TY - JOUR
T1 - Molecular basis of JAK2 activation in erythropoietin receptor and pathogenic JAK2 signaling
AU - Abraham, Bobin George
AU - Haikarainen, Teemu
AU - Vuorio, Joni
AU - Girych, Mykhailo
AU - Virtanen, Anniina T.
AU - Kurttila, Antti
AU - Karathanasis, Christos
AU - Heilemann, Mike
AU - Sharma, Vivek
AU - Vattulainen, Ilpo
AU - Silvennoinen, Olli
N1 - Publisher Copyright:
copyright © 2024 the Authors,
PY - 2024/3
Y1 - 2024/3
N2 - Janus kinase 2 (JAK2) mediates type I/II cytokine receptor signaling, but JAK2 is also activated by somatic mutations that cause hematological malignancies by mechanisms that are still incompletely understood. Quantitative superresolution microscopy (qSMLM) showed that erythropoietin receptor (EpoR) exists as monomers and dimer-izes upon Epo stimulation or through the predominant JAK2 pseudokinase domain mutations (V617F, K539L, and R683S). Crystallographic analysis complemented by kinase activity analysis and atomic-level simulations revealed distinct pseudokinase dimer interfaces and activation mechanisms for the mutants: JAK V617F activity is driven by dimerization, K539L involves both increased receptor dimerization and kinase activity, and R683S prevents autoinhibition and increases catalytic activity and drives JAK2 equilibrium toward activation state through a wild-type dimer interface. Artificial intelligence–guided modeling and simulations revealed that the pseudokinase mutations cause differences in the pathogenic full-length JAK2 dimers, particularly in the FERM-SH2 domains. A detailed molecular understanding of mutation-driven JAK2 hyperactivation may enable novel therapeutic approaches to selectively target pathogenic JAK2 signaling.
AB - Janus kinase 2 (JAK2) mediates type I/II cytokine receptor signaling, but JAK2 is also activated by somatic mutations that cause hematological malignancies by mechanisms that are still incompletely understood. Quantitative superresolution microscopy (qSMLM) showed that erythropoietin receptor (EpoR) exists as monomers and dimer-izes upon Epo stimulation or through the predominant JAK2 pseudokinase domain mutations (V617F, K539L, and R683S). Crystallographic analysis complemented by kinase activity analysis and atomic-level simulations revealed distinct pseudokinase dimer interfaces and activation mechanisms for the mutants: JAK V617F activity is driven by dimerization, K539L involves both increased receptor dimerization and kinase activity, and R683S prevents autoinhibition and increases catalytic activity and drives JAK2 equilibrium toward activation state through a wild-type dimer interface. Artificial intelligence–guided modeling and simulations revealed that the pseudokinase mutations cause differences in the pathogenic full-length JAK2 dimers, particularly in the FERM-SH2 domains. A detailed molecular understanding of mutation-driven JAK2 hyperactivation may enable novel therapeutic approaches to selectively target pathogenic JAK2 signaling.
U2 - 10.1126/sciadv.adl2097
DO - 10.1126/sciadv.adl2097
M3 - Article
C2 - 38457493
AN - SCOPUS:85187492510
SN - 2375-2548
VL - 10
JO - Science Advances
JF - Science Advances
IS - 10
M1 - eadl2097
ER -