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Abstract

Similar to mammalian stem cells, plant stem cells divide at a high frequency with the unique characteristic that the original mother cell retains stem cell activity whereas the daughter cell will acquire over time a certain cell type. Remarkably, at the center of the root stem cell niche, a small group of cells can be found that exhibit a division rate being far below that of its surrounding stem cells, being the quiescent center (QC) cells. Their low division rate is likely contribution to their stress resistance, as indicated by the observation that induced cell proliferation renders the QC cells sensitive to e.g. DNA damage. Moreover, whereas QC cells are more resistant to DNA damage, they appear to be engaged into cell division upon perceiving stress. Using a combination of genetics and biochemical purifications we identified a new transcription complex that controls cell division upon loss of stem cells. Remarkably, the co-expression of all complex subunits grants differentiated cells the ability to obtain QC identity, resulting in ectopic de novo establishment of stem cell niches. Reversely, activity of both subunits is required for re-establishment of new stem cell niches upon loss of QC cells by stress.

Refs

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