Etude des effets des rayonnements ionisants sur la niche hématopoïétique et traitement du syndrome aigu d'irradiation par thérapie génique chez le macaque irradié à forte dose

Garrigou, Philipppe

07 September 2011

La niche des cellules souches hématopoïétiques représente un compartiment complexe et radiosensible. Sa protection est nécessaire pour la restauration de l'hématopoïèse faisant suite à la myélosuppression due à l'exposition aux rayonnements ionisants. Nous avons dans un premier temps étudié l'effet des RI sur les progéniteurs endothéliaux et mésenchymateux de la niche par une étude de radiosensiblilité et une étude d'évaluation de la mort cellulaire. Nous avons proposé par la suite une stratégie innovante de thérapie génique basée sur la sécrétion locale et à court terme du morphogène Sonic hedgehog visant à favoriser la réparation de niche vasculaire et de stimuler les cellules souches hématopoïétiques et les cellules progénitrices résiduelles. Nous avons étudié la réponse hématopoïétique des singes irradiés à 8-Gy gamma après une seule injection intra-osseuse de cellules souches mésenchymateuses xénogéniques, multipotentes et d'origine adipocytaire transfectées avec un plasmide pIRES2-eGFP codant la protéine Shh. La durée de thrombocytopénie et celle de neutropénie ont été significativement réduites chez les animaux greffés et les clonogènes sont normalisés à partir du 42e jour. Les aires sous la courbe des numération des plaquettes et des neutrophiles entre 0 et 30 jours ont été significativement plus élevée chez les animaux traités que chez les témoins. La greffe d'explants de MatrigelTM colonisés ou non avec des ASC chez des souris immunodéprimées a démontré une activité pro-angiogénique notable des ASC transfectées avec le plasmide Shh . Le suivi à long terme (180 à 300 jours) a confirmé une reconstitution durable dans les quatre singes greffés. Globalement cette étude suggère que la greffe de cellules souches multipotentes Shh-peut représenter une nouvelle stratégie pour la prise en charge des dommages radio-induits de la niche.

[SDV] Life Sciences

Irradiation

ASC

Sonic Hedgehog

Cellules souches

Hématopoïèse

Culture cellulaire

The Transcriptional Regulation of Stem Cell Differentiation Programs by Hedgehog Signalling

Voronova, Anastassia

30 August 2012

The Hedgehog (Hh) signalling pathway is one of the key signalling pathways orchestrating intricate organogenesis, including the development of neural tube, heart and skeletal muscle. Yet, insufficient mechanistic understanding of its diverse roles is available. Here, we show the molecular mechanisms regulating the neurogenic, cardiogenic and myogenic properties of Hh signalling, via effector protein Gli2, in embryonic and adult stem cells. In Chapter 2, we show that Gli2 induces neurogenesis, whereas a dominant-negative form of Gli2 delays neurogenesis in P19 embryonal carcinoma (EC) cells, a mouse embryonic stem (ES) cell model. Furthermore, we demonstrate that Gli2 associates with Ascl1/Mash1 gene elements in differentiating P19 cells and activates the Ascl1/Mash1 promoter in vitro. Thus, Gli2 mediates neurogenesis in P19 cells at least in part by directly regulating Ascl1/Mash1 expression. In Chapter 3, we demonstrate that Gli2 and MEF2C bind each other’s regulatory elements and regulate each other’s expression while enhancing cardiomyogenesis in P19 cells. Furthermore, dominant-negative Gli2 and MEF2C proteins downregulate each other’s expression while imparing cardiomyogenesis. Lastly, we show that Gli2 and MEF2C form a protein complex, which synergistically activates cardiac muscle related promoters. In Chapter 4, we illustrate that Gli2 associates with MyoD gene elements while enhancing skeletal myogenesis in P19 cells and activates the MyoD promoter in vitro. Furthermore, inhibition of Hh signalling in muscle satellite cells and in proliferating myoblasts leads to reduction in MyoD and MEF2C expression. Finally, we demonstrate that endogenous Hh signalling is important for MyoD transcriptional activity and that Gli2, MEF2C and MyoD form a protein complex capable of inducing skeletal muscle-specific gene expression. Thus, Gli2, MEF2C and MyoD participate in a regulatory loop and form a protein complex capable of inducing skeletal muscle-specific gene expression. Our results provide a link between the regulation of tissue-restricted factors like Mash1, MEF2C and MyoD, and a general signal-regulated Gli2 transcription factor. We therefore provide novel mechanistic insights into the neurogenic, cardiogenic and myogenic properties of Gli2 in vitro, and offer novel plausible explanations for its in vivo functions. These results may also be important for the development of stem cell therapy strategies.

