Cellular synthesis of protein pretzelanes

Topology has been recognized as a unique dimension in molecular engineering, yet the topological diversity remains largely untapped, especially in macromolecules. Herein, we report the molecular design, cellular synthesis, and detailed characterization of protein pretzelanes with a chemical topology of a bridged Hopf link. The synergy between the intramolecular chain entwining guided by the p53dim (X) domains and the genetically encoded side-chain coupling by SpyTag(A)-SpyCatcher(B) reaction facilitates the direct synthesis of the model protein pretzelane BXA-BXA in Escherichia coli. The approach tolerates the insertion of various proteins-of interest, such as elastin-like protein (ELP), superfolder green fluorescent protein (GFP) and dihydrofolate reductase (DHFR), at the bridge region between two rings, giving rise to three protein pretzelanes BXA-ELP-BXA, BXA-GFP-BXA, and BXA-DHFR-BXA. Their topology has been verified by combined techniques of MALDI-TOF mass spectrometry, ion mobility-mass spectrometry, site-specific mutation, and orthogonal proteolytic digestion experiments. Not only are the fluorescent properties of GFP and the catalytic properties of DHFR fully retained, the pretzelane topology also renders BXA-DHFR-BXA more thermally resilient than the wild-type DHFR. These results expand the topological diversity of proteins and demonstrate protein stabilization as a potential functional benefit for the pretzelane topology.

Automated summary

This study presents the molecular design, synthesis, and characterization of protein pretzelanes with a chemical topology of a bridged Hopf link. By utilizing intramolecular chain entwining and genetically encoded side-chain coupling reactions, the model protein pretzelane was directly synthesized in Escherichia coli. Various proteins of interest were successfully inserted at the bridge region, resulting in diverse protein pretzelanes. The topological structure was verified using several techniques, and the results showed that the pretzelane topology not only retained the functional properties of the inserted proteins but also improved thermal resilience.