Role of WT1 in Ischaemic Angiogenesis

Ogley, Robert James

January 2018

Ischaemia causes irreversible tissue damage in cardiovascular disease. Since regenerative angiogenesis fails to consistently induce sufficient reperfusion to facilitate repair, targeted manipulation of angiogenesis is clinically desirable. The Wilms' tumour suppressor (Wt1) is a transcription factor which regulates numerous genes and cellular processes, including many intrinsic to angiogenesis. We hypothesise that WT1 in the endothelium influences the angiogenic function of endothelial cells. WT1 was identified in endothelial and non-endothelial cells comprising vessel outgrowths generated by cultured aortic rings from WT1-GFP reporter mice. Inducible deletion of WT1 from the endothelium (VE-Wt1 KO) significantly delayed angiogenesis in this assay (p < 0.05 relative to controls). In vivo, WT1 expression was evident in vascular endothelial and perivascular cells of the hindlimb as early as 3 days following femoral artery ligation to induce ischaemia, often in cells expressing epithelial and mesenchymal markers simultaneously. However, VE-Wt1 KO had no effect on hindlimb reperfusion (laser Doppler; days 0-28) or on vessel density (day 28). Similarly, VE-Wt1 KO had no effect on vessel density or expression of angiogenic factors (qRT-PCR) in sponges inserted subcutaneously in mice (20 days). To further understand the role of WT1 in angiogenesis, transcriptomic RNA expression analysis was performed in WT1+ and WT1- cells isolated (FACs) from sponges after implantation in WT1-GFP mice. WT1+ cells exhibited higher expression of genes involved in a number of processes relevant to tissue repair, including angiogenesis (p=3.11x10-8), wound healing (p=3.45x10-7) and epithelial-to-mesenchymal transition (EMT) (p=5.86x10-4). These results shed new light on the role of WT1 in ischaemic angiogenesis. In concurrence with previously published work, we show that deletion of endothelial WT1 can delay angiogenesis however, WT1 is not just instrumental in endothelial cells in this context. WT1 has a broader role in tissue repair in ischaemia, in part through regulation of cell transition (EMT). This work has improved our understanding of the regulatory role of WT1 in angiogenesis and repair, while revealing a number of novel insights into the function of WT1. This highlights WT1 as a potentially beneficial therapeutic target to facilitate regeneration in cardiovascular disease.

The Role of the p14ARF Tumour Suppressor in Promoting Apoptosis

Gallagher, Stuart John

January 2008

Doctor of Philosophy (PhD) / The incidence of melanoma has risen dramatically during the past three decades, yet there has been little improvement in effective treatments for this intractable and aggressive disease. Melanoma tumours are notoriously resistant to apoptosis, a cell suicide program that is activated by most cancer therapies. This thesis explores the role of the melanoma susceptibility gene product p14ARF in promoting cell cycle arrest and apoptosis, in order to resolve the impact of this tumour suppressor in melanomagenesis and melanoma susceptibility. The p14ARF tumour suppressor gene is mutated in almost half of all cancers, and germline mutations in p14ARF confer a greatly increased risk of developing melanoma. The primary function of p14ARF is to relay oncogenic signals to p53, a central regulator of cellular response to stress. There is conflicting evidence regarding the role of p14ARF in promoting apoptosis. Much of the current evidence is based on murine studies, which may not translate accurately to humans due to important differences in animal physiology and the primary sequence and functions of the mouse and human ARF proteins. Furthermore, results from previous studies are often compounded by supra-physiological expression of p14ARF, and are complicated by the fact that p14ARF shares its genomic sequence with the p16INK4a tumour suppressor gene. This study demonstrates that p14ARF expression in human cancer and primary cell lines promotes rapid p53-dependent cell cycle arrest, rather than apoptosis. As p14ARF expression did not induce apoptosis, we investigated if p14ARF could modulate the sensitivity of a cell to apoptosis induced by cytotoxic agents. Using a p14ARF-inducible U2OS osteosarcoma cell line model, we examined the impact of p14ARF expression on the apoptotic response of the cell to a panel of thirteen cytotoxic agents. p14ARF expression increased apoptosis caused by a sub-set of agents, including trichostatin A, sodium butyrate, DRB, Adriamycin and UVB radiation. p14ARF-mediated chemosensitivity was p53- and caspase-dependent, and involved the loss of mitochondrial potential. While loss of mitochondrial potential was dependent on p53, it was not blocked by caspase inhibition, demonstrating that caspases play a role downstream of mitochondrial depolarisation. Inhibition of individual components of the apoptotic program showed that p14ARF-mediated chemosensitivity was not strictly dependent on the pro-apoptotic Bax or Fas proteins. We also investigated whether p14ARF could sensitise melanoma to chemotherapeutics in vivo. We investigated the expression level of p14ARF, p16INK4a and MITFm and mutation status of B-RAF, N-RAS and PTEN in melanomas from 30 patients that had undergone isolated limb infusion - a palliative therapeutic strategy that results in much higher response rates than systemic treatment. Expression of p14ARF did not predict response to the drugs actinomycin D and melphalan . Instead, high expression of p16INK4a and presence of activating N-RAS mutation were independent predictors of response to high doses of these chemotherapeutic drugs. This work suggests that p14ARF analogues may be beneficial adjuncts in cancer therapy, but are unlikely to be effective as single agents. Additionally, p14ARF mimetics will only be effective in tumours with intact p53 signalling. Melanomas frequently carry functional p53, and may be susceptible to this mode of treatment providing the apoptotic pathway downstream of p53 is intact or can be restored.

