Rôle de l'altération de la perméabilité vasculaire endoneurale dans la genèse des douleurs neuropathiques périphériques post-traumatiques : Implications des voies de signalisation TLR4, Sonic Hedgehog et Wnt/ß-caténine / Disruption of endoneurial vascular permeability in the development of painful post-traumatic neuropathies : Implications of TLR4, Sonic Hedgehog and Wnt/ß-catenin signaling pathways

Moreau, Nathan

01 March 2017

A la suite d'une lésion nerveuse périphérique, de multiples altérations cellulaires et moléculaires participent à la régénération physiologique du nerf, mais induisent dans certains cas le développement d'une cicatrisation dysfonctionnelle et l'apparition d'une douleur neuropathique chronique. La régulation de la perméabilité vasculaire endoneurale du nerf lésé joue un rôle essentiel dans ces phénomènes de cicatrisation nerveuse, via notamment l'infiltration locale d'immunocytes. L'objectif de ce travail était d'étudier le rôle spécifique de l'altération de la barrière hémato-nerveuse (BHN) au niveau du site lésé dans le développement des douleurs neuropathiques périphériques post-traumatiques. Nous avons montré à l'aide de modèles de constriction chronique du nerf sciatique et/ou infra-orbitaire que la disruption précoce de la BHN est un évènement clé de la neuropathie, favorisant l'infiltration locale de substances algogènes et d'immunocytes induisant une neuroinflammation, une sensibilisation périphérique et la neuropathie. L'altération des voies de signalisation Sonic Hedgehog, Wnt/?-caténine et TLR4 au niveau des cellules endothéliales endoneurales, favorise cette disruption en diminuant la synthèse des protéines de jonctions serrées, molécules clés de l'intégrité de la BHN. De plus, l'implication différentielle de ces voies dans des modèles de neurite et de neuropathie apporte un éclairage nouveau à la transition phénotypique entre neurite et neuropathie : alors que la neurite s'accompagne d'une perméabilité vasculaire endoneurale réversible, la neuropathie pourrait être considérée comme une pathologie de la perméabilité vasculaire chronique irréversible. / Following peripheral nerve injury, multiple cellular and molecular alterations occur within the nerve’s parenchyma, participating in physiological healing of the nerve, but can also lead to the development of dysfunctional nerve healing, translating as chronic neuropathic pain. The regulation of endoneurial microvascular permeability within the injured nerve plays a pivotal rôle in physiological and pathological nerve healing, notably via the local infiltration of pro-regenerative immunocytes. The main goal of this work was to study the specific role of local blood-nerve barrier disruption in the development of painful post-traumatic peripheral neuropathy. In sciatic nerve and/or infra-orbital nerve chronic constriction injury models, we showed that early disruption of the blood-nerve barrier is a key event in the development of neuropathy, allowing local infiltration of algogenic substances and immunocytes within the nerve’s parenchyma, responsible for local neuroinflammation, peripheral sensitization and peripheral neuropathic pain development. Among the homeostatic regulatory mecanisms of this barrier, the alteration of Sonic Hedgehog, Wnt/β-catenin and TLR4 signaling pathways in endoneurial endothelial cells, mediates the disruption of the blood-nerve barrier by downregulating key tight-junction proteins. Furthermore, the differential implication of these signaling pathways in models of neuritis and neuropathy shed light on the phenotypical transition between neuritis and neuropathy : As neuritis is associated with reversible endoneurial vascular permeability, neuropathy could be considered a disease of irreversible chronic vascular permeability.

