From gut homeostasis to cancer

The mammalian intestine has one of the highest turnover rates in the body. The intestinal epithelium is completely renewed in less than a week. It is divided into spatially distinct compartments in the form of finger-like projections and invaginations that are dedicated to specific functions. Intestinal cells are constantly produced from a stem cell reservoir that gives rise to proliferating transient amplifying cells, which subsequently differentiate and migrate to the correct compartment before dying after having fulfilled their physiological function. In recent years, a substantial body of evidence has accumulated to support the concept that signaling pathways known to be crucial for embryonic development of multiple organisms play a critical role in tightly regulating and controlling the self-renewing process of the intestine. Moreover, the same pathways appear to be deregulated in several hereditary and sporadic colorectal cancer syndromes due to activating and/or inactivating mutations of key components of such pathways. In this review we discuss recent findings demonstrating that differentiation and homeostasis of the intestine are controlled by developmental pathways such as Wnt, Notch, TGF-beta and Hedgehog, and illustrate how their deregulation contributes to intestinal neoplasia.

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

RhoV, a Potential Notch Target Gene in Murine Skin, Does not Play an Essential Role in Epidermis Development and Homeostasis

April Bezdek Pomey

The evolutionarily conserved Notch signaling cascade plays a pivotal role in the regulation of many fundamental processes such as stem cell maintenance, proliferation, and differentiation. Recently, we aimed to identify downstream target genes regulated by Notch1 during epidermal differentiation. For this purpose an Affymetrix mouse gene chip array of 14.000 genes was performed in both Notch1 gain and loss of function experiments using murine primary keratinocytes. Thirteen genes positively or negatively regulated, based on expression levels and relevance of the involved signaling pathways, were further validated by real-time PCR. Among these, we decided to focus on the Rho GTPase RhoV because it showed robust up- and down-regulation under both gain- and loss-of-function conditions. Therefore, we generated different transgenic mice expressing either a dominant active or a dominant negative form of RhoV specifically in the skin. Morphological and histological analyses did not reveal any overt skin phenotype in transgenic mice. In addition, challenging the system by performing wound healing assays demonstrated that the healing process in transgenic mice occurred normally and that the migration and/or differentiation of keratinocytes was unimpaired. Taken together, our data suggest that gain or loss of RhoV function does not perturb skin development and homeostasis, and does not affect the wound healing process. In addition to the investigation of the potential Notch target gene RhoV, we sought to generate both a floxed Jag2 gene targeted mouse line and a Notch2-specifc reporter mouse. The former was intended to enable conditional deletion of the Notch ligand Jagged2 and therefore allow its role to be studied in a loss-of-function context. The Notch2 reporter mouse is a tool enabling the in vivo study of cells that receive a Notch2-mediated signal. The strategy employs elements of a Tet-Off system and allows cells receiving a Notch2 specific signal to be identified in any tissue at any given time point.

EPFL2010

The Cell Differentiation Status Influences the Outcome of Notch-Induced Malignancy

Caroline Poisson

The Notch signaling cascade is a well conserved pathway that regulates many aspects of embryonic development and plays a crucial role in the differentiation process and tissue homeostasis in multiple organs of adult species. Several human pathological disorders, including cancer, arise as a consequence of the deregulation of the Notch signaling pathway. Notch deregulation, up to date, has been best characterized in acute T-cell lymphoblastic leukemia (T-ALL). Indeed, in T-ALL pediatric patients activating Notch1 mutations have been identified in more than 50% of the cases. Increased knowledge of the mechanisms underlying T-ALL development and maintenance is clearly needed as one out of 5 patients with T-ALL has a very poor prognosis. Moreover, the high toxicity of chemotherapeutic regimens has been associated with elevated risks of developing severe secondary health problems. In the present study, we characterized the role of Notch in T-ALL induction and maintenance. Using transgenic mouse models, we could demonstrate that the oncogenic potential of Notch is dependent on RBP-Jκ transcriptional activity. Indeed, the canonical Notch signaling pathway, mediated by the RBP-Jκ transcription factor, is essential for both Notch-mediated T-ALL induction and maintenance, as well as for the induction of a Notch-mediated lymphoproliferative disorder. Moreover, constitutive overexpression of Notch1 at discrete developmental stages within the hematopoietic system, led us to identify a correlation between the differentiation status of a cell, within the hierarchy of the hematopoietic tree, and its sensitivity to Notch1-induced transformation. We demonstrated that forced Notch1 expression in hematopoietic stem cells was not sufficient to induce T-ALL. Nevertheless, aberrant Notch1 expression in the bone marrow resulted in the development of a lethal lymphoproliferative disorder. Overexpression of Notch1 in thmus at the DN2 to DN3 stage of T-cell delvelopment generated an aggressive transplantable T-ALL with important metastatic potential. This suggested that progenitors already committed to the T-cell lineage are highly susceptible to Notch-mediated transformation, which is relevant to the human disease. Nevertheless, forced Notch1 expression after the β-selection checkpoint in the thymys, was no longer sufficient to induce transformation of late DN3 to DN4 thymocytes. We therefore established a murine genetic system that allowed us to dissect the mechanisms of aberrant Notch1 signaling in a lymphoproliferative disorder and a true T-ALL model. We were able to assess the genetic signature that is involved in the transplantability and metastatic potential of leukemic cells and generated a list of candidate genes implicated in these processes. In addition, we correlated genes identified in our murine models with genes associated as well in human T-ALL profiles to identify genes implicated in T-ALL pathogenesis in both mouse and human.

EPFL2011

The Intestinal Epithelium

Luca Pellegrinet

EPFL2011

RhoV, a Potential Notch Target Gene in Murine Skin, Does not Play an Essential Role in Epidermis Development and Homeostasis

April Bezdek Pomey

EPFL2010

The Cell Differentiation Status Influences the Outcome of Notch-Induced Malignancy

Caroline Poisson

EPFL2011