embryonic stem cells

satellite cells

hedgehog

gli

Mash

MEF2

MyoD

cardiomyogenesis

skeletal myogenesis

neurogenesis

Novel Properties of SP cells in STS, and How They May Be Targeted to Develop Potential Therapies

Wang, Chang Ye Yale

30 December 2010

Tumours contain heterogeneous cell populations. A population enriched in tumour-initiating potential has been identified in soft-tissue sarcoma (STS) by the isolation of "side population" (SP) cells. In this study, we compared the gene expression profiles of SP and non-SP cells in STS and identified Hedgehog (Hh) and Notch pathways as potential candidates for the targeting of SP cells. Upon verification of the activation of these pathways in SP cells, using primary tumor xenografts in NOD-SCID mice as our experimental model, we used the Hh blocker Triparanol and the Notch blocker DAPT to demonstrate that the suppression of these pathways effectively depleted the abundance of SP cells, reduced tumour growth, and inhibited the tumour-initiating potential of the treated sarcoma cells upon secondary transplantation. The data provide additional evidence that SP cells act as tumour initiating cells and points to Hh and Notch pathways as enticing targets for developing potential cancer therapies.

Cancer

Stem Cell

Soft-tissue sarcoma

sarcoma

Notch

Hedgehog

Therapy

0306

0992

0307

Novel Properties of SP cells in STS, and How They May Be Targeted to Develop Potential Therapies

Wang, Chang Ye Yale

30 December 2010

Tumours contain heterogeneous cell populations. A population enriched in tumour-initiating potential has been identified in soft-tissue sarcoma (STS) by the isolation of "side population" (SP) cells. In this study, we compared the gene expression profiles of SP and non-SP cells in STS and identified Hedgehog (Hh) and Notch pathways as potential candidates for the targeting of SP cells. Upon verification of the activation of these pathways in SP cells, using primary tumor xenografts in NOD-SCID mice as our experimental model, we used the Hh blocker Triparanol and the Notch blocker DAPT to demonstrate that the suppression of these pathways effectively depleted the abundance of SP cells, reduced tumour growth, and inhibited the tumour-initiating potential of the treated sarcoma cells upon secondary transplantation. The data provide additional evidence that SP cells act as tumour initiating cells and points to Hh and Notch pathways as enticing targets for developing potential cancer therapies.

Cancer

Stem Cell

Soft-tissue sarcoma

sarcoma

Notch

Hedgehog

Therapy

0306

0992

0307

The Role of Sonic Hedgehog in Outflow Tract Development

Dyer, Laura Ann

January 2009

<p>The two major contributing populations to the outflow tract of the heart are the secondary heart field and the cardiac neural crest. These two populations are responsible for providing the myocardium that supports the outflow tract valves, the smooth muscle that surrounds these valves and the outflow vessels themselves, and the septum that divides the primitive, single outflow tract into an aorta and pulmonary trunk. Because the morphogenesis of this region is so complex, its development is regulated by many different signaling pathways. One of these pathways is the Sonic hedgehog pathway. This thesis tests the hypothesis that Sonic hedgehog induces secondary heart field proliferation, which is necessary for normal outflow tract development. To address this hypothesis, I took advantage of small chemical antagonists and agonists to determine how too little or too much hedgehog signaling would affect the secondary heart field, both in in vitro explants and in vivo. I have determined that Sonic hedgehog signaling maintains proliferation in a subset of secondary heart field cells. This proliferation is essential for generating enough myocardium and smooth muscle and also for the cardiac neural crest to septate the outflow tract into two equal-sized vessels. Up-regulating hedgehog signaling induces proliferation, which is quickly down-regulated, showing that the embryo exhibits a great deal of plasticity. Together, these studies have shown that Sonic hedgehog promotes proliferation in a subset of the secondary heart field and that the level of proliferation must be tightly regulated in order to form a normal outflow tract.</p> / Dissertation

Biology, Cell

cardiac neural crest

DiGeorge syndrome

outflow tract

secondary heart field

Sonic hedgehog

The Role of FGF Signaling During Granule Neuron Precursor Development and Tumorigenesis

