Nature Communications (Aug 2024)

Hydrogen sulfide coordinates glucose metabolism switch through destabilizing tetrameric pyruvate kinase M2

  • Rong-Hsuan Wang,
  • Pin-Ru Chen,
  • Yue-Ting Chen,
  • Yi-Chang Chen,
  • Yu-Hsin Chu,
  • Chia-Chen Chien,
  • Po-Chen Chien,
  • Shao-Yun Lo,
  • Zhong-Liang Wang,
  • Min-Chen Tsou,
  • Ssu-Yu Chen,
  • Guang-Shen Chiu,
  • Wen-Ling Chen,
  • Yi-Hsuan Wu,
  • Lily Hui-Ching Wang,
  • Wen-Ching Wang,
  • Shu-Yi Lin,
  • Hsing-Jien Kung,
  • Lu-Hai Wang,
  • Hui-Chun Cheng,
  • Kai-Ti Lin

DOI
https://doi.org/10.1038/s41467-024-51875-9
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 18

Abstract

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Abstract Most cancer cells reprogram their glucose metabolic pathway from oxidative phosphorylation to aerobic glycolysis for energy production. By reducing enzyme activity of pyruvate kinase M2 (PKM2), cancer cells attain a greater fraction of glycolytic metabolites for macromolecule synthesis needed for rapid proliferation. Here we demonstrate that hydrogen sulfide (H2S) destabilizes the PKM2 tetramer into monomer/dimer through sulfhydration at cysteines, notably at C326, leading to reduced PKM2 enzyme activity and increased PKM2-mediated transcriptional activation. Blocking PKM2 sulfhydration at C326 through amino acid mutation stabilizes the PKM2 tetramer and crystal structure further revealing the tetramer organization of PKM2-C326S. The PKM2-C326S mutant in cancer cells rewires glucose metabolism to mitochondrial respiration, significantly inhibiting tumor growth. In this work, we demonstrate that PKM2 sulfhydration by H2S inactivates PKM2 activity to promote tumorigenesis and inhibiting this process could be a potential therapeutic approach for targeting cancer metabolism.