<p>While ferroptosis induction offers promising avenue for cancer therapeutics, its clinical utility in colorectal cancer (CRC) is limited by pervasive intrinsic resistance mechanisms. Here, we identify Aurora kinase A (AURKA) as a central suppressor of ferroptosis by rewiring cholesterol metabolism. Mechanistically, AURKA phosphorylates and destabilizes its negative regulator SAPS3 at Ser523/524, relieving AMPK suppression. Activated AMPK subsequently inhibits SREBP2 nuclear translocation and DHCR7 transcription, resulting in the accumulation of 7-dehydrocholesterol (7-DHC), a lipid antioxidant that confers ferroptosis resistance. Both genetic and pharmacologic inhibition of AURKA restore ferroptosis sensitivity and enhance chemotherapy efficacy in vitro and in patient-derived xenograft models. Clinically, elevated AURKA expression correlates with poor prognosis and reduced chemotherapy response in CRC patients. These findings delineate a novel AURKA-SAPS3-AMPK-SREBP2 axis that bridges cholesterol homeostasis and ferroptosis evasion, positioning AURKA as a promising therapeutic target for chemosensitization in CRC.</p><p></p>

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AURKA-mediated destabilization of SAPS3 drives ferroptosis evasion via 7-dehydrocholesterol biosynthesis in colorectal cancer

  • Jialing Gao,
  • Weijing Zhang,
  • Lulu Chen,
  • Ruihan Pu,
  • Shaoqing Huang,
  • Xiaoxue Wu,
  • Zhenshuang Du,
  • Weiling He,
  • Mei Song

摘要

While ferroptosis induction offers promising avenue for cancer therapeutics, its clinical utility in colorectal cancer (CRC) is limited by pervasive intrinsic resistance mechanisms. Here, we identify Aurora kinase A (AURKA) as a central suppressor of ferroptosis by rewiring cholesterol metabolism. Mechanistically, AURKA phosphorylates and destabilizes its negative regulator SAPS3 at Ser523/524, relieving AMPK suppression. Activated AMPK subsequently inhibits SREBP2 nuclear translocation and DHCR7 transcription, resulting in the accumulation of 7-dehydrocholesterol (7-DHC), a lipid antioxidant that confers ferroptosis resistance. Both genetic and pharmacologic inhibition of AURKA restore ferroptosis sensitivity and enhance chemotherapy efficacy in vitro and in patient-derived xenograft models. Clinically, elevated AURKA expression correlates with poor prognosis and reduced chemotherapy response in CRC patients. These findings delineate a novel AURKA-SAPS3-AMPK-SREBP2 axis that bridges cholesterol homeostasis and ferroptosis evasion, positioning AURKA as a promising therapeutic target for chemosensitization in CRC.