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Can Cysteine Protease Cross-Class Inhibitors Achieve Selectivity?

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Covalent inhibitors targeting cysteine proteases offer therapeutic potential but face selectivity challenges. This perspective explores strategies for designing selective inhibitors, considering both reversible and irreversible covalent modifications for various cysteine proteases.

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Area of Science:

  • Biochemistry
  • Medicinal Chemistry
  • Drug Discovery

Background:

  • Cysteine proteases are crucial therapeutic targets for diverse diseases, including parasitic infections and cancer.
  • These enzymes share a common mechanism involving an encounter complex and nucleophilic attack by a catalytic cysteine residue.
  • Modulating cysteine protease activity often involves covalent modification, presenting challenges in achieving selectivity and avoiding off-target effects.

Purpose of the Study:

  • To explore strategies for achieving selectivity in small molecule inhibitors targeting cysteine proteases.
  • To evaluate the potential of reversible versus irreversible covalent inhibitors in mitigating off-target effects.
  • To discuss target- and ligand-based design approaches for cysteine protease inhibitors, including repurposing strategies.

Main Methods:

  • Review of existing literature on cysteine protease inhibitors and their mechanisms of action.
  • Analysis of target- and ligand-based drug design principles.
  • Discussion of structure-activity relationships for inhibitors targeting cathepsins, cruzain, rhodesain, and falcipain-2.

Main Results:

  • Covalent modification is a preferred method for modulating cysteine protease activity.
  • Achieving selectivity remains a significant challenge due to the conserved catalytic mechanisms.
  • Both reversible and irreversible covalent inhibitors present distinct advantages and disadvantages regarding selectivity and off-target effects.

Conclusions:

  • Designing selective cysteine protease inhibitors requires careful consideration of the target enzyme's active site and the inhibitor's chemical properties.
  • Repurposing inhibitors across different cysteine proteases is a viable strategy, but requires thorough validation.
  • Further research into novel design strategies is needed to overcome selectivity challenges and develop safer, more effective therapeutics.