An active machine learning discovery platform for membrane-disrupting and pore-forming peptides

Alexander van Teijlingen, Dan Edwards, Liao Hu, Annamaria Lilienkampf, Scott L Cockroft, Tell Tuttle*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract / Description of output

Membrane-disrupting and pore-forming peptides (PFPs) play a substantial role in bionanotechnology and can determine the life and death of cells. The control of chemical and ion transport through cell membranes is essential to maintaining concentration gradients. Likewise, the delivery of drugs and intracellular proteins aided by pore-forming agents are of interest in treating malfunctioning cells. Known PFPs tend to be up to 50 residues in length, which is commensurate with the thickness of a lipid bilayer. Accordingly, few short PFPs are known. Here we show that the discovery of PFPs can be accelerated via an active machine learning approach. The approach identified 71 potential PFPs from the 25.6 billion octapeptide sequence space; 13 sequences were tested experimentally, and all were found to have the predicted membrane-disrupting ability, with 1 forming highly stable pores. Experimental verification of the predicted pore-forming ability demonstrated that a range of short peptides can form pores in membranes, while the positioning and characteristics of residues that favour pore-forming behaviour were identified. This approach identified more ultrashort (8-residues, unmodified, non-cyclic) PFPs than previously known. We anticipate our findings and methodology will be useful in discovering new pore-forming and membrane-disrupting peptides for range of applications from nanoreactors to therapeutics.
Original languageEnglish
JournalPhysical Chemistry Chemical Physics
Early online date30 May 2024
DOIs
Publication statusE-pub ahead of print - 30 May 2024

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