Nature Communications (Mar 2025)

HSD17B4 deficiency causes dysregulation of primary cilia and is alleviated by acetyl-CoA

  • Ji-Eun Bae,
  • Soyoung Jang,
  • Joon Bum Kim,
  • Na Yeon Park,
  • Doo Sin Jo,
  • Hyejin Hyung,
  • Pansoo Kim,
  • Min-Seon Kim,
  • Hong-Yeoul Ryu,
  • Hyun-Shik Lee,
  • Dong-Seok Lee,
  • Myriam Baes,
  • Zae Young Ryoo,
  • Dong-Hyung Cho

DOI
https://doi.org/10.1038/s41467-025-57793-8
Journal volume & issue
Vol. 16, no. 1
pp. 1 – 13

Abstract

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Abstract Primary cilia are dynamic sensory organelles orchestrating key signaling pathways, and disruption of primary ciliogenesis is implicated in a spectrum of genetic disorders. The peroxisomal bifunctional enzyme HSD17B4 is pivotal for peroxisomal β-oxidation and acetyl-CoA synthesis, and its deficiency profoundly impairs peroxisomal metabolism. While patients with HSD17B4 deficiency exhibit ciliopathy-like symptoms due to dysfunctional primary cilia, the molecular connection between HSD17B4 and ciliopathy remains poorly understood. Here, we demonstrate that HSD17B4 deficiency impairs primary ciliogenesis and alters cilia-mediated signaling, suggesting a potential link between peroxisomal metabolism and ciliary function. Notably, elevation of acetyl-CoA rescues ciliary defects via HDAC6-mediated ciliogenesis in HSD17B4-deficient cells. Strikingly, acetate administration restores motor function, enhances primary cilia formation, and preserves the Purkinje layer in Hsd17B4-knockout mice. These findings provide insights into the functional link between HSD17B4 and primary cilia, highlighting acetyl-CoA as a potential therapeutic target for HSD17B4 deficiency and ciliopathy.