Role of the Hedgehog receptor Patched1 in the development and function of T lymphocytes

Michel, Kai-David

05 June 2013

No description available.

570

Hedgehog

Patched1

T cells

Biologie (PPN619462639)

Investigating Tom1 as a Candidate Regulator of Ptch1

Crawford, Michelle Audrey

03 December 2012

Sonic hedgehog (Shh) is a signaling molecule that is involved in patterning the embryo and regulates adult stem cell homeostasis. Patched1 (Ptch1) is the receptor for Shh and upon binding to Shh is endocytosed, allowing downstream signaling to occur. Ptch1 is critical to the cellular response to Shh because it is both a negative regulator of the Shh signaling pathway and a transcriptional target of the pathway. Therefore, the regulation of Ptch1 levels will directly affect the ability of cells to respond to Shh. Understanding this process requires the characterization of novel Ptch1-interacting proteins that regulate Ptch1 levels in the cell. This thesis investigated a role for the adapter protein Tom1 as a putative Ptch1-interacting protein involved in regulating Ptch1 levels through endocytic cycling. It was found that Tom1 overexpression did not regulate the patterning of vertebrate nervous system, but did play a role the sub-cellular localization of Ptch1.

Developmental biology

Neuroscience

Sonic hedgehog

Patched1

Tom1

Contribution of Patched1 and the Sonic Hedgehog Pathway to Vertebrate Limb Development

Natalie Butterfield

Unknown Date

No description available.

Molecular mechanisms of choroid fissure closure and ventral retina formation in the zebrafish eye

Lee, Jiwoon

10 February 2011

During optic cup morphogenesis, the neuroectodermal layers of the optic vesicle (OV) invaginate ventrally, and fuse at the choroid fissure (CF) along the proximo-distal axis such that the retina and retinal pigment epithelium (RPE) are confined within the cup. Failure of CF closure results in colobomas, which are characterized by the persistence of a cleft or hole at the back of the eye. While CF closure is a critical aspect of ocular development, the molecular and cellular mechanisms underlying this process are poorly understood. My research examined CF closure and colobomas using zebrafish as a model system. In the first study, I determined that early cell fate changes within the eye field could cause colobomas using the zebrafish mutant blowout. Colobomas in blowout resulted from defects in optic stalk morphogenesis whereby the optic stalk extended into the retina and impeded the edges of the CF from meeting and fusing. Positional cloning of blowout identified a nonsense mutation in patched1, a negative regulator of the Hedgehog pathway. Up-regulation of Hedgehog pathway activity causes disruption in the patterning of the OV into proximal and distal territories, revealing that cell fate determination, mediated by Hedgehog signaling, is intimately involved in regulating CF closure. In the second study, I examined Bcl6 function and regulation during zebrafish eye development. bcl6 encodes a transcriptional repressor expressed in the ventral retina during zebrafish eye development. Loss of Bcl6 function leads to colobomas along with up-regulation of p53, a previously known Bcl6 target, and an increase in the number of apoptotic cells in the retina, demonstrating that Bcl6 plays a critical role in preventing apoptosis in the retina during early eye development. I also showed that Vax1 and Vax2 act upstream of bcl6 in the ventral retina. Furthermore, I identified functional interactions between Bcl6, Bcor and Hdac1 during eye development, demonstrating that Bcl6 functions along with Bcor and Hdac1 to mediate cell survival by regulating p53 expression. Together my studies expand the gene regulatory network involved in cell fate determination and cell survival during CF closure and ventral retina formation, and provide mechanistic insight into coloboma formation. / text

Choroid fissure closure

Coloboma

Shh

Patched1

Bcl6

Zebrafish eye

Retina

Ocular development

Eye development

Role of Patched1 in Epidermal Homeostasis

Rehan Villani

Unknown Date

Abstract – The Role of Patched1 in Epidermal Homeostasis Hedgehog (Hh) signalling is a critical pathway involved in the development of many, if not all, organ systems. However the abnormal activation of Hh signalling in fully developed adult organs leads to cancer. Mutation of the Hh signal receptor, Patched1 (Ptc1), causes Naevoid Basal Cell Carcinoma Syndrome, which presents with developmental defects and cancer predisposition. The activation of Hh signalling is seen in a wide range of non-inherited cancer types also, including Medulloblastoma and Basal Cell Carcinoma (BCC) of the skin. BCC is the most common form of human cancer and over 90% of cases are linked to abnormally high Hh signalling. Hh signalling is known to regulate hair follicle morphogenesis during development and more recently has been linked to modulation of the embryonic epidermal stem cell compartment. However both the mechanisms behind this process and the mechanism behind its induction of BCC are still uncharacterised. The aim of this project was to determine the role of Ptc1 in the skin, particularly the adult stem cell compartment, and the role of Hh signalling in BCC formation. The deletion of Ptc1 specifically in the adult epidermis was enabled by the creation of a K14-Cre Recombinase induced Ptc1 Conditional (K14-Cre:Ptc1C/C) transgenic mouse line. Proliferation was increased throughout the epithelia and BCC-like lesions developed within 4 weeks of Ptc1 deletion. This indicates that Hh signalling plays a critical role in repressing cell turnover in the interfollicular epithelium (IFE) and bulge region in the adult despite being previously reported not to play a role in this area. Ptc1 deletion in the epithelia was also found to promote the IFE lineage over hair follicles and expand the expression of many proposed stem cell markers, including K15, Sox9 and p63. K14-Cre:Ptc1C/C transgenic mice also exhibited a severe growth defect, linked to low levels of Igf1 hormone in the serum. Igf1 binding protein alteration in the skin was determined to be the most likely cause and prompted the investigation of Igf axis signalling in Ptc1 deleted epidermis. Insulin-like growth factor binding protein 2 was found to localise to the bulge or stem cell region of the hair follicle, and was increased in K14-Cre:Ptc1C/C epidermis. Igfbp2 was coincident with a loss of PI3K/Akt signal translation. The majority of human BCC samples also expressed Igfbp2 at much higher levels than surrounding normal tissue indicating these results are relevant to the human BCC condition also. Interestingly Hh activation was also shown to increase p38 MAPK throughout the epidermis indicating it is a universal target of Hh signalling in the skin. In summary we have found that Hh signal activation in the epidermis promotes the bulge/stem cell and interfollicular lineages of the skin at the expense of hair follicles. Finally the modulation of PI3K/Akt signalling by Igfbp2 in the bulge is perhaps mediating the effect of Hh signalling via the promotion of the bulge lineage leading to the development of BCC.

patched1

skin

hedgehog

epidermal

homeostasis

insulin-like growth factor

tyrosine kinase

Hedgehog signalling in lung development and airway regeneration

Uda Ho

Unknown Date

Tumorigenesis is often caused by the dysregulation of developmental pathways that are activated during repair, a process that recapitulates development. The Hedgehog (Hh) pathway is a signalling pathway essential for cell patterning and identity during embryogenesis. Activation of Hh signalling has been reported in small cell lung cancer progression, but the role of the Hh receptor, Patched1 (Ptch1), remains poorly understood. Therefore, it is imperative that we understand how Ptch1 is involved in development and tissue repair in order to understand its roles in cancer. This project aimed to study the role of Ptch1 during the branching process of lung development and in the regeneration of airway epithelial cells. A conditional knockout approach was utilised to excise Ptch1 by crossing Ptch1 conditional mice with Dermo1-Cre mice (Dermo1Cre+/-;Ptch1lox/lox), thereby activating the Hh pathway in the mesenchyme, independent of ligand. Dermo1Cre+/-;Ptch1lox/lox embryos died at E12.0 and showed secondary lung branching arrest leading to lobe formation defects. Expression of Ptch1, Gli1 and Foxf1 were shown to be upregulated in both proximal and distal lung mesenchyme, indicating inappropriate pathway activation and disruption of the Hh gradient. Fgf10 expression was spatially reduced in Dermo1Cre+/-;Ptch1lox/lox lungs and the addition of Fgf10 to these lungs in culture showed partial restoration of branching, thus Hh signalling was shown to regulate branching via Fgf10. Due to the patterning defect associated with our in vivo model, we took an in vitro approach to delete Ptch1 in lung explants cultures. This also showed reduced branching and validated that mesenchymal proliferation was enhanced after Ptch1 deletion, consistent with the previously reported role of Hh signalling in mesenchymal cell survival. Small cell lung cancer originates in the proximal lung and has been linked to aberrant repair processes. Therefore, Hh signalling in proximal airway repair was investigated. Ptch1 expressing cells were detected in the bronchial epithelium and stroma during homeostasis. But these cells were not detected following polidocanol-induced injury in the murine nasal septum and lung. However during naphthalene-induced repair, Ptch1 expressing cells were detected in the regenerating bronchial epithelium, suggesting that Hh dependent progenitors respond specifically to naphthalene-induced damage and perhaps are pulmonary neuroendocrine or variant Clara cells. Therefore, this project has provided insight into how Ptch1 patterns lung branching and lobe specification during development and also highlights the importance of Ptch1 in pulmonary epithelial regeneration.

Hedgehog Signalling

patched1

Fibroblast Growth Factor

Lung Development

airway regeneration

Cell Patterning

Branching Morphogenesis

Mouse Model

polidocanol

Naphthalene