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Ontogeny and function of the circadian clock in intestinal organoids

Andrew E. Rosselot, Miri Park, Mari Kim, Toru Matsuura, Gang Wu, Danilo E. F. L. Flôres, Krithika R. Subramanian, Suengwon Lee, Nambirajan Sundaram, Taylor Broda, Heather A. McCauley, Jennifer Hawkins, Kashish Chetal, Nathan Salomonis, Noah F. Shroyer, Michael A. Helmrath, James M. Wells, John B. Hogenesch, Sean R. Moore, Christian I. Hong

2021The EMBO Journal47 citationsDOIOpen Access PDF

Abstract

Circadian rhythms regulate diverse aspects of gastrointestinal physiology ranging from the composition of microbiota to motility. However, development of the intestinal circadian clock and detailed mechanisms regulating circadian physiology of the intestine remain largely unknown. In this report, we show that both pluripotent stem cell‐derived human intestinal organoids engrafted into mice and patient‐derived human intestinal enteroids possess circadian rhythms and demonstrate circadian phase‐dependent necrotic cell death responses to Clostridium difficile toxin B (TcdB). Intriguingly, mouse and human enteroids demonstrate anti‐phasic necrotic cell death responses to TcdB. RNA‐Seq analysis shows that ~3–10% of the detectable transcripts are rhythmically expressed in mouse and human enteroids. Remarkably, we observe anti‐phasic gene expression of Rac1, a small GTPase directly inactivated by TcdB, between mouse and human enteroids, and disruption of Rac1 abolishes clock‐dependent necrotic cell death responses. Our findings uncover robust functions of circadian rhythms regulating clock‐controlled genes in both mouse and human enteroids governing organism‐specific, circadian phase‐dependent necrotic cell death responses, and lay a foundation for human organ‐ and disease‐specific investigation of clock functions using human organoids for translational applications. How rhythmicity of gene expression in the gut epithelium develops and which molecular mechanisms contribute to its maintenance remains unclear. This analysis of mouse and human organoid models uncovers species‐specific oscillatory behavior of circadian genes in the intestine. Mouse and human 3D in vitro models show tissue maturation to determine species‐specific circadian rhytms in the intestine.

Topics & Concepts

BiologyOrganoidCircadian rhythmCircadian clockFunction (biology)OntogenyCell biologyNeuroscienceGeneticsCircadian rhythm and melatonin
Ontogeny and function of the circadian clock in intestinal organoids | Litcius