The role of hedgehog signalling in tumorigenesis

It has long been known from work in both Drosophila and vertebrate systems that the hedgehog signalling pathway is pivotal to embryonic development, but the past 5 years has seen an increase in our understanding of how members of this pathway are crucial to the processes of tumorigenesis. This important link was firmly established with the discovery that mutations in the gene encoding the hedgehog receptor molecule patched are responsible for both familial and sporadic forms of basal cell carcinoma (BCC), as well as a number of other tumour types. It is now known that a number of key members of the hedgehog cascade are involved in tumorigenesis, and dysregulation of this pathway appears to be a key element in the aetiology of a range of tumours. (C) 2001 Elsevier Science Ireland Ltd. All rights reserved.

Novel genes regulated by Sonic Hedgehog in pluripotent mesenchymal cells

Sonic Hedgehog is a secreted morphogen involved in patterning a wide range of structures in the developing embryo. Disruption of the Hedgehog signalling cascade leads to a number of developmental disorders and plays a key role in the formation of a range of human cancers. The identification of genes regulated by Hedgehog is crucial to understanding how disruption of this pathway leads to neoplastic transformation. We have used a Sonic Hedgehog (Shh) responsive mouse cell line, C3H/10T1/2, to provide a model system for hedgehog target gene discovery. Following activation of cell cultures with Shh, RNA was used to interrogate microarrays to investigate downstream transcriptional consequences of hedgehog stimulation. As a result 11 target genes have been identified, seven of which are induced (Thrombomodulin, GILZ, BF-2, Nr4a1, IGF2, PMP22, LASP1) and four of which are repressed (SFRP-1, SFRP-2, Mip1-gamma, Amh) by Shh. These targets have a diverse range of putative functions and include transcriptional regulators and molecules known to be involved in regulating cell growth or apoptosis. The corroboration of genes previously implicated in hedgehog signalling, along with the finding of novel targets, demonstrates both the validity and power of the C3H/10T1/2 system for Shh target gene discovery.

Rab23, a negative regulator of hedgehog signaling, localizes to the plasma membrane and the endocytic pathway

The regulation of hedgehog signaling by vesicular trafficking was exemplified by the finding that Rab23, a Rab-GTPase vesicular transport protein, is mutated in open brain mice. In this study, the localization of Rab23 was analyzed by light and immunoelectron microscopy after expression of wild-type (Rab23-GFP), constitutively active Rab23 (Rab23Q68L-GFP), and inactive Rab23 (Rab23S23N-GFP) in a range of mammalian cell types. Rab23-GFP and Rab23Q68L-GFP were predominantly localized to the plasma membrane but were also associated with intracellular vesicular structures, whereas Rab23S23N-GFP was predominantly cytosolic. Vesicular Rab23-GFP colocalized with Rab5Q79L and internalized transferrin-biotin, but not with a marker of the late endosome or the Golgi complex. To investigate Rab23 with respect to members of the hedgehog signaling pathway, Rab23-GFP was coexpressed with either patched or smoothened. Patched colocalized with intracellular Rab23-GFP but smoothened did not. Analysis of patched distribution by light and immunoelectron microscopy revealed it is primarily localized to endosomal elements, including transferrin receptor-positive early endosomes and putative endosome carrier vesicles and, to a lesser extent, with LBPA-positive late endosomes, but was excluded from the plasma membrane. Neither patched or smoothened distribution was altered in the presence of wild-type nor mutant Rab23-GFP, suggesting that despite the endosomal colocalization of Rab23 and patched, it is likely that Rab23 acts more distally in regulating hedgehog signaling.