Douleur neuropathique

Barrière hémato-Nerveuse

Sonic Hedgehog

Tlr4

Wnt/beta-caténine

Perméabilité vasculaire

Neuropathic pain

Blood-nerve barrier

Microvascular permeability

612.8

Expression and Functional Analysis of pthrp1 and ihha in the Regeneration of Bones in Zebrafish Caudal Fin

Al-Rewashdy, Ali

January 2013

The parathyroid hormone related protein (PTHrP) and Indian Hedgehog (IHH) are two secreted molecules, acting as paracrine factors during embryonic development and post-natal growth of endochondral bones. PTHrP and IHH are essential factors for the regulation of chondrocyte proliferation and differentiation. However, it has previously been shown that PTHrP and IHH are also expressed in the chick and mouse embryos intramembranous bones, which do not form through a cartilage intermediate and in which chondrocytes are absent. Similarly, the zebrafish orthologs, pthrp1 and ihha, are also expressed during the regeneration of the intramembranous bones of the fin rays of the zebrafish caudal fin. This surprising observation led us to further analyze the expression and function of pthrp1 and ihha in the regenerating fin rays. Gene expression analysis using in situ hybridization shows that pthrp1 is expressed in a stripe of cells located within the domain of expression of ihha in the newly differentiating osteoblasts in the regenerating fin rays. Also, pthrp1 expression is observed at the level of the joints between the bone segments forming the rays and co-localizes with the expression domain of evx1, a transcription factor that has been implicated in the formation of joints in the caudal fin. Furthermore, RT-PCR analyses show that pthrp2 and the pthrp receptors mRNA (pth1r, pth2r and pth3r) are also present in the fin regenerate. Finally, functional analysis shows that the knockdown of pthrp1 or ihha expression by electroporation of morpholinos induces a delay of the regenerative outgrowth of the fin. These results suggest that pthrp1 and ihha may be involved in the regulation of proliferation and differentiation of chondrocyte-like osteoblasts in the fin rays, playing a role similar to that described in the mammalian growth plate of endochondral bones. In addition, pthrp1 is possibly an important factor involved in the formation and maintenance of joints of the dermal bones of the fin rays.

Indian Hedgehog (IHH)

Bone

Zebrafish

Regeneration

Endochondral ossification

Intramembranous ossification

Morpholino knockdown

In situ hybridization

RT-PCR

EVX1

Pthrp1

Ihha

Secretion and Signaling Activities of Lipoprotein-Associated Hedgehog and Non-Sterol-Modified Hedgehog in Flies and Mammals

Palm, Wilhelm, Swierczynska, Marta M., Kumari, Veena, Ehrhart-Bornstein, Monika, Bornstein, Stefan R., Eaton, Suzanne

10 December 2015

Hedgehog (Hh) proteins control animal development and tissue homeostasis. They activate gene expression by regulating processing, stability, and activation of Gli/Cubitus interruptus (Ci) transcription factors. Hh proteins are secreted and spread through tissue, despite becoming covalently linked to sterol during processing. Multiple mechanisms have been proposed to release Hh proteins in distinct forms; in Drosophila, lipoproteins facilitate long-range Hh mobilization but also contain lipids that repress the pathway. Here, we show that mammalian lipoproteins have conserved roles in Sonic Hedgehog (Shh) release and pathway repression. We demonstrate that lipoprotein-associated forms of Hh and Shh specifically block lipoprotein-mediated pathway inhibition. We also identify a second conserved release form that is not sterol-modified and can be released independently of lipoproteins (Hh-N*/Shh-N*). Lipoprotein-associated Hh/Shh and Hh-N*/Shh-N* have complementary and synergistic functions. In Drosophila wing imaginal discs, lipoprotein-associated Hh increases the amount of full-length Ci, but is insufficient for target gene activation. However, small amounts of non-sterol-modified Hh synergize with lipoprotein-associated Hh to fully activate the pathway and allow target gene expression. The existence of Hh secretion forms with distinct signaling activities suggests a novel mechanism for generating a diversity of Hh responses.

info:eu-repo/classification/ddc/610

ddc:610

Sledování buněčných populací z regresivních zubních primordií během ontogeneze / Tracing the fate of cell populations from regressive tooth primordia during ontogenesis

