform that enables rapid screening of complex and heterogeneous copolymer brushes as enzyme immobilization supports, named combinatorial high-throughput enzyme support screening (CHESS). Using a 384-well plate format, we synthesized arrays of three-component polymer brushes in the microwells using photoactivated surface-initiated polymerization and immobilized enzymes in situ. The utility of CHESS to identify optimal immobilization supports under thermally and chemically denaturing conditions was demonstrated using Bacillus subtilis Lipase A (LipA). The identification of supports with optimal compositions was validated by immobilizing LipA on polymer-brush-modified biocatalyst particles. We further demonstrated that CHESS could be used to predict the optimal composition of polymer brushes a priori for the previously unexplored enzyme, alkaline phosphatase (AlkP). Our findings demonstrate that CHESS represents a predictable and reliable platform for dramatically accelerating the search of chemical compositions for immobilization supports and further facilitates the discovery of biocompatible and stabilizing materials.
Keyphrases
  • high throughput
  • drug delivery
  • drug release
  • bacillus subtilis
  • single cell
  • small molecule
  • cancer therapy
  • machine learning
  • mass spectrometry
  • artificial intelligence
  • high density