Molecular Metabolism (Jul 2022)

Neuronal miR-29a protects from obesity in adult mice

  • Yuan Ma,
  • Nicola Murgia,
  • Yu Liu,
  • Zixuan Li,
  • Chaweewan Sirakawin,
  • Ruslan Konovalov,
  • Nikolai Kovzel,
  • Yang Xu,
  • Xuejia Kang,
  • Anshul Tiwari,
  • Patrick Malonza Mwangi,
  • Donglei Sun,
  • Holger Erfle,
  • Witold Konopka,
  • Qingxuan Lai,
  • Syeda Sadia Najam,
  • Ilya A. Vinnikov

Journal volume & issue
Vol. 61
p. 101507

Abstract

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Objective: Obesity, a growing threat to the modern society, represents an imbalance of metabolic queues that normally signal to the arcuate hypothalamic nucleus, a critical brain region sensing and regulating energy homeostasis. This is achieved by various neurons many of which developmentally originate from the proopiomelanocortin (POMC)-expressing lineage. Within the mature neurons originating from this lineage, we aimed to identify non-coding genes in control of metabolic function in the adulthood. Methods: In this work, we used microRNA mimic delivery and POMCCre-dependent CRISPR-Cas9 knock-out strategies in young or aged mice. Importantly, we also used CRISPR guides directing suicide cleavage of Cas9 to limit the off-target effects. Results: Here we found that mature neurons originating from the POMC lineage employ miR-29a to protect against insulin resistance obesity, hyperphagia, decreased energy expenditure and obesity. Moreover, we validated the miR-29 family as a prominent regulator of the PI3K-Akt-mTOR pathway. Within the latter, we identified a direct target of miR-29a-3p, Nras, which was up-regulated in those and only those mature POMCCreCas9 neurons that were effectively transduced by anti-miR-29 CRISPR-equipped construct. Moreover, POMCCre-dependent co-deletion of Nras in mature neurons attenuated miR-29 depletion-induced obesity. Conclusions: Thus, the first to our knowledge case of in situ Cre-dependent CRISPR-Cas9-mediated knock-out of microRNAs in a specific hypothalamic neuronal population helped us to decipher a critical metabolic circuit in adult mice. This work significantly extends our understanding about the involvement of neuronal microRNAs in homeostatic regulation.

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