Notch signaling in the pigmented epithelium of the anterior eye segment promotes ciliary body development at the expense of iris formation

The ciliary body and iris are pigmented epithelial structures in the anterior eye segment that function to maintain correct intra-ocular pressure and regulate exposure of the internal eye structures to light, respectively. The cellular and molecular factors that mediate the development of the ciliary body and iris from the ocular pigmented epithelium remain to be fully elucidated. Here, we have investigated the role of Notch signaling during the development of the anterior pigmented epithelium by using genetic loss- and gain-of-function approaches. Loss of canonical Notch signaling results in normal iris development but absence of the ciliary body. This causes progressive hypotony and over time leads to phthisis bulbi, a condition characterized by shrinkage of the eye and loss of structure/function. Conversely, Notch gain-of-function results in aniridia and profound ciliary body hyperplasia, which causes ocular hypertension and glaucoma-like disease. Collectively, these data indicate that Notch signaling promotes ciliary body development at the expense of iris formation and reveals novel animal models of human ocular pathologies.

Notch Signaling in Pigment Cells and Generation of Mouse Models for Ocular Diseases

Bhushan Sarode

Cellular signaling mediated by Notch receptors results in coordinated regulation of cell growth, survival and differentiation. In melanocytes, Notch signaling is essential for the maintenance of melanocytes and the melanocyte stem cell population. Whereas, in pigmented eye structures, specifically in ciliary body and iris, the role of Notch signaling in their structure and their development is largely unknown. In the first part, I have tried to identify possible Notch target genes in melanocytes which might indicate why the melanocyte stem cell population disappears in the absence of Notch. For that purpose, I carried out microarray analysis on Notch deficient melanoblasts and identified putative Notch targets. I have furthermore established mouse melanocyte cell lines from mice which could be used as a valuable tool to study melanocyte biology. In the second part, I have elucidated the functional significance of the Notch cascade in pigmented eye structures. The ciliary body and iris are pigmented epithelial structures in the anterior eye segment that function to maintain correct intraocular pressure and regulate exposure of the internal eye structures to light respectively. In this part I have analyzed the role of the Notch signaling by performing both loss- and gain-of-function experiments for Notch in the murine ocular pigmented epithelium using Mart-1::Cre mice. Loss of canonical Notch2 signaling results in normal iris development but ciliary body aplasia. In contrast, Notch gain-of-function induces the reciprocal phenotype and causes aniridia and ciliary body hyperplasia. The loss and gain-of-function models I have generated develop ocular hypotony and ocular hypertension respectively, mimicking the human diseases phthisis bulbi and closed angle glaucoma. Importantly, the ocular hypertension that occurs following Notch overexpression is responsive to hypotensive drugs, and thus can serve as a platform to evaluate novel hypotensive agents that may be used to treat closed angle glaucoma. In summary, the present study has identified novel putative Notch target genes which will provide us information to study the pigmentation and related disorder. The data obtained in the second chapter provide novel insight into the role of Notch signaling during development of the ciliary body and iris and thus represent a conceptual advance in our understanding of how pigmented structures of the eye are formed. In addition, the genetic models presented in this study represent robust tools with which to study the etiology, pathology and treatment of diseases related to aberrant intraocular pressure, such as phthisis bulbi and closed angle glaucoma.

EPFL2013

Role of Neurogenin3 in migration of pancreatic endocrine cells during development

Mathieu Gouzi

The pancreas is one of the major organs of the digestive tract. Its endocrine function, mainly regulating glucose blood level, is achieved by endocrine cells. These cells are organized in clusters, the so-called islets of Langerhans. During development, these cells are specified within the pancreatic epithelium, and will subsequently delaminate and migrate out of the epithelium in order to form the islets. Neurogenin3 (Ngn3) is a bHLH transcription factor that is responsible for the differentiation of all endocrine cell types, but whether or not it has a role in their migration is still an open question. By using the chicken embryo model organism, we found that the differentiation and migration programs are two different processes that are induced by Ngn3 and that can be uncoupled. Therefore, we tried to unravel the mechanisms by which Ngn3 can induce endocrine cell migration. We found that, in both chick and mouse models, over-expression of Ngn3 induces a loss of apico-basal polarity, a breakdown of basal lamina, and more importantly, a loss of the epithelial marker E-cadherin (E-cad). It seems that this is not a direct effect mediated by direct binding to E-boxes in the E-cad promoter. Therefore, we are currently trying to find targets of Ngn3 that could mediate repression of E-cad, focusing on the zinc-finger transcription factors Snail1 and Snail2. Moreover, we also used a pancreatic explant culture method, developed in the laboratory of Pr. Jonathan Slack, which allows us to do time-lapse imaging and describe precisely the migration of endocrine cells in a system similar to in vivo conditions. Taking advantage of our Pdx1::Ngn3ERTM transgenic line, we followed Ngn3 misexpressing cells to understand in a more physiological manner how they migrate in the developing pancreas. We found that endocrine cell migrate at an average speed of 11.35 µm/h and migrate through an average length of 132.30 µm in 12 hours. We also found that endocrine cells migrate in the three compartments we defined: in the mesenchyme, inside the epithelium and at the edge of the epithelium. Their average velocity significantly changes depending on the compartment cells are migrating in. We found that the fastest cells are the ones migrating at the edge of the epithelium. RNA profiling comparing Ngn3 knockouts rescued or not by the Pdx1::Ngn3ERTM transgene was also used to identify the genes that function in endocrine cell migration downstream of Ngn3. We identified new Ngn3 target genes, some of which are implicated in migration such as the Doublecortin family.

EPFL2010

Atopic dermatitis-like disease and associated lethal myeloproliferative disorder arise from loss of notch signaling in the murine skin

Matteo Di Piazza, Ute Koch, Freddy Radtke

BACKGROUND: The Notch pathway is essential for proper epidermal differentiation during embryonic skin development. Moreover, skin specific loss of Notch signaling in the embryo results in skin barrier defects accompanied by a B-lymphoproliferative disease. However, much less is known about the consequences of loss of Notch signaling after birth. METHODOLOGY AND PRINCIPAL FINDINGS: To study the function of Notch signaling in the skin of adult mice, we made use of a series of conditional gene targeted mice that allow inactivation of several components of the Notch signaling pathway specifically in the skin. We demonstrate that skin-specific inactivation of Notch1 and Notch2 simultaneously, or RBP-J, induces the development of a severe form of atopic dermatitis (AD), characterized by acanthosis, spongiosis and hyperkeratosis, as well as a massive dermal infiltration of eosinophils and mast cells. Likewise, patients suffering from AD, but not psoriasis or lichen planus, have a marked reduction of Notch receptor expression in the skin. Loss of Notch in keratinocytes induces the production of thymic stromal lymphopoietin (TSLP), a cytokine deeply implicated in the pathogenesis of AD. The AD-like associated inflammation is accompanied by a myeloproliferative disorder (MPD) characterized by an increase in immature myeloid populations in the bone marrow and spleen. Transplantation studies revealed that the MPD is cell non-autonomous and caused by dramatic microenvironmental alterations. Genetic studies demontrated that G-CSF mediates the MPD as well as changes in the bone marrow microenvironment leading to osteopenia. SIGNIFICANCE: Our data demonstrate a critical role for Notch in repressing TSLP production in keratinocytes, thereby maintaining integrity of the skin and the hematopoietic system.

Public Library of Science2010