Communications Biology (Apr 2023)

Proteomic data and structure analysis combined reveal interplay of structural rigidity and flexibility on selectivity of cysteine cathepsins

  • Livija Tušar,
  • Jure Loboda,
  • Francis Impens,
  • Piotr Sosnowski,
  • Emmy Van Quickelberghe,
  • Robert Vidmar,
  • Hans Demol,
  • Koen Sedeyn,
  • Xavier Saelens,
  • Matej Vizovišek,
  • Marko Mihelič,
  • Marko Fonović,
  • Jaka Horvat,
  • Gregor Kosec,
  • Boris Turk,
  • Kris Gevaert,
  • Dušan Turk

DOI
https://doi.org/10.1038/s42003-023-04772-8
Journal volume & issue
Vol. 6, no. 1
pp. 1 – 15

Abstract

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Abstract Addressing the elusive specificity of cysteine cathepsins, which in contrast to caspases and trypsin-like proteases lack strict specificity determining P1 pocket, calls for innovative approaches. Proteomic analysis of cell lysates with human cathepsins K, V, B, L, S, and F identified 30,000 cleavage sites, which we analyzed by software platform SAPS-ESI (Statistical Approach to Peptidyl Substrate-Enzyme Specific Interactions). SAPS-ESI is used to generate clusters and training sets for support vector machine learning. Cleavage site predictions on the SARS-CoV-2 S protein, confirmed experimentally, expose the most probable first cut under physiological conditions and suggested furin-like behavior of cathepsins. Crystal structure analysis of representative peptides in complex with cathepsin V reveals rigid and flexible sites consistent with analysis of proteomics data by SAPS-ESI that correspond to positions with heterogeneous and homogeneous distribution of residues. Thereby support for design of selective cleavable linkers of drug conjugates and drug discovery studies is provided.