AI Article Synopsis
- Knockout studies revealed that Bmi-1 is crucial for the self-renewal of neural stem cells (NSCs) after birth but not during embryonic stages.
- Using lentiviral shRNAs, the study found that Bmi-1 is also essential for NSC self-renewal in embryos and its importance increases as development progresses.
- The research indicates that when Bmi-1 is reduced, it leads to issues in NSC proliferation linked to the cell-cycle inhibitor p21, suggesting that understanding these mechanisms could be vital for advancing stem cell therapies.
Article Abstract
Knockout studies have shown that the polycomb gene Bmi-1 is important for postnatal, but not embryonic, neural stem cell (NSC) self-renewal and have identified the cell-cycle inhibitors p16/p19 as molecular targets. Here, using lentiviral-delivered shRNAs in vitro and in vivo, we determined that Bmi-1 is also important for NSC self-renewal in the embryo. We found that neural progenitors depend increasingly on Bmi-1 for proliferation as development proceeds from embryonic through adult stages. Acute shRNA-mediated Bmi-1 reduction causes defects in embryonic and adult NSC proliferation and self-renewal that, unexpectedly, are mediated by a different cell-cycle inhibitor, p21. Gene array analyses revealed developmental differences in Bmi-1-controlled expression of genes in the p21-Rb cell cycle regulatory pathway. Our data therefore implicate p21 as an important Bmi-1 target in NSCs, potentially with stage-related differences. Understanding stage-related mechanisms underlying NSC self-renewal has important implications for development of stem cell-based therapies.
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