Rationalizing Diverse Binding Mechanisms to the Same Protein Fold: Insights for Ligand Recognition and Biosensor Design. Journal Article uri icon

Overview

abstract

  • The engineering of novel protein-ligand binding interactions, particularly for complex drug-like molecules, is an unsolved problem, which could enable many practical applications of protein biosensors. In this work, we analyzed two engineered biosensors, derived from the plant hormone sensor PYR1, to recognize either the agrochemical mandipropamid or the synthetic cannabinoid WIN55,212-2. Using a combination of quantitative deep mutational scanning experiments and molecular dynamics simulations, we demonstrated that mutations at common positions can promote protein-ligand shape complementarity and revealed prominent differences in the electrostatic networks needed to complement diverse ligands. MD simulations indicate that both PYR1 protein-ligand complexes bind a single conformer of their target ligand that is close to the lowest free-energy conformer. Computational design using a fixed conformer and rigid body orientation led to new WIN55,212-2 sensors with nanomolar limits of detection. This work reveals mechanisms by which the versatile PYR1 biosensor scaffold can bind diverse ligands. This work also provides computational methods to sample realistic ligand conformers and rigid body alignments that simplify the computational design of biosensors for novel ligands of interest.

publication date

  • August 16, 2024

has subject area

has restriction

  • closed

Date in CU Experts

  • July 24, 2024 3:49 AM

Full Author List

  • Leonard AC; Friedman AJ; Chayer R; Petersen BM; Woojuh J; Xing Z; Cutler SR; Kaar JL; Shirts MR; Whitehead TA

author count

  • 10

Other Profiles

Electronic International Standard Serial Number (EISSN)

  • 1554-8937

Additional Document Info

start page

  • 1757

end page

  • 1772

volume

  • 19

issue

  • 8