Cell Reports (Feb 2019)

Loss of Hepatic Oscillatory Fed microRNAs Abrogates Refed Transition and Causes Liver Dysfunctions

  • Babukrishna Maniyadath,
  • Tandrika Chattopadhyay,
  • Srikant Verma,
  • Sujata Kumari,
  • Prineeta Kulkarni,
  • Kushal Banerjee,
  • Asmitha Lazarus,
  • Saurabh S. Kokane,
  • Trupti Shetty,
  • Krishanpal Anamika,
  • Ullas Kolthur-Seetharam

Journal volume & issue
Vol. 26, no. 8
pp. 2212 – 2226.e7

Abstract

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Summary: Inability to mediate fed-fast transitions in the liver is known to cause metabolic dysfunctions and diseases. Intuitively, a failure to inhibit futile translation of state-specific transcripts during fed-fast cycles would abrogate dynamic physiological transitions. Here, we have discovered hepatic fed microRNAs that target fasting-induced genes and are essential for a refed transition. Our findings highlight the role of these fed microRNAs in orchestrating system-level control over liver physiology and whole-body energetics. By targeting SIRT1, PGC1α, and their downstream genes, fed microRNAs regulate metabolic and mitochondrial pathways. MicroRNA expression, processing, and RISC loading oscillate during these cycles and possibly constitute an anticipatory mechanism. Fed-microRNA oscillations are deregulated during aging. Scavenging of hepatic fed microRNAs causes uncontrolled gluconeogenesis and failure in the catabolic-to-anabolic switching upon feeding, which are hallmarks of metabolic diseases. Besides identifying mechanisms that enable efficient physiological toggling, our study highlights fed microRNAs as candidate therapeutic targets. : Maniyadath et al. have discovered oscillatory hepatic miRNAs that exert network-level control on metabolism and mitochondrial functions to mediate fed-fast-refed transitions. Fed miRNAs possibly act as anticipatory mechanisms for physiological state switching and are deregulated in aging. Abrogating fed-miRNA fluctuations causes liver dysfunctions, abolishes catabolic-anabolic shift, and affects organismal homeostasis. Keywords: microRNA, fed, fast, liver, PGC1α, SIRT1, gluconeogenesis, fatty acid oxidation, mitochondria, energetics