PT  - JOURNAL ARTICLE
AU  - Kailin R. Mesa
AU  - Kyogo Kawaguchi
AU  - David G. Gonzalez
AU  - Katie Cockburn
AU  - Jonathan Boucher
AU  - Tianchi Xin
AU  - Allon M. Klein
AU  - Valentina Greco
TI  - Epidermal stem cells self-renew upon neighboring differentiation
AID  - 10.1101/155408
DP  - 2017 Jan 01
TA  - bioRxiv
PG  - 155408
4099  - http://biorxiv.org/content/early/2017/06/25/155408.short
4100  - http://biorxiv.org/content/early/2017/06/25/155408.full
AB  - Many adult tissues are dynamically sustained by the rapid turnover of stem cells. Yet, how cell fates such as self-renewal and differentiation are orchestrated to achieve long-term homeostasis remains elusive. Studies utilizing clonal tracing experiments in multiple tissues have argued that while stem cell fate is balanced at the population level, individual cell fate - to divide or differentiate – is determined intrinsically by each cell seemingly at random ( 1 ,2 ,3 ,4 ,5). These studies leave open the question of how cell fates are regulated to achieve fate balance across the tissue. Stem cell fate choices could be made autonomously by each cell throughout the tissue or be the result of cell coordination ( 6 ,7). Here we developed a novel live tracking strategy that allowed recording of every division and differentiation event within a region of epidermis for a week. These measurements reveal that stem cell fates are not autonomous. Rather, direct neighbors undergo coupled opposite fate decisions. We further found a clear ordering of events, with self-renewal triggered by neighbor differentiation, but not vice-versa. Typically, around 1-2 days after cell delamination, a neighboring cell entered S/G2 phase and divided. Functional blocking of this local feedback showed that differentiation continues to occur in the absence of cell division, resulting in a rapid depletion of the epidermal stem cell pool. We thus demonstrate that the epidermis is maintained by nearest neighbor coordination of cell fates, rather than by asymmetric divisions or fine-tuned cell-autonomous stochastic fate choices. These findings establish differentiation-dependent division as a core feature of homeostatic control, and define the relevant time and length scales over which homeostasis is enforced in epithelial tissues.