Molecular Metabolism (Sep 2021)

Non-canonical NRF2 activation promotes a pro-diabetic shift in hepatic glucose metabolism

  • Pengfei Liu,
  • Matthew Dodson,
  • Hui Li,
  • Cody J. Schmidlin,
  • Aryatara Shakya,
  • Yongyi Wei,
  • Joe G.N. Garcia,
  • Eli Chapman,
  • Pawel R. Kiela,
  • Qing-Yu Zhang,
  • Eileen White,
  • Xinxin Ding,
  • Aikseng Ooi,
  • Donna D. Zhang

Journal volume & issue
Vol. 51
p. 101243

Abstract

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Objective: NRF2, a transcription factor that regulates cellular redox and metabolic homeostasis, plays a dual role in human disease. While it is well known that canonical intermittent NRF2 activation protects against diabetes-induced tissue damage, little is known regarding the effects of prolonged non-canonical NRF2 activation in diabetes. The goal of this study was to determine the role and mechanisms of prolonged NRF2 activation in arsenic diabetogenicity. Methods: To test this, we utilized an integrated transcriptomic and metabolomic approach to assess diabetogenic changes in the livers of wild type, Nrf2−/−, p62−/−, or Nrf2−/−; p62−/− mice exposed to arsenic in the drinking water for 20 weeks. Results: In contrast to canonical oxidative/electrophilic activation, prolonged non-canonical NRF2 activation via p62-mediated sequestration of KEAP1 increases carbohydrate flux through the polyol pathway, resulting in a pro-diabetic shift in glucose homeostasis. This p62- and NRF2-dependent increase in liver fructose metabolism and gluconeogenesis occurs through the upregulation of four novel NRF2 target genes, ketohexokinase (Khk), sorbitol dehydrogenase (Sord), triokinase/FMN cyclase (Tkfc), and hepatocyte nuclear factor 4 (Hnf4A). Conclusion: We demonstrate that NRF2 and p62 are essential for arsenic-mediated insulin resistance and glucose intolerance, revealing a pro-diabetic role for prolonged NRF2 activation in arsenic diabetogenesis.

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