Řadová, Marie

January 2013

(v anglickém jazyce) Development of tooth primordia in mice is an important model for study of odontogenesis. Several dental rudiments develop during the mouse embryogenesis. These structures develop in functional teeth in their phylogenetically older relatives. Similarly, we can initiate growth of teeth from these germs in some mutant mice. In my diploma thesis we have focused on the importance of rudimentary structures with odontogenic potential in postnatal individuals. As a model of development, we have chosen a cell population originating from rudimentary primordia MS (mesial segment) that develops in diastema of the lower jaw during the embryonic day 12.5. Using the inducible Cre-lox technology we have marked the cells which are part of the signal domain of primordia at this time. As a marker of these cells we have used gene Shh. We have found out that these cells persist prenataly and also postnatally. Further we have isolated this cell area and we have tested it using a variety of methods. We have shown that in the cells of postnatal individual are expressed markers of stem cells (Sox2, Bmi1, Gli1) and also genes for major enamel matrix structural proteins: ameloblastin and amelogenin. The same stem cell markers are also expressed in vitro culture of the isolated cells. This cell population...

Validation de la fonctionnalité des continuités écologiques en milieu urbain : approches plurispécifiques et multi-sites / Validation of the green infrastructure functionnality in urban landscape : multi-species and multi-sites approaches

Balbi, Manon

30 November 2017

Le maintien de la connectivité à travers les paysages urbains, par nature très fragmentés, est un enjeu majeur de conservation de la biodiversité urbaine. On observe une prise en compte croissante de la connectivité dans les politiques d’aménagement du territoire, notamment avec l’établissement de la trame verte et bleue. De multiples outils cartographiques permettent de mettre en évidence les continuités écologiques (zones de forte connectivité), mais leur validation fonctionnelle fait souvent défaut. L’objectif de cette thèse est de valider les prédictions d’un modèle de chemin de moindre coût, sur plusieurs villes et avec différents modèles biologiques. Les espèces étudiées présentent différents modes et capacités de dispersion (vol, marche, reptation) et des exigences écologiques spécifiques (préférences pour les milieux herbacés ou boisés). Des protocoles de validation basés sur l’écologie du mouvement et la génétique du paysage sont appliqués, dans un souci de réplication (au sein de plusieurs villes) et de contrôle de la variabilité inter-individuelle. Nos résultats montrent des mouvements accrus au sein des continuités écologiques comparés à ceux observés en contextes paysagers prédits comme non connectés : les hérissons transloqués s’y déplacent sur des distances plus longues, plusieurs passereaux répondent à la repasse de chant sur de plus longues distances et les papillons de nuit montrent des taux de recapture beaucoup plus élevés. Par ailleurs, les analyses indirectes réalisées sur l’escargot petit-gris montrent une relation assez faible entre la différenciation génétique des populations et les modèles de connectivité. Ce travail fournit des arguments scientifiques pour soutenir la mise en place de continuités écologiques en milieu urbain. / Maintaining connectivity across urban landscape, intrinsically fragmented, is a major issue of urban biodiversity conservation. Connectivity is increasingly taken into account by policy and stakeholders, especially through the establishment of the blue-green infrastructure. Multiple mapping tools allow to detect ecological networks (highly connected areas), however their functionnal validation is often lacking. The objective of this study is to validate least cost path analysis predictions in several cities with different biological models. Studied species vary in terms of dispersal means and capacities (flight, walk, crawling) and habitat requirement (e.g. herbaceous or forested habitats). Several protocols based on movement ecology and landscape genetic are applied, focusing on replication (within and among cities) and control of inter-individual variability. Our results indicate that movement is increased in predicted ecological networks when compared with areas predicted as poorly connected: the translocated hedgehogs travelled longer distances, several passerine responded to song playback over longer distances, and moths showed increased recapture rates. Indirect analysis on the garden snail showed a weak relation between population genetic differentiation and connectivity models. This work provides scientific support for the establishment of ecological networks in urban landscapes.

Connectivité

Paysage urbain

Mouvement

Génétique du paysage

Chemin de moindre coût

Hérisson

Oiseau

Papillon

Escargot

Connectivity

Urban landscape

Movement

Landscape genetic

Least cost path

Hedgehog

Bird

Moth

Snail

Quantitative Analysis of Hedgehog Gradient Formation Using an Inducible Expression System: a Dissertation

Su, Vivian F.

