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Cysteine Alkylation in Enzymes and Transcription Factors: A Therapeutic Strategy for Cancer

Celia María Curieses Andrés, Fernando Lobo, José Manuel Pérez de la Lastra, Elena Bustamante Munguira, Celia Andrés, Eduardo Pérez‐Lebeña

2025Cancers7 citationsDOIOpen Access PDF

Abstract

Metabolic enzymes and cancer-driving transcriptions factors are often overexpressed in neoplastic cells, and their exposed cysteine residues are amenable to chemical modification. This review explores cysteine alkylation as a cancer treatment strategy, focusing on Michael acceptors like curcumin and helenalin, which interact with transcription factors NF-κB, STAT3 and HIF-1α. Molecular docking studies using AutoDockFR revealed distinct binding affinities: curcumin showed strong interactions with STAT3 and NF-κB, while helenalin exhibited high affinity for STAT3 and HIF-1α. Synthetic compounds like STAT3-IN-1 and CDDO-Me demonstrated superior binding in most targets, except for CDDO-Me with HIF-1α, suggesting unique structural incompatibilities. Natural products such as zerumbone and umbelliferone displayed moderate activity, while palbociclib highlighted synthetic-drug advantages. These results underscore the importance of ligand-receptor structural complementarity, particularly for HIF-1α's confined binding site, where helenalin's terminal Michael acceptor system proved optimal. The findings advocate for integrating computational and experimental approaches to develop cysteine-targeted therapies, balancing synthetic precision with natural product versatility for context-dependent cancer treatment strategies.

Topics & Concepts

CysteineChemistryCurcuminDocking (animal)Natural productTranscription factorBiochemistryComputational biologyEnzymeCancer researchBiologyMedicineGeneNursingCancer-related Molecular PathwaysSynthesis and biological activityCancer therapeutics and mechanisms
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