Emmenegger, Brian Andrew

January 2010

<p>Development requires a delicate balance of proliferation and differentiation. Too little proliferation can result in dysfunctional tissues, while prolonged or heightened proliferation can result in tumor formation. This is clearly seen with the granule neuron precursors (GNPs) of the cerebellum. Too little proliferation of these cells during development results in ataxia, whereas too much proliferation results in the cerebellar tumor medulloblastoma. While these cells are known to proliferate in response to Shh, it is not clear what controls the differentiation of these cells in vivo.</p><p> Previous work from our lab has identified basic fibroblast growth factor (bFGF) as a candidate differentiation factor for these cells. In this thesis, I characterize some of the cellular and molecular mechanisms involved in FGF-mediated inhibition (FMI) of Shh-induced GNP proliferation. In addition, I employ FGFR knockouts and a bFGF gain-of-function mouse to determine whether FGF signaling is necessary and/or sufficient for differentiation of GNPs during cerebellar development. Finally, the question of whether bFGF can be effective as a therapeutic agent for in vivo tumor treatment is tested in a transplant model.</p><p> These experiments indicate that FGF signaling is neither necessary nor sufficient for GNP differentiation during cerebellar development. However, transplanted tumors are potently inhibited by bFGF treatment. Furthermore, FMI is shown to occur around the level of Gli2 processing in the Shh pathway, implying that such a treatment has promise to be widely effective in treatment of Shh-dependent medulloblastomas.</p> / Dissertation

Biology

bFGF

fibroblast growth factor

granule neuron precursors

medulloblastoma

Shh

sonic hedgehog

A Novel Proteolytic Event Controls Hedgehog Intracellular Sorting and Transport

Daniele, Joseph

January 2012

The protein Hedgehog (Hh) is a highly conserved, secreted ligand (and morphogen) capable of patterning many different tissues during development. Recently, Sonic Hedgehog (SHH) a human homolog of Drosophila Hh was found to be a causative agent in certain cancers. While several drugs are being developed to combat the binding of SHH to its receptor Patched or the Patched-target Smoothened, very little is known about how SHH is secreted from the producing cell, another site for therapeutic targeting. We report here the characterization of a novel proteolytic event and genetic pathway that controls Hh intracellular sorting and axon transport using the Drosophila eye imaginal disc as our model system. In fly larval photoreceptor neurons the developmental signal Hh is guided to the apical (retina) and basal (growth cone, GC) ends where secretion of the morphogen is an inductive factor in photoreceptor differentiation and establishment of eye/brain neural connections. The Hh secreted from the basal side induces lamina development while Hh secreted at the retina induces ommatidial development. Hedgehog processing consists of autocleavage from its 46 kDa form (HhU) to become a lipid-modified N-terminal signaling molecule (HhN; 19kDa) and a C-terminal molecule (HhC24; 24 kDa). Following autocleavage, a fraction of the C-terminal auto-cleavage product then undergoes a second cleavage event leading to 16 kDa (HhC16) and 9 kDa products. Nothing is known about the significance of the C-terminal “2nd cleavage” other than its occurrence in both fly and human tissue. In an effort to identify regulators of Hh sorting, we discovered that the HhC “2nd cleavage” is a determining factor in the sorting of the HhN signaling domain. That is, if a cell induces more cleavage (more HhC16) we observe more HhN in the apical domain. Likewise, if a cell inhibits 2nd cleavage (less HhC16) we see more basal HhN. Creation of a “2nd cleavage mutant” shows that this process has developmental significance. Further, biochemical characterization of the 2nd cleavage suggests it occurs in the ER after autocleavage and that HhC24 can exit the cell in a Golgi independent manner (via lipid droplets) while HhC16 remains intracellular. The ER exit of HhC24 appears to be controlled by a conserved PP2A (Mts) /PKB (Akt) kinase pathway which potentially regulates the size and number of lipid droplets produced. These findings are an important first step in understanding the intracellular sorting and transport of Hh and highlight new targets for the treatment of SHH-related cancers. The discovery of divergent modes of Hh secretion and the “2nd cleavage” open novel avenues for Hh research by offering an alternative, and very direct, line of attack in the treatment of Hh-related cancer.

hedgehog

intracellular transport

lipid droplet

morphogen

secretion

sorting

biochemistry

cellular biology

developmental biology

Smoothened regulation in the Hedgehog signaling pathway

Nedelcu, Daniel

18 October 2013

Hedgehog signaling is a pathway essential in embryonic development, adult stem cell maintenance, and is implicated in the formation and progression of cancer. Signaling in this pathway is triggered when the secreted protein Hedgehog binds to its membrane receptor, Patched. Patched normally inhibits the seven-spanner transmembrane protein Smoothened (Smo). Binding of Hedgehog inhibits Patched resulting in Smo derepression. Active Smo then triggers the activation of the cytoplasmic steps of the signaling pathway.