The role of Hedgehog signaling during zebrafish larvae fin fold regeneration

Several studies have demonstrated that although the structure of the adult and larval zebrafish caudal fin is different, there are similarities at the cellular and molecular level that turn larval zebrafish fin fold a useful model to study the basic principles of regeneration. In this process, while the essential role for Hedgehog (Hh) signaling is well established in the adult zebrafish caudal fin system, its involvement in juvenile tissue regeneration is still unknown. The aim of this Master thesis was therefore to evaluate the contribution of the Hh signaling pathway to the larval zebrafish fin fold regeneration process. Accordingly, we analyzed the expression of several Hh signaling components through in situ hybridization. Here, we showed that several of these genes are effectively expressed in the larval regenerating fin tissue, suggesting a role for Hh signaling also during larval regeneration. However, divergence in the regulation of few Hh signaling components appears to exist between the adult and larval zebrafish fin regeneration processes. Nevertheless, similarly to adult caudal fin regeneration, when Hh signaling was blocked, by using cyclopamine, the larval fin fold regenerative outgrowth is severely impaired. Since larval zebrafish fin fold is ciliated, and primary cilia are closely related to Hh signaling regulation in vertebrate systems, we further addressed the role of primary cilia during larval fin fold regeneration process. To this end, we used the zebrafish iguana mutant, in which primary cilia are not formed, to study the modulation of Hh signaling expression during larval fin fold regeneration in the absence of primary cilia. Here, we found that several genes were expressed with a delay, coincident with the delay in the mutant fin fold regeneration observed in previous work. We show that Hh signaling in the fin fold is crucial to promote cell proliferation. When Hh signaling is blocked using cyclopamine there is a strong blockage of cell proliferation and regeneration is also blocked. Surprisingly, in iguana mutants where Hh signaling is impaired but not totally blocked, cell proliferation is not detected but regeneration still occurs. This raises the question about the requirement of cell proliferation in larvae fin fold regeneration. By blocking the cell cycle using aphidicolin we demonstrate that cell proliferation is not necessary for zebrafish larvae fin fold regeneration.

Primary cilia and the regulation of hedgehog signaling: link to cardiac development

