Bmi1 regulates murine intestinal stem cell proliferation and self-renewal downstream of Notch

Genetic data indicate that abrogation of Notch-Rbpj or Wnt-beta-catenin pathways results in the loss of the intestinal stem cells (ISCs). However, whether the effect of Notch is direct or due to the aberrant differentiation of the transit-amplifying cells into post-mitotic goblet cells is unknown. To address this issue, we have generated composite tamoxifen-inducible intestine-specific genetic mouse models and analyzed the expression of intestinal differentiation markers. Importantly, we found that activation of beta-catenin partially rescues the differentiation phenotype of Rbpj deletion mutants, but not the loss of the ISC compartment. Moreover, we identified Bmi1, which is expressed in the ISC and progenitor compartments, as a gene that is co-regulated by Notch and beta-catenin. Loss of Bmi1 resulted in reduced proliferation in the ISC compartment accompanied by p16(INK4a) and p19(ARF) (splice variants of Cdkn2a) accumulation, and increased differentiation to the post-mitotic goblet cell lineage that partially mimics Notch loss-of-function defects. Finally, we provide evidence that Bmi1 contributes to ISC self-renewal.

The Intestinal Epithelium

Luca Pellegrinet

The mammalian intestine is a prototype of a self-renewing organ. The rapid cellular turnover is supported by proliferating progenitors located in the intestinal crypt, which is also the stem cell location. Homeostasis of the intestinal epithelium has to be under stringent control to ensure lifelong self-renewal. Processes like proliferation and differentiation (often deregulated in cancer) seem to be controlled by a relative small number of signaling pathways, including Wnt and Notch. Notch signaling is playing a crucial role in the maintenance of the intestinal homeostasis by controlling progenitors proliferation and their cell fate. In this thesis project we studied Notch signaling and its role in the murine intestine focusing on 1) Its downstream mediators; 2) The identification of the physiological Notch ligands; 3) Its role on the stem cell compartment, and 4) the potential cross talk between Notch and Wnt. Furthermore, 5) we investigated the role of Notch signaling in Wnt induced intestinal tumorigenesis. This study evidenced that Hes1 is not the unique Notch signaling mediator in the intestinal epithelium. Moreover the transcription factor Klf4 is not required for goblet cell differentiation. The in vivo role of the Notch ligands Dll1, Dll4 and Jag1 was assessed deriving inducible intestine specific single and double gene-targeted mice. Inactivation of individual ligands did not show any loss of Notch phenotype with the exception of Dll1 mutant mice. Only by deriving double mutants we identified Dll1 and Dll4 as the physiological Notch ligands in the intestine. We provided evidence for the first time that Notch1 signaling is active in intestinal stem cell. Furthermore we demonstrated that Notch signaling is required for the maintenance of intestinal stem cells, as well as for the transit-amplifying progenitor compartment. Using different genetic gain and loss-off function approaches we investigated the relation between the Notch and Wnt cascade for the maintenance of the proliferative crypt compartment. A synergistic relation was observed between Notch and Wnt in intestinal tumorigenesis. Collectively our data highlight Notch signaling as a key player for the maintenance of intestinal homeostasis.

EPFL2011

BCL9 is an essential component of canonical Wnt signaling that mediates the differentiation of myogenic progenitors during muscle regeneration

Michel Aguet

Muscle stem cells and their progeny play a fundamental role in the regeneration of adult skeletal muscle. We have previously shown that activation of the canonical Wnt/beta-catenin signaling pathway in adult myogenic progenitors is required for their transition from rapidly dividing transient amplifying cells to more differentiated progenitors. Whereas Wnt signaling in Drosophila is dependent on the presence of the co-regulator Legless, previous studies of the mammalian ortholog of Legless, BCL9 (and its homolog, BCL9-2), have not revealed an essential role of these proteins in Wnt signaling in specific tissues during development. Using Cre-lox technology to delete BCL9 and BCL9-2 in the myogenic lineage in vivo and RNAi technology to knockdown the protein levels in vitro, we show that BCL9 is required for activation of the Wnt/beta-catenin cascade in adult mammalian myogenic progenitors. We observed that the nuclear localization of beta-catenin and downstream TCF/LEF-mediated transcription, which are normally observed in myogenic progenitors upon addition of exogenous Wnt and during muscle regeneration, were abrogated when BCL9/9-2 levels were reduced. Furthermore, reductions of BCL9/9-2 inhibited the promotion of myogenic differentiation by Wnt and the normal regenerative response of skeletal muscle. These results suggest a critical role of BCL9/9-2 in the Wnt-mediated regulation of adult, as opposed to embryonic, myogenic progenitors.

Elsevier2009

The Intestinal Epithelium

Luca Pellegrinet

EPFL2011