16 November 2006

The Hedgehog (Hh) family of proteins are secreted growth factors that play an essential role in the embryonic development of all organisms and the main components in the pathway are conserved from insects to humans. These proteins affect patterning and morphogenesis of multiple tissues. Therefore, mutations in the Hh pathway can result in a wide range of developmental defects and oncogenic diseases. Because the main components in the pathway are conserved from insects to humans, Drosophilahas been shown to provide a genetically tractable system to gain insight into the processes that Hh is involved in. In this study, the roles of Hh cholesterol modification and endocytosis during gradient fonnation are explored in the Drosophila larval wing imaginal disc. To exclude the possibility of looking at a redistribution of preexisting Hh instead of Hh movement, a spatially and temporally regulated system has been developed to induce Hh expression. Functional Hh-GFP with and without the cholesterol-modification was expressed in a wild-type or shi-tslendocytosis mutant background. The Gal80 system was used to temporally express (pulse) the Hh-GFP transgenes to look at the rate of Hh gradient formation over time and determine whether this process was affected by cholesterol modification and/or endocytosis. Hh with and without cholesterol were both largely detected in punctate structures and the spreading of the different forms of Hh was quantified by measuring distances of these particles from the expressing cells. Hh without cholesterol showed a greater range of distribution, but a lower percentage of particles near the source. Loss of endocytosis blocked formation of intracellular Hh particles, but did not dramatically alter its movement to target cells. Staining for Hh, its receptor Ptc and cortical actin revealed that these punctate structures could be classified into four types of Hh containing particles: cytoplasmic with and without Ptc, and cell surface with and without Ptc. Cholesterol is specifically required for the formation of cytoplasmic particles lacking Ptc. While previous studies have shown discrepancies in the localization of Hh following a block in endocytosis, Hh with and without cholesterol is detected at both apical and basolateral surfaces, but not at basal surfaces. In the absence of cholesterol and endocytosis, Hh particles can be observed in the extracellular space. Through three-dimensional reconstruction and quantitative analysis, this study concludes that the cholesterol modification is required to restrict Hh movement. In addition, the cholesterol modification promotes Ptc-independent internalization. This study also observes that Dynamin-dependent endocytosis is necessary for internalization but does not play an essential role in Hh distribution. The data in this thesis supports the model in which Hh movement occurs via planar diffusion.

Hedgehog Proteins

Drosophila melanogaster

Drosophila Proteins

Cholesterol

Body Patterning

Embryonic and Fetal Development

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Embryonic Structures

Genetic Phenomena

Lipids

Polycyclic Compounds

Tissues

Dissecting Signaling Pathways that Regulate Axonal Guidance Effects of Sonic Hedgehog: A Dissertation

Guo, Daorong

24 March 2011

During development, axons respond to a variety of guidance cues in the environment to navigate to the proper targets. Sonic hedgehog (Shh), a classical morphogen, has been shown to function as a guidance factor that directly acts on the growth cones of various types of axons. We previously found that Shh affects retinal ganglion cell (RGC) axonal growth and navigation in a concentration-dependent manner. However, the signaling pathways that mediate such events are still unclear. In this thesis, we show that high concentrations of Shh induce growth cone collapse and repulsive turning of the chick RGC through rapid increase of Ca2+ in the growth cone, and specific activation of PKCα and Rho signaling pathways. We further found that integrin linked kinase (ILK) acts as an immediate downstream effector of PKCα. PKCα directly phosphorylates ILK in vitro at two previously unidentified sites threonine-173 and -181. Inhibition of PKCα, Rho, and ILK by pharmacological inhibitors and/or dominant-negative approaches abolished the negative effects of high-concentration of Shh. We provide evidence that Rho likely functions downstream of PKC and suggest that PKC, Rho and ILK may cooperatively mediate the negative effects of high concentrations of Shh. Furthermore, retroviral expression of dominant-negative constructs of PKCα (DN-PKCα) and ILK-double mutants (ILK-DM) resulted in misguidance of RGC axons at the optic chiasm in vivo. These results demonstrate that new signaling pathways composed of PKCα, Rho, and ILK play an important role in Shh-induced axonal chemorepulsion. In contrast, we show that attractive axonal turning in response to low concentrations of Shh is independent of PKCα, but requires the activity of cyclic nucleotides cAMP. Taken together, our results suggest that the opposing effects of Shh on axon guidance are mediated by different signaling pathways.

