Cell Reports (May 2022)

A highland-adaptation mutation of the Epas1 protein increases its stability and disrupts the circadian clock in the plateau pika

  • Na Liu,
  • Hongni Tian,
  • Ziqing Yu,
  • Haijiao Zhao,
  • Wenjing Li,
  • Di Sang,
  • Keteng Lin,
  • Yilin Cui,
  • Meimei Liao,
  • Zhancong Xu,
  • Chen Chen,
  • Ying Guo,
  • Yibing Wang,
  • Huan-wei Huang,
  • Jiawen Wang,
  • He Zhang,
  • Wei Wu,
  • He Huang,
  • Shengqing Lv,
  • Zhenqian Guo,
  • Wei Wang,
  • Sanduo Zheng,
  • Fengchao Wang,
  • Yanming Zhang,
  • Tao Cai,
  • Eric Erquan Zhang

Journal volume & issue
Vol. 39, no. 7
p. 110816

Abstract

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Summary: The Qinghai-Tibet Plateau (QTP) harbors hundreds of species well adapted to its extreme conditions, including its low-oxygen (hypoxic) atmosphere. Here, we show that the plateau pika—a keystone mammal of the QTP—lacks robust circadian rhythms. The major form of the plateau pika Epas1 protein includes a 24-residue insert caused by a point mutation at the 5′ juncture site of Intron14 and is more stable than other mammalian orthologs. Biochemical studies reveal that an Epas1-Bmal1 complex with lower trans-activation activity occupies the E1/E2 motifs at the promoter of the core-clock gene Per2, thus explaining how an Epas1 mutation—selected in the hypoxic conditions of the QTP—disrupts the molecular clockwork. Importantly, experiments with hypoxic chambers show that mice expressing the plateau pika Epas1 ortholog in their suprachiasmatic nucleus have dysregulated central clocks, and pika Epas1 knockin mice reared in hypoxic conditions exhibit dramatically reduced heart damage compared with wild-type animals.

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