Tristan Rodriguez and his team found that several types of viable, but fitness-compromised stem cells are eliminated from mouse embryonic stem cell (ESC) cultures due to cell competition. By co-culturing wild-type and different ‘unfit’ mouse ESCs for up to four days in differentiation-promoting media, they could show that cells with strongly reduced bone morphogenetic (BMP) signaling, compromised autophagy or with tetraploid genomes were selectively eliminated from mixed cultures, whereas they grew normally in monocultures [ 21••]. Moreover, a co-culture of two populations with compromised fitness did not show signs of competition, indicating that this system may be employed in the future to assess if certain fitness deficits
are stronger than others (e.g. autophagy vs. slow proliferation). Cells with defective BMP signaling are also outcompeted from developing fly epithelia [ 6]. In Drosophila, Stem Cell Compound Library molecular weight loser cells can be protected from
competition by overactivation of the BMP pathway (i.e. Dpp signaling). This suggests that loser cells may at least partly die because they compete less efficiently for growth/survival signals both in Drosophila and mammals [ 22•• and 6]. In a second study, Miguel Torres and his group focused their attention on early mouse embryonic development, namely the epiblast stage (Figure 1c) Bcl 2 inhibitor [22••]. The epiblast is already implanted embryonic tissue, still composed of pluripotent stem cells, which will differentiate subsequently to form all three germ layers during gastrulation. At around embryonic day 6.5 (E6.5) apoptosis peaks in the epiblast indicating that
a large fraction of cells are being eliminated. Miguel Torres and colleagues successfully developed a system to create random genetic mosaics (iMOS-System) in the mouse epiblast, which can be followed afterwards by marker proteins [22••]. When inducing a subset Cytidine deaminase of cells with higher c-Myc levels, they observed supercompetition, meaning that embryonic tissues analyzed a few days post mosaic induction, consisted mainly of c-Myc overexpressing cells [22••]. This relative enrichment of supercompetitor cells did not occur if cell death was prevented by the expression of an apoptosis inhibitor in surrounding wild-type cells. These findings demonstrate that, as in Drosophila, the relative expansion of winner cells is dependent on the purging of cells with lower relative levels of Myc. Both groups describe that ‘loser stem cells’ in their systems express lower levels of c-Myc protein compared to the winner population [21•• and 22••] and that the relative difference in Myc protein correlates with the extent of competition observed in the mouse embryo [22••]. However, it was the analysis of endogenous c-Myc expression in the epiblast, which provided the key to understand the physiologic role of cell competition: up to E6.75, epiblast stem cells showed intrinsic variations in c-Myc protein expression, whereas by day E7.
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