RESUMO: As células eucarióticas evoluíram um sistema de sinalização complexo que lhes permite responder aos sinais extracelulares e intracelulares. Desta forma, as vias de sinalização são essenciais para a sobrevivência da célula e do organismo, uma vez que regulam processos fundamentais, tais como o desenvolvimento, o crescimento, a imunidade, e a homeostase dos tecidos. A via de transdução de sinal Hedgehog (Hh) envolve o receptor Patched1 (Ptch1), que tem um efeito inibidor sobre a proteína Smoothened (Smo) na ausência dos seus ligandos, as proteínas Sonic hedgehog (Shh). Estas proteínas são reguladores fundamentais do desenvolvimento embrionário, como ilustrado pelas malformações drásticas observadas em embriões humanos e de murganho com perturbações da transdução de sinal da via Hh e que incluem polidactilia, defeitos craniofaciais e malformações ósseas. Igualmente importantes são as consequências da ativação inapropriada da via de sinalização Hh na formação de tumores. Curiosamente, os componentes desta via localizam-se nos cílios primários. Além disso, demonstrou-se que esta localização é crucial para a sinalização através da via Hh. Na presença dos ligandos, Ptch1 é internalizado e destinado a degradação ou sequestrado num compartimento da célula de onde não pode desempenhar o seu papel inibitório. A proteína Arl13b é uma pequena GTPase pertencente à família Arf/Arl da superfamília Ras de pequenas GTPases e foi implicada no síndrome de Joubert, uma ciliopatia caracterizada por ataxia congénita cerebelar, hipotonia, atrso mental e cardiopatia congénita. Murganhos deficientes para Arl13b, chamado hennin (hnn) morrem morrem prematuramente ao dia 13,5 de gestação (E13,5) e exibem anomalias morfológicas nos cílios que levam à interrupção da sinalização Hh. Além disso, a Arl13b está diretamente envolvida na regulação da via Hh, controlando a localização de vários componentes desta via nos cílios primários. Neste trabalho, mostramos que a Arl13b se localiza em circular dorsal ruffles (CDRs), que são estruturas de actina envolvidas em macropinocitose e internalização de recetores, e que regula a sua formação. Além disso, aprofundámos o conhecimento do processo de ativação da via de sinalização Hh, mostrando que as CDRs sequestram seletivamente e internalizam o recetor Ptch1. As CDRs formam-se minutos após ativação da via por ligandos Shh ou pelo agonista de Smo SAG e continuam a ser formadas a partir daí, sugerindo uma indução contínua da reorganização do citoesqueleto de actina quando a via está ativada. Observámos ainda que a inibição da formação de CDRs através do silenciamento de WAVE1, uma proteína necessária para a formação destas estruturas, resulta na diminuição da ativação da via de sinalização Hh. Além disso, o bloqueio da macropinocitose, que se segue ao fecho das CDRs, através do silenciamento de uma proteína necessária para a cisão de macropinossomas, nomeadamente a proteína BARS, tem um efeito semelhante. Estes resultados sugerem que as CDRs e a macropinocitose são necessárias para a ativação da via de sinalização Hh e indicam que esta via de internalização controla os níveis de sinal Hh. Durante o desenvolvimento, as células proliferativas dependem do cílio primário para a transdução de várias vias de sinalização. A via Hh induz a diferenciação do músculo cardíaco. Por conseguinte, os murganhos deficientes na via de sinalização Hh exibem uma variedade de defeitos de lateralidade, incluindo alteração do looping do coração, como pode ser visto em murganhos deficientes para Arl13b. Por conseguinte, investigámos o papel da Arl13b no desenvolvimento do coração. Mostramos que a Arl13b é altamente expressa no coração de embriões de murganho e de murganhos adultos ao nível do mRNA e da proteína. Além disso, o perfil de distribuição da Arl13b no coração segue o dos cílios primários, que são essenciais para o desenvolvimento cardíaco. Corações de murganhos hnn no estadio E12,5 mostram um canal átrio-ventricular aberto, espessamento da camada compacta ventricular e aumento do índice mitótico no ventrículo esquerdo. Além disso, um atraso de 1 a 2 dias no desenvolvimento é observado em corações de murganhos hnn, quando comparados com controlos selvagens no estadio E13,5. Assim, estes resultados sugerem que a Arl13b é necessária para o desenvolvimento embrionário do coração e que defeitos cardíacos podem contribuir para a letalidade embrionária de murganhos hnn. Em suma, foi estabelecido um novo mecanismo para a regulação dos níveis de superfície do recetor Ptch1, que envolve a remodelação do citoesqueleto de actina e a formação de CDRs após a ativação da via de sinalização Hh. Este mecanismo permite um feedback negativo que evita a repressão excessiva da via através da remoção de Ptch1 da superfície da célula. Além disso, determinou-se que uma mutação de perda de função na Arl13b causa defeitos cardíacos durante o desenvolvimento, possivelmente relacionados com a associação dos defeitos em cílios primários e na sinalização Hh, existentes em murganhos deficientes para Arl13b. A via de sinalização Hh tem tido um papel central entre as vias de sinalização, uma vez que a sua regulação é crucial para o funcionamento apropriada da célula. Assim, a