p14ARF

Melanoma

Cancer

Apoptosis

Tumour suppressor

Egr2/Egr3 are essential tumour suppressor genes for lymphomagenesis

Bhullar, Punamdip Kaur

January 2013

Non-Hodgkin’s lymphoma is the fifth most common cancer in the UK, accounting for 4% of all new cases. The control of lymphomagenesis still remains a challenge. Early growth response gene (Egr) 2 and 3 are zinc finger transcription factors. Egr2 plays an important role in the development of both central nervous system and lymphocytes. However the mechanism of action in lymphocytes is still unknown. In order to fully understand the function of Egr2, in lymphocytes, we developed Egr2 and 3 double knockout mice (Egr2-/-Egr3-/-) by crossbreeding lymphocyte specific Egr2 knockout mice (CD2-Egr2-/-) with Egr3 knockout mice (Egr3-/-), as previous reports suggested that Egr3 compensates for the role of Egr2. In the absence of Egr2 and 3, the homeostasis of T cells is dysregulated with hyper-homeostatic proliferation of effector like phenotype cells. More importantly the development of spontaneous B and T cell lymphoma was found in more than 70% of Egr2-/-Egr3-/- mice. The lymphoma cells from Egr2-/-Egr3-/- mice were highly proliferative and metastatically spread into other non-lymphoid organs, such as lung, liver and kidney. In additional to this lymphoma development the Egr2-/-Egr3-/- mice showed signs of chronic inflammatory disorder. This inflammatory disorder was characterised by glomerulonephritis and an increase in serum cytokines, which may provide the microenvironment for the lymphoma development. To explore the molecular mechanism of tumour development in Egr2-/-Egr3-/- mice, the transcriptional profile of Egr2 was studied by microarray and ChIP-on-chip. We found firstly that Egr2 directly binds to the promoter regions of Ikaros and FOXO3. The deletion of Egr2 and 3 in lymphocytes led to the downregulation of Ikaros, Aiolos and FOXO3 expression. The impaired expression was found to be associated with proliferative disorder and the development of T and B cell lymphoma. Secondly Egr2 strongly inhibits STAT3 transcriptional activity by regulating SOCS3, which is a known inhibitor of STAT3. The breakdown of this regulation could be an important mechanism in lymphomagenesis. A model is proposed which defines Egr2 and Egr3 as the backbone of important tumour suppressor genes that control cell fate decision and regulates homeostasis in the lymphoid system. Thus, our results suggest that Egr2 and 3 are important regulators of lymphocyte function by their involvement in multiple cell signalling pathways, which could potentially be key genes for future cancer therapy.