Hedgehog Proteins

Axons

Retinal Ganglion Cells

Amino Acids, Peptides, and Proteins

Cell and Developmental Biology

Cells

Enzymes and Coenzymes

Sense Organs

Deformation heterogeneity radiomics to predict molecular sub-types and overall survival in pediatric Medulloblastoma.

Iyer , Sukanya Raj

01 June 2020

No description available.

Biomedical Engineering

Medulloblastoma

Molecular sub-typing

Wingless

Sonic Hedgehog

Group 3

Group 4

Radiomics

Deformation

Brain

Machine Learning

Cancer

Image analysis

Survival

Prognosis

Diagnosis

Adult Medulloblastoma: Updates on Current Management and Future Perspectives

Franceschi, Enrico, Giannini, Caterina, Furtner, Julia, Pajtler, Kristian W., Asioli, Sofia, Guzman, Raphael, Seidel, Clemens, Gatto, Lidia, Hau, Peter

02 November 2023

Medulloblastoma (MB) is a malignant embryonal tumor of the posterior fossa belonging to the family of primitive neuro-ectodermic tumors (PNET). MB generally occurs in pediatric age, but in 14–30% of cases, it affects the adults, mostly below the age of 40, with an incidence of 0.6 per million per year, representing about 0.4–1% of tumors of the nervous system in adults. Unlike pediatric MB, robust prospective trials are scarce for the post-puberal population, due to the low incidence of MB in adolescent and young adults. Thus, current MB treatments for older patients are largely extrapolated from the pediatric experience, but the transferability and applicability of these paradigms to adults remain an open question. Adult MB is distinct from MB in children from a molecular and clinical perspective. Here, we review the management of adult MB, reporting the recent published literature focusing on the effectiveness of upfront chemotherapy, the development of targeted therapies, and the potential role of a reduced dose of radiotherapy in treating this disease.

info:eu-repo/classification/ddc/610

ddc:610

Hepatic Hedgehog Signaling Participates in the Crosstalk between Liver and Adipose Tissue in Mice by Regulating FGF21

Ott, Fritzi, Körner, Christiane, Werner, Kim, Gericke, Martin, Liebscher, Ines, Lobsien, Donald, Radrezza, Silvia, Shevchenko, Andrej, Hofmann, Ute, Kratzsch, Jürgen, Gebhardt, Rolf, Berg, Thomas, Matz-Soja, Madlen

09 October 2023

The Hedgehog signaling pathway regulates many processes during embryogenesis and the homeostasis of adult organs. Recent data suggest that central metabolic processes and signaling cascades in the liver are controlled by the Hedgehog pathway and that changes in hepatic Hedgehog activity also affect peripheral tissues, such as the reproductive organs in females. Here, we show that hepatocyte-specific deletion of the Hedgehog pathway is associated with the dramatic expansion of adipose tissue in mice, the overall phenotype of which does not correspond to the classical outcome of insulin resistance-associated diabetes type 2 obesity. Rather, we show that alterations in the Hedgehog signaling pathway in the liver lead to a metabolic phenotype that is resembling metabolically healthy obesity. Mechanistically, we identified an indirect influence on the hepatic secretion of the fibroblast growth factor 21, which is regulated by a series of signaling cascades that are directly transcriptionally linked to the activity of the Hedgehog transcription factor GLI1. The results of this study impressively show that the metabolic balance of the entire organism is maintained via the activity of morphogenic signaling pathways, such as the Hedgehog cascade. Obviously, several pathways are orchestrated to facilitate liver metabolic status to peripheral organs, such as adipose tissue.

info:eu-repo/classification/ddc/570

ddc:570