descoberta de um novo mecanismo de tráfego através de macropinocitose e CDRs que controla a ativação e repressão da via de sinalização Hh traz novas perspetivas de como esta via pode ser regulada e pode ainda conduzir à identificação de novos alvos e estratégias terapêuticas. --------------------ABSTRACT: Eukaryotic cells have evolved a complex signaling system that allows them to respond to extracellular and intracellular cues. Signaling pathways are essential for cell and organism survival, since they regulate fundamental processes such as development, growth, immunity, and tissue homeostasis. The Hedgehog (Hh) pathway of signal transduction involves the receptor Patched1 (Ptch1), which has an inhibitory effect on Smoothened (Smo) in the absence of its ligands, the Sonic hedgehog (Shh) proteins. These proteins are fundamental regulators of embryonic development, as illustrated by the dramatic malformations seen in human and mouse embryos with perturbed Hh signal transduction that include polydactyly, craniofacial defects and skeletal malformations. Equally important are the consequences of inappropriate activation of the Hh signaling response in tumor formation. Interestingly, the components of this pathway localize to primary cilia. Moreover, it has been shown that this localization is crucial for Hh signaling. However, in the presence of the ligands, Ptch1 is internalized and destined for degradation or sequestered in a cell compartment where it no longer can play its inhibitory role. ADP-ribosylation factor-like (Arl) 13b, a small GTPase belonging to Arf/Arl family of the Ras superfamily of small GTPases has been implicated in Joubert syndrome, a ciliopathy characterized by congenital cerebellar ataxia, hypotonia, intellectual disability and congenital heart disease. Arl13b-deficient mice, called hennin (hnn) die at embryonic day 13.5 (E13.5) and display morphological abnormalities in primary cilia that lead to the disruption of Hh signaling. Furthermore, Arl13b is directly involved in the regulation of Hh signaling by controlling the localization of several components of this pathway to primary cilia. Here, we show that Arl13b localizes to and regulates the formation of circular dorsal rufles (CDRs), which are actin-basedstructures known to be involved in macropinocytosis and receptor internalization. Additionally, we extended the knowledge of the Hh signaling activation process by showing that CDRs selectively sequester and internalize Ptch1 receptors. CDRs are formed minutes after Hh activation by Shh ligands or the Smo agonist SAG and keep being formed thereafter, suggesting a continuous induction of actin reorganization when the pathway is switched on. Importantly, we observed that disruption of CDRs by silencing WAVE1, a protein required for CDR formation, results in down-regulation of Hh signaling activation. Moreover, the blockade of macropinocytosis, which follows CDR closure, through silencing of a protein necessary for the fission of macropinosomes, namely BARS has a similar effect. These results suggest that CDRs and macropinocytosis are necessary for activation of Hh signaling and indicate that this pathway of internalization controls Hh signal levels. During development, proliferating cells rely on the primary cilium for the transduction of several signaling pathways. Hh induces the differentiation of cardiac muscle. Accordingly, Hh-deficient mice display a variety of laterality defects, including alteration of heart looping, as seen in Arl13b-deficient mice. Therefore, we investigated the role of Arl13b in heart development. We show that Arl13b is highly expressed in the heart of both embryonic and adult mice at mRNA and protein levels. Also, Arl13b localization profile mimics that of primary cilia, which have been shown to be essential to early heart development. E12.5 hnn hearts show an open atrioventricular channel, increased thickening of the ventricular compact layer and increased mitotic index in the left ventricle. Moreover, a delay of 1 to 2 days in development is observed in hnn hearts, when compared to wild-type controls at E13.5. Hence, these results suggest that Arl13b is necessary for embryonic heart development and that cardiac defects might contribute to the embryonic lethality of hnn mice. Altogether, we established a novel mechanism for the regulation of Ptch1 surface levels, involving cytoskeleton remodeling and CDR formation upon Hh signaling activation. This mechanism allows a negative feedback loop that prevents excessive repression of the pathway by removing Ptch1 from the cell surface. Additionally, we determined that the Arl13b loss-offunction mutation causes cardiac defects during development, possibly related to the associated ciliary and Hh signaling defects found in Arl13b-deficient mice. Hh signaling has taken a center stage among the signaling pathways since its regulation is crucial for the appropriate output and function of the cell. Hence, the finding of a novel trafficking mechanism through CDRs and macropinocytosis that controls Hh signaling activation and repression brings new insights to how this pathway can be regulated and can lead to the discovery of novel therapeutic targets and strategies.