610

USING THE ZEBRAFISH MODEL TO DETERMINE THE ROLE OF THE HACE1 TUMOUR SUPPRESSOR IN NORMAL DEVELOPMENT AND TUMOURIGENESIS

McDonald, Lindsay

27 June 2011

HACE1 is a tumour suppressor gene located at human chromosome 6q21. HACE1 is downregulated in Wilms’ tumour as well as several other human cancers. Its role in normal development remains unknown. The zebrafish has established itself as a robust model for studying vertebrate development and human cancers. A zebrafish hace1 homologue has been identified. Whole mount in situ hybridization (WISH) assays and colocalization studies demonstrate conserved hace1 expression. Moreover, morpholino knockdown of hace1 reveals perturbed cardiac development and function. Transgenic zebrafish harboring either wild type or dominant negative mutated C876S (C876S DN) human HACE1 genes have been generated. DN zebrafish display increased apoptosis, both untreated and following irradiation-induced cellular damage. There was no difference in cell cycle progression between wild type embryos and C876S DN. Further characterization of the HACE1 transgenic zebrafish model will serve to better our understanding of the role of human HACE1 in normal development and tumourigenesis.

Cancer

Zebrafish

Tumour suppressor

Wilms' tumour

Itch E3 ubiquitin ligase regulates LATS1 tumour suppressor stability

Ho, King Ching

27 April 2011

The Large Tumor Suppressor 1 (LATS1) is a serine/threonine kinase and tumor suppressor found down-regulated in a broad spectrum of human cancers. It is a central player of the emerging Hippo-LATS tumour suppressor pathway, which plays important roles in cell proliferation, apoptosis, and stem cell differentiation. Despite the ample data supporting a role of LATS1 in tumour suppression, how LATS1 is regulated at the molecular level remains largely unknown. In this study, we have identified Itch, a HECT class E3 ubiquitin ligase, as a novel binding partner of LATS1. Itch can complex with LATS1 both in vitro and in vivo through the PPxY motifs of LATS1 and the WW domains of Itch. Significantly, we found that over-expression of Itch promoted LATS1 degradation by polyubiquitination through the 26S proteasome pathway. On the other hand, knockdown of endogenous Itch by shRNAs provoked stabilization of endogenous LATS1 proteins. Finally, through several functional assays, we also revealed that change of Itch abundance alone is sufficient for altering LATS1-mediated downstream signaling, negative regulation of cell proliferation, and induction of apoptosis. Together, our study identifies E3 ubiquitin ligase Itch as the first negative regulator of LATS1 and presents for the first time a possibility of targeting LATS1/Itch interaction as a therapeutic strategy in cancer. / Thesis (Master, Pathology & Molecular Medicine) -- Queen's University, 2011-04-26 22:25:46.008

Proteomics

Ubiquitination

Tumour suppressor

Protein stability

The molecular genetics of adenocarcinoma of the oesophagus and gastric cardia

Gleeson, Catherine M.

January 1996

No description available.

572.8

BRCA1 mediated G2/M cell cycle arrest in response to taxol

Quinn, Jennifer E.

January 2000

No description available.

610

The Role of the p14ARF Tumour Suppressor in Promoting Apoptosis

Gallagher, Stuart John

January 2008

Doctor of Philosophy (PhD) / The incidence of melanoma has risen dramatically during the past three decades, yet there has been little improvement in effective treatments for this intractable and aggressive disease. Melanoma tumours are notoriously resistant to apoptosis, a cell suicide program that is activated by most cancer therapies. This thesis explores the role of the melanoma susceptibility gene product p14ARF in promoting cell cycle arrest and apoptosis, in order to resolve the impact of this tumour suppressor in melanomagenesis and melanoma susceptibility. The p14ARF tumour suppressor gene is mutated in almost half of all cancers, and germline mutations in p14ARF confer a greatly increased risk of developing melanoma. The primary function of p14ARF is to relay oncogenic signals to p53, a central regulator of cellular response to stress. There is conflicting evidence regarding the role of p14ARF in promoting apoptosis. Much of the current evidence is based on murine studies, which may not translate accurately to humans due to important differences in animal physiology and the primary sequence and functions of the mouse and human ARF proteins. Furthermore, results from