Plasmodium falciparum HSP90 inhibitors show divergent resistance despite a shared ATP-binding site.

  • Journal Article

Journal:
Cell reports, Volume: 45, Issue: 7
Published:
July 5, 2026
PMID:
42406593
Authors:
Fu-Hsuan Ko FH, Amanda K Lukens AK, Mariana Laureano de Souza M, Alex Foy A, Jason Hsiao J, Tolla Ndiaye T, John Okombo J, Tomas Yeo T, Heekuk Park H, Anne-Catrin Uhlemann AC, Nonlawat Boonyalai N, Krittikorn Kumpornsin K, Gareth Girling G, Charisse Pasaje C, Luiz Godoy L, Priyan Kapoor P, Gregory L Durst GL, Sabine Ottilie S, Arnab Chatterjee A, Jacquin Niles J, Marcus Lee M, David A Fidock DA, Dyann F Wirth DF, Elizabeth A Winzeler EA
Abstract:

Drug resistance poses a major challenge across therapeutic areas including malaria, yet factors governing resistance propensity remain poorly understood. We demonstrate that two HSP90 inhibitors targeting the identical ATP-binding site exhibit dramatically different resistance profiles in P. falciparum. Geldanamycin readily selected 10 distinct resistance mutations conferring up to 22-fold resistance, while AUY-922 required 44 weeks to yield a single A41S mutation with only 2-fold resistance. Resistance mutations mapped throughout geldanamycin’s binding pocket but localized near the ATP-binding site for AUY-922. Strikingly, A41S enhanced AUY-922 binding affinity via additional hydrogen bonding, yet stronger binding paradoxically correlated with resistance. Conditional HSP90 knockdown increased geldanamycin sensitivity but not AUY-922 activity, indicating distinct target dependencies despite shared binding sites. We propose AUY-922’s lower resistance risk reflects engagement of multiple HSP90 family members. These findings demonstrate that resistance risk cannot be predicted from binding site identity alone, informing development of more durable therapeutics.


Courtesy of the U.S. National Library of Medicine