Hedgehog signaling governs the development of otic sensory epithelium and its associated innervation in zebrafish

The inner ear is responsible for the perception of motion and sound in vertebrates. Its functional unit, the sensory patch, contains mechanosensory hair cells innervated by sensory neurons from the statoacoustic ganglion (SAG) that project to the corresponding nuclei in the brainstem. How hair cells develop at specific positions, and how otic neurons are sorted to specifically innervate each endorgan and to convey the extracted information to the hindbrain is not completely understood. In this work, we study the generation of macular sensory patches and investigate the role of Hedgehog (Hh) signaling in the production of their neurosensory elements. Using zebrafish transgenic lines to visualize the dynamics of hair cell and neuron production, we show that the development of the anterior and posterior maculae is asynchronic, suggesting they are independently regulated. Tracing experiments demonstrate the SAG is topologically organized in two different neuronal subpopulations, which are spatially segregated and innervate specifically each macula. Functional experiments identify the Hh pathway as crucial in coordinating the production of hair cells in the posterior macula, and the formation of its specific innervation. Finally, gene expression analyses suggest that Hh influences the balance between different SAG neuronal subpopulations. These results lead to a model in which Hh orients functionally the development of inner ear towards an auditory fate in all vertebrate species.

PPARbeta/delta regulates paneth cell differentiation via controlling the hedgehog signaling pathway.

BACKGROUND & AIMS: All 4 differentiated epithelial cell types found in the intestinal epithelium derive from the intestinal epithelial stem cells present in the crypt unit, in a process whose molecular clues are intensely scrutinized. Peroxisome proliferator-activated receptor beta (PPARbeta) is a nuclear hormone receptor activated by fatty acids and is highly expressed in the digestive tract. However, its function in intestinal epithelium homeostasis is understood poorly. METHODS: To assess the role of PPARbeta in the small intestinal epithelium, we combined various cellular and molecular approaches in wild-type and PPARbeta-mutant mice. RESULTS: We show that the expression of PPARbeta is particularly remarkable at the bottom of the crypt of the small intestine where Paneth cells reside. These cells, which have an important role in the innate immunity, are strikingly affected in PPARbeta-null mice. We then show that Indian hedgehog (Ihh) is a signal sent by mature Paneth cells to their precursors, negatively regulating their differentiation. Importantly, PPARbeta acts on Paneth cell homeostasis by down-regulating the expression of Ihh, an effect that can be mimicked by cyclopamine, a known inhibitor of the hedgehog signaling pathway. CONCLUSIONS: We unraveled the Ihh-dependent regulatory loop that controls mature Paneth cell homeostasis and its modulation by PPARbeta. PPARbeta currently is being assessed as a drug target for metabolic diseases; these results reveal some important clues with respect to the signals controlling epithelial cell fate in the small intestine.

Structure of the ovaries of the Nimba otter shrew, Micropotamogale lamottei, and the Madagascar hedgehog tenrec, Echinops telfairi.

The otter shrews are members of the subfamily Potamogalinae within the family Tenrecidae. No description of the ovaries of any member of this subfamily has been published previously. The lesser hedgehog tenrec, Echinops telfairi, is a member of the subfamily Tenrecinae of the same family and, although its ovaries have not been described, other members of this subfamily have been shown to have ovaries with non-antral follicles. Examination of these two species illustrated that non-antral follicles were characteristic of the ovaries of both species, as was clefting and lobulation of the ovaries. Juvenile otter shrews range from those with only small follicles in the cortex to those with 300- to 400-microm follicles similar to those seen in non-pregnant and pregnant adults. As in other species, most of the growth of the oocyte occurred when follicles had one to two layers of granulosa cells. When larger follicles became atretic in the Nimba otter shrew, hypertrophy of the theca interna produced nodules of glandular interstitial tissue. In the tenrec, the hypertrophying theca interna cells in most large follicles appeared to undergo degeneration. Both species had some follicular fluid in the intercellular spaces between the more peripheral granulosa cells. It is suggested that this fluid could aid in separation of the cumulus from the remaining granulosa at ovulation. The protruding follicles in lobules and absence of a tunica albuginea might also facilitate ovulation of non-antral follicles. Ovaries with a thin-absent tunica albuginea and follicles with small-absent antra are widespread within both the Eulipotyphla and in the Afrosoricida, suggesting that such features may represent a primitive condition in ovarian development. Lobulated and deeply crypted ovaries are found in both groups but are not as common in the Eulipotyphla making inclusion of this feature as primitive more speculative.

Comparative genomics of Hedgehog loci in chordates and the origin of Shh regulatory novelties

The origin and evolution of the complex regulatory landscapes of some vertebrate developmental genes, often spanning hundreds of Kbp and including neighboring genes, remain poorly understood. The Sonic Hedgehog (Shh) genomic regulatory block (GRB) is one of the best functionally characterized examples, with several discrete enhancers reported within its introns, vast upstream gene-free region and neighboring genes (Lmbr1 and Rnf32). To investigate the origin and evolution of this GRB, we sequenced and characterized the Hedgehog (Hh) loci from three invertebrate chordate amphioxus species, which share several early expression domains with Shh. Using phylogenetic footprinting within and between chordate lineages, and reporter assays in zebrafish probing >30 Kbp of amphioxus Hh, we report large sequence and functional divergence between both groups. In addition, we show that the linkage of Shh to Lmbr1 and Rnf32, necessary for the unique gnatostomate-specific Shh limb expression, is a vertebrate novelty occurred between the two whole-genome duplications.

Étude des mécanismes moléculaires induits par Sonic hedgehog lors du guidage axonal des neurones commissuraux de la moelle épinière

Le morphogène Sonic hedgehog (Shh) est requis pour le guidage axonal des neurones commissuraux lors du développement de la moelle épinière, phénomène impliquant des événements de réorganisation du cytosquelette d’actine. Bien qu’il soit généralement admis que le cytosquelette d’actine soit régulé via les petites GTPases de la famille Rho, un effet de Shh sur ces protéines n’a jamais été observé dans aucun contexte physiologique. Nous démontrons que Shh active les petites GTPases Rac1 et Cdc42 et que cette activation est rapide et donc, compatible avec les effets de guidage induits par Shh sur les neurones commissuraux. En parallèle, nous avons étudié l’activation de la protéine Boc, qui est un récepteur de Shh requis pour le guidage axonal des neurones commissuraux. Ces résultats contribuent à raffiner notre compréhension de la transduction cellulaire induite par Shh lors du guidage axonal des neurones commissuraux.

The importance of the Hedgehog signaling pathway at the level of the blood-brain barrier

La barrière hémato-encéphalique (BHE) protège le système nerveux central (SNC) en contrôlant le passage des substances sanguines et des cellules immunitaires. La BHE est formée de cellules endothéliales liées ensemble par des jonctions serrées et ses fonctions sont maintenues par des astrocytes, celles ci sécrétant un nombre de facteurs essentiels. Une analyse protéomique de radeaux lipidiques de cellules endothéliales de la BHE humaine a identifié la présence de la voie de signalisation Hedgehog (Hh), une voie souvent liées à des processus de développement embryologique ainsi qu’au niveau des tissus adultes. Suite à nos expériences, j’ai déterminé que les astrocytes produisent et secrètent le ligand Sonic Hh (Shh) et que les cellules endothéliales humaines en cultures primaires expriment le récepteur Patched (Ptch)-1, le co-récepteur Smoothened (Smo) et le facteur de transcription Gli-1. De plus, l’activation de la voie Hh augmente l’étanchéité des cellules endothéliales de la BHE in vitro. Le blocage de l’activation de la voie Hh en utilisant l’antagoniste cyclopamine ainsi qu’en utilisant des souris Shh déficientes (-/-) diminue l’expression des protéines de jonctions serrées, claudin-5, occcludin, et ZO-1. La voie de signalisation s’est aussi montrée comme étant immunomodulatoire, puisque l’activation de la voie dans les cellules endothéliales de la BHE diminue l’expression de surface des molécules d’adhésion ICAM-1 et VCAM-1, ainsi que la sécrétion des chimiokines pro-inflammatoires IL-8/CXCL8 et MCP-1/CCL2, créant une diminution de la migration des lymphocytes CD4+ à travers une monocouche de cellules endothéliales de la BHE. Des traitements avec des cytokines pro-inflammatoires TNF-α and IFN-γ in vitro, augmente la production de Shh par les astrocytes ainsi que l’expression de surface de Ptch-1 et de Smo. Dans des lésions actives de la sclérose en plaques (SEP), où la BHE est plus perméable, les astrocytes hypertrophiques augmentent leur expression de Shh. Par contre, les cellules endothéliales de la BHE n’augmentent pas leur expression de Ptch-1 ou Smo, suggérant une dysfonction dans la voie de signalisation Hh. Ces résultats montrent que la voie de signalisation Hh promeut les propriétés de la BHE, et qu’un environnement d’inflammation pourrait potentiellement dérégler la BHE en affectant la voie de signalisation Hh des cellules endothéliales.