Cellular biology

Chemistry

Biology

cilium

cysteine-rich domain

Hedgehog

oxysterols

Smoothened

Central role for Sonic hedgehog-triggered pericytes in hindbrain choroid plexus development

Yang, Peter

25 February 2014

The choroid plexus is an organ within each brain ventricle comprised of elaborate folds of epithelium (CPe) and vasculature. It performs numerous functions essential for brain development and health, including secretion of cerebrospinal fluid (CSF) and acting as the blood-CSF barrier. Functionality requires: (1) that CPe and vasculature develop in register and in close proximity, so that the CPe ensheaths the vasculature at a high surface area to volume ratio, which permits efficient CSF secretion; and (2) that CPe barrier integrity is sustained throughout choroid plexus expansion. Genetic experiments in mouse embryos have identified a central role for Sonic hedgehog (Shh) in coordinating these developmental challenges. Specifically, Shh is secreted by differentiated CPe and drives choroid plexus expansion. In the absence of Shh, a hypoplastic choroid plexus forms, which is deficient in CPe, vasculature, and villous folds. Two choroid plexus cell populations respond to Shh: (1) rhombic lip-resident CPe progenitor cells and (2) vascular pericytes. Here, I present evidence that canonical Shh signaling to CPe progenitors alone is insufficient to fully drive their proliferation at normal rates. Rather, Shh-triggered pericytes appear to secondarily boost CPe progenitor cell proliferation, in addition to acting in vascular development. Shh-triggered pericytes also appear necessary for formation of the characteristic folds of the choroid plexus. Thus, pericytes coordinate the expansion of choroid plexus epithelium and vasculature. Notch signaling was also explored and was found to inhibit the differentiation of CPe progenitors, maintaining them in a proliferative state. Notch activation in CPe progenitors leads to invaginated tubules from the overproliferating CPe progenitor domain, without associated vascular growth or villous folds. Folding morphogenesis may thus be regulated by vascular components such as pericytes, and require that vascular growth match CPe growth. To identify Shh-induced pericyte signaling programs that might underlie these developmental processes, expression profiling was performed on dsRed-labeled pericytes isolated from Shh-deficient versus wild-type choroid plexuses. Candidate genes, including several involved in lipid metabolism, were identified. Collectively, this work points to pericytes as central in orchestrating the coordinated elaboration of multiple choroid plexus cell types, producing the complex tissue architecture required for efficient CSF production.

Genetics

Developmental biology

Biology

Choroid plexus

Development

Epithelium

Notch

Pericyte

Sonic hedgehog

Discovery of bioactive lipids and lipid pathways in cell death and disease

Zhang, Tejia

04 June 2015

Apoptosis is an intricately regulated cellular process required for the health and homeostasis of living systems. The mitochondrial apoptotic pathway depends on the BCL-2 family of pro- and anti-apoptotic members whose interactions regulate cell fate. BAX and BAK are key pro-apoptotic proteins required for mitochondrial permeabilization during apoptosis. While the mitochondrial death program relies heavily on its protein components, evidences support equally crucial roles for lipids and lipid metabolism in promoting or hindering apoptosis at the mitochondria. To gain insight into the interplay between lipids and BCL-2 proteins we used a liquid chromatography (LC)-mass spectrometry (MS)-based comparative lipidomics approach to uncover lipid changes in the absence of BAX and/or BAK. Our analysis revealed novel functions for BAX and BAK in inflammation and ceramide metabolism. A targeted LC-MS workflow was also developed for characterization of a novel lipid class involved in type 2 diabetes. Targeted LC-MS revealed altered oxysterol metabolism following perturbation of the Sonic hedgehog pathway. Taken together, our findings demonstrate interesting connections among lipids, cell death and disease. / Chemistry and Chemical Biology

Biochemistry

Apoptosis

Inflammation

Lipids

Metabolomics

Sonic hedgehog pathway

Type 2 diabetes