Transit-amplifying cells

[IDW2BB]

The latest from Elaine.


http://www.ncbi.nlm.nih.gov/pubmed/24813615

Transit-amplifying cells orchestrate stem cell activity and tissue regeneration.

Hsu YC1, Li L1, Fuchs E2.



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Abstract

Transit-amplifying cells (TACs) are an early intermediate in tissue regeneration. Here, using hair follicles (HFs) as a paradigm, we show that emerging TACs constitute a signaling center that orchestrates tissue growth. Whereas primed stem cells (SCs) generate TACs, quiescent SCs only proliferate after TACs form and begin expressing Sonic Hedgehog (SHH). TAC generation is independent of autocrine SHH, but the TAC pool wanes if they can't produce SHH. We trace this paradox to two direct actions of SHH: promoting quiescent-SC proliferation and regulating dermal factors that stoke TAC expansion. Ingrained within quiescent SCs' special sensitivity to SHH signaling is their high expression of GAS1. Without sufficient input from quiescent SCs, replenishment of primed SCs for the next hair cycle is compromised, delaying regeneration and eventually leading to regeneration failure. Our findings unveil TACs as transient but indispensable integrators of SC niche components and reveal an intriguing interdependency of primed and quiescent SC populations on tissue regeneration.

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related study:


http://www.ncbi.nlm.nih.gov/pubmed/24462289

High Runx1 levels promote a reversible, more-differentiated cell state in hair-follicle stem cells during quiescence.

Lee SE1, Sada A1, Zhang M1, McDermitt DJ1, Lu SY1, Kemphues KJ1, Tumbar T2.



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Erratum in
Cell Rep. 2014 Feb 13;6(3):592.

Abstract

Quiescent hair follicle (HF) bulge stem cells (SCs) differentiate to early progenitor (EP) hair germ (HG) cells, which divide to produce transit-amplifying matrix cells. EPs can revert to SCs upon injury, but whether this dedifferentiation occurs in normal HF homeostasis (hair cycle) and the mechanisms regulating both differentiation and dedifferentiation are unclear. Here, we use lineage tracing, gain of function, transcriptional profiling, and functional assays to examine the role of observed endogenous Runx1 level changes in the hair cycle. We find that forced Runx1 expression induces hair degeneration (catagen) and simultaneously promotes changes in the quiescent bulge SC transcriptome toward a cell state resembling the EP HG fate. This cell-state transition is functionally reversible. We propose that SC differentiation and dedifferentiation are likely to occur during normal HF degeneration and niche restructuring in response to changes in endogenous Runx1 levels associated with SC location with respect to the niche.