Regulators of Hedgehog Signaling in Chondrocytes: Sufu, Kif7, and Primary Cilium

Hsu, Shu-Hsuan Claire

22 August 2012

The Hedgehog (Hh) signaling pathway has received attention regarding its important role in embryonic development, however the mechanism by which pathway regulators, such as Suppressor of fused (Sufu), Kinesin family member 7 (Kif7), and primary cilium, mediate Hh signaling transduction is not entirely understood. The work presented here examines the roles of Sufu and Kif7 in regulating Hh signaling in growth plate chondrocytes, as well as how they mediate parathyroid hormone-like hormone (Pthlh) signaling during chondrocyte development. I show here that Sufu and Kif7 are essential regulators of Indian hedgehog (Ihh) signaling. While Sufu negatively regulates Gli transcription factors, Kif7 functions both positively and negatively in chondrocytes. Kif7 plays a role in Sufu protein degradation and the exclusion of Sufu-Gli complexes from the primary cilium. Importantly, halving the dosage of Sufu restores normal Hh pathway activity and chondrocyte development in Kif7-null mice, demonstrating that the positive role of Kif7 is to restrict the inhibitory function of Sufu. Furthermore, Kif7 exerts inhibitory function on Gli transcriptional activity in chondrocytes when Sufu function is absent. Therefore, Kif7 regulates the activity of Gli transcription factors through both Sufu-dependent and Sufu-independent mechanisms. I show that Sufu is crucial for mediating the negative effect of Pthlh on Gli transcriptional activity and chondrocyte hypertrophic differentiation, whereas Kif7 and primary cilium are dispensable in this process. Although primary cilium is required for Hh ligand-mediated activation of Gli transcription, Pthlh negatively controls Gli transcriptional activity in a cilia-independent manner. The results of this work provide insight into how Hh signaling is regulated by Sufu and Kif7 in the context of primary cilium, but also suggest Sufu serves as an important link between Ihh and Pthlh signaling during growth plate chondrocyte development.

Hedgehog signaling

chondrogenesis

0306

0307

0379

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)

MACROPHAGE AEBP1 CONTRIBUTES TO MAMMARY EPITHELIAL CELL HYPERPLASIA AS A NOVEL REGULATOR OF SONIC HEDGEHOG SIGNALLING

Holloway, Ryan

27 November 2012

Chronic inflammation stimulates mammary tumourigenesis by disrupting signalling interactions between the epithelial ducts and the surrounding stromal microenvironment. Adipocyte enhancer-binding protein 1 (AEBP1) promotes mammary epithelial cell hyperplasia as a stromal factor that enhances activity of the proinflammatory transcription factor Nuclear Factor-?B (NF-?B) in macrophages. Aberrant NF-?B activity in macrophages elevates production of proinflammatory signals and the ligand sonic hedgehog (Shh), a significant contributor to tumourigenesis. In this study, Shh expression was elevated in macrophages isolated from transgenic mice (AEBP1TG) that overexpress AEBP1. Transient overexpression of AEBP1 in a macrophage cell line resulted in increased Shh expression. Furthermore, hedgehog target genes Gli1 and Bmi1 were up-regulated in mammary epithelium of AEBP1TG mice and HC11 mammary epithelial cells co-cultured with AEBP1TG macrophages. Growth of HC11 cells and mammary tumours was enhanced in response to AEBP1TG macrophages. These findings suggest that macrophage AEBP1 overexpression contributes to mammary hyperplasia through enhanced hedgehog signalling.

hyperplasia

Sonic hedgehog

mammary gland

macrophage

AEBP1

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

The Role of Hedgehog-Gli Pathway Regulators in Skin Development and Tumorigenesis

Li, Zhu Juan

08 August 2013

Proper control of Hedgehog (Hh) signaling is critical for hair follicle morphogenesis and ectopic Hh pathway activity is a hallmark of basal cell carcinoma (BCC), the most common type of skin cancer. Mutations in Hh pathway components such as the Hh-binding receptor PATCHED1 (PTCH1) are frequently found in BCC. However, how Hh pathway activation disrupts normal skin homeostasis to promote BCC formation remains poorly understood. Gli2, the major mediator of Hh signaling is essential for hair follicle development and its overexpression in the epidermis induces BCC formation. Despite the importance of Gli2 in the skin, how it is regulated during skin development and tumorigenesis is unclear. Using a genetic approach with loss-of-function mouse mutants and primary keratinocyte cultures, I have uncovered the distinct and overlapping functions of Sufu and Kif7, two evolutionarily conserved regulators of the Hh pathway, during skin development and tumorigenesis. Sufu and Kif7 play opposing roles in Hh signaling through the regulation of Gli2 subcellular distribution, and Kif7 performs distinct Sufu-dependent and –independent functions. In addition, deletion of both Sufu and Kif7 in embryonic skin leads to complete loss of follicular fate and compromised epidermal differentiation. In the adult skin, inactivation of Sufu does not drive BCC formation and requires additional genetic alterations such as the loss of Kif7. Using a Ptc1 mouse model for BCC, I have identified previously unrecognized molecular pathways and cellular events involved in BCC pathogenesis. This includes, aberrant cell cycle progression, loss of cell cycle checkpoint regulation, and suppression of the p53 response. Overall my work provides critical insight into the molecular control of Hh signaling and the downstream events driving BCC formation.

Hedgehog

Gli

Basal cell carcinoma

skin

0307

The Role of Hedgehog-Gli Pathway Regulators in Skin Development and Tumorigenesis

Li, Zhu Juan

08 August 2013

Proper control of Hedgehog (Hh) signaling is critical for hair follicle morphogenesis and ectopic Hh pathway activity is a hallmark of basal cell carcinoma (BCC), the most common type of skin cancer. Mutations in Hh pathway components such as the Hh-binding receptor PATCHED1 (PTCH1) are frequently found in BCC. However, how Hh pathway activation disrupts normal skin homeostasis to promote BCC formation remains poorly understood. Gli2, the major mediator of Hh signaling is essential for hair follicle development and its overexpression in the epidermis induces BCC formation. Despite the importance of Gli2 in the skin, how it is regulated during skin development and tumorigenesis is unclear. Using a genetic approach with loss-of-function mouse mutants and primary keratinocyte cultures, I have uncovered the distinct and overlapping functions of Sufu and Kif7, two evolutionarily conserved regulators of the Hh pathway, during skin development and tumorigenesis. Sufu and Kif7 play opposing roles in Hh signaling through the regulation of Gli2 subcellular distribution, and Kif7 performs distinct Sufu-dependent and –independent functions. In addition, deletion of both Sufu and Kif7 in embryonic skin leads to complete loss of follicular fate and compromised epidermal differentiation. In the adult skin, inactivation of Sufu does not drive BCC formation and requires additional genetic alterations such as the loss of Kif7. Using a Ptc1 mouse model for BCC, I have identified previously unrecognized molecular pathways and cellular events involved in BCC pathogenesis. This includes, aberrant cell cycle progression, loss of cell cycle checkpoint regulation, and suppression of the p53 response. Overall my work provides critical insight into the molecular control of Hh signaling and the downstream events driving BCC formation.

Hedgehog

Gli

Basal cell carcinoma

skin

0307

Studies in stem cell biology and developmental pathway regulation in the pancreas and breast

O'Toole, Sandra Alison, Garvan Institute of Medical Research, Faculty of Medicine, UNSW

January 2008

Breast and pancreatic cancers are among the major causes of cancer mortality in our society. There has been a significant decline in mortality from breast cancer over the last two decades, while pancreatic cancer has an exceptionally poor prognosis. Although these malignancies have very different clinical outcomes they share the common feature that metastatic disease is almost uniformly fatal. The existence of cancer stem cells has been postulated as a major factor in tumour recurrence after traditional chemo- or radio-therapy. Addressing this important clinical question requires a deeper understanding of the biology of normal and cancer stem cells and the signalling pathways involved in their regulation. The identity of the pancreatic stem cell remains elusive. However, using a murine model of haematopoietic stem cell (HSC) transplantation I have demonstrated for the first time transdifferentiation of these bone marrow derived cells into mature pancreatic acinar cells, where they appear to contribute to cell turnover ultimately forming acini and lobules. These data show that HSC have surprising developmental plasticity and provide insight into a potential stem cell niche in the pancreas. The Hedgehog, Wnt and Notch signalling pathways play a critical role in early development and in the maintenance and self-renewal of stem cells. There is also increasing evidence that dysregulation of these pathways contributes to the development of many malignancies. There is relatively little information regarding their role in breast cancer development and progression. I used immunohistochemistry for key proteins in these pathways, sonic hedgehog, beta-catenin and Notch 1 in three substantial series of human breast lesions and determined that abnormal expression of these proteins is an early event in the development in breast cancer, and is associated with particular breast cancer subtypes, Shh and beta-catenin expression is associated predominantly with the basal-like phenotype and Notch 1 with the HER2 amplified phenotype. Overexpression of Shh in particular confers a worse clinical outcome in invasive ductal carcinoma. Furthermore, increased levels of Shh in a 3D culture model of non-transformed mammary epithelial cells resulted in disorganisation of acini and the development of an abnormal discohesive phenotype. Finally the role of Shh was investigated in a mammary epithelial transplantation model, where overexpression of Shh resulted in the development of hyperplasia of the mammary ductal epithelium. Together these data confirm that the Hedgehog, Wnt and Notch developmental pathways are dysregulated in breast cancer and represent viable targets for further investigation of potential novel therapies in breast cancer.

wnt

Hedgehog

Notch

Breast

stem cell

pancreas

Regulation of somite myogenesis by cytokines occurs in specific somite regions and during distinct temporal periods /

Baranski, Alicia Michelle.

January 2007

Thesis (Ph. D.)--University of Washington, 2007. / Vita. Includes bibliographical references (leaves 188-204).

Regulation der Wirkung von Sonic Hedgehog durch Cholesterin

Laubner, Daniela.

January 2002

München, Techn. Univ., Diss., 2002.

Investigating the Molecular Signaling Pathways Governing Proliferation, Differentiation, and Patterning During Zebrafish Regenerative Osteogenesis

Armstrong, Benjamin

27 October 2016

Upon amputation, zebrafish innately regenerate lost or damaged bone by precisely positioning injury-induced, lineage-restricted osteoblast progenitors (pObs). While substantial progress has been made in identifying the cellular and molecular mechanisms underlying this fascinating process, the cell-specific function of these pathways is poorly understood. Understanding how molecular signals initiate osteoblast dedifferentiation, balance progenitor renewal and re-differentiation, and control bone shape during regeneration are of paramount importance for developing human therapies. We show that fin amputation induces a Wnt/β-catenin-dependent epithelial to mesenchymal transformation (EMT) of osteoblasts to generate proliferative Runx2+ pObs. Localized Wnt/β-catenin signaling maintains this progenitor population towards the distal tip of the regenerative blastema. As they become proximally displaced, pObs upregulate sp7 and subsequently mature into re-epithelialized Runx2-/sp7+ osteoblasts that extend pre-existing bone. Autocrine Bone Morphogenetic Protein (BMP) signaling promotes osteoblast differentiation by activating sp7 expression and counters Wnt by inducing Dickkopf-related Wnt antagonists. As such, opposing activities of Wnt and BMP coordinate the simultaneous demand for growth and differentiation during bone regeneration. Previous studies have implicated Hedgehog/Smoothened (Hh/Smo) signaling in controlling the re-establishment of stereotypically branched bony rays during fin regeneration. Using a photoconvertible patched2 reporter, we resolve active Hh/Smo output to a narrow distal regenerate zone comprising pObs and neighboring migratory basal epidermal cells. Hh/Smo activity is driven by epidermal Sonic hedgehog a (Shha) rather than Ob-derived Indian hedgehog a (Ihha), which instead uses non-canonical signaling to support bone maturation. Using high-resolution imaging and BMS-833923, a uniquely effective Smo inhibitor, we show that Shha/Smo promotes branching by escorting pObs into split groups that mirror transiently divided clusters of Shha-expressing epidermis. Epidermal cellular protrusions directly contact pObs only where an otherwise occluding basement membrane remains incompletely assembled. These intimate interactions progressively generate physically separated pOb pools that then regenerate independently to collectively re-form a now branched bone. Our studies elucidate a signaling network model that provides a conceptual framework to understand innate bone repair and regeneration mechanisms and rationally design regenerative therapeutics. This dissertation includes previously published co-authored material. / 10000-01-01

Bifurcation

Hedgehog

Osteoblasts

Ray morphogenesis

Regeneration

Zebrafish