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SuFEx Chemistry Enables Covalent Assembly of a 280-kDa 18-Subunit Pore-Forming Complex.

Lee SchnaiderSophia K TanPratik R SinghFloriana CapuanoAlistair J ScottRichard HambleyLei LuHyunjun YangE Jayne WallaceHyunil JoWilliam F DeGrado
Published in: Journal of the American Chemical Society (2024)
Proximity-enhanced chemical cross-linking is an invaluable tool for probing protein-protein interactions and enhancing the potency of potential peptide and protein drugs. Here, we extend this approach to covalently stabilize large macromolecular assemblies. We used SuFEx chemistry to covalently stabilize an 18-subunit pore-forming complex, CsgG:CsgF, consisting of nine CsgG membrane protein subunits that noncovalently associate with nine CsgF peptides. Derivatives of the CsgG:CsgF pore have been used for DNA sequencing, which places high demands on the structural stability and homogeneity of the complex. To increase the robustness of the pore, we designed and synthesized derivatives of CsgF-bearing sulfonyl fluorides, which react with CsgG in very high yield to form a covalently stabilized CsgG:CsgF complex. The resulting pores formed highly homogeneous channels when added to artificial membranes. The high yield and rapid reaction rate of the SuFEx reaction prompted molecular dynamics simulations, which revealed that the SO 2 F groups in the initially formed complex are poised for nucleophilic reaction with a targeted Tyr. These results demonstrate the utility of SuFEx chemistry to structurally stabilize very large (here, 280 kDa) assemblies.
Keyphrases
  • molecular dynamics simulations
  • single molecule
  • single cell
  • heat shock protein
  • drug discovery
  • amino acid
  • cancer therapy
  • drug delivery
  • climate change
  • quantum dots
  • resting state
  • functional connectivity
  • nucleic acid