Goran Tomić scite author profile

SummaryThe intestinal epithelium is largely maintained by self-renewing stem cells but with apparently committed progenitors also contributing, particularly following tissue damage. However, the mechanism of, and requirement for, progenitor plasticity in mediating pathological response remain unknown. Here we show that phosphorylation of the transcription factor Atoh1 is required for both the contribution of secretory progenitors to the stem cell pool and for a robust regenerative response. As confirmed by lineage tracing, Atoh1+ cells (Atoh1(WT)CreERT2 mice) give rise to multilineage intestinal clones both in the steady state and after tissue damage. In a phosphomutant Atoh1(9S/T-A)CreERT2 line, preventing phosphorylation of ATOH1 protein acts to promote secretory differentiation and inhibit the contribution of progenitors to self-renewal. Following chemical colitis, Atoh1+ cells of Atoh1(9S/T-A)CreERT2 mice have reduced clonogenicity that affects overall regeneration. Progenitor plasticity maintains robust self-renewal in the intestinal epithelium, and the balance between stem and progenitor fate is directly coordinated by ATOH1 multisite phosphorylation.

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Phospho-regulation of Atoh1 is required for plasticity of secretory progenitors and tissue regeneration

Tomić

Morrissey

Kozar

et al. 2018

Preprint

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SUMMARYThe intestinal epithelium is maintained by a small number of self-renewing stem cells in homeostasis. In addition committed progenitors can contribute to the functional stem cell compartment at a low level during homeostasis and substantially during regeneration following tissue damage. However the mechanism of, and requirement for, progenitor plasticity in mediating pathological response has not been demonstrated. Here we show that multisite phosphorylation of the transcription factor Atoh1 is required both for the contribution of secretory progenitors to the intestinal stem cell pool and for a robust regenerative response following damage. In lineage tracing experiments Atoh1+ cells (Atoh1(WT)CreERT2 mice) show stem cell activity by giving rise to multilineage intestinal clones both in the steady state and after tissue damage. Notably in the colonic epithelium a single generation of Atoh1+ progenitors sustains 1 in 15 stem cells. In an activating Atoh1(9S/T-A)CreERT2 line, the loss of phosphorylation sites on the Atoh1 protein promotes secretory differentiation and inhibits the contribution of these cells to self-renewal. Finally, in a chemical colitis model the Atoh1+ cells of Atoh1(9S/T-A)CreERT2 mice have reduced clonogenic capacity that impacts overall regenerative response of the epithelium. Thus progenitor plasticity plays an integral part in maintaining robust self-renewal in the intestinal epithelium and the balance between stem and progenitor fate behaviour is directly co-ordinated by Atoh1 multi-site phosphorylation.

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Goran Tomić

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Phospho-regulation of ATOH1 Is Required for Plasticity of Secretory Progenitors and Tissue Regeneration

Phospho-regulation of Atoh1 is required for plasticity of secretory progenitors and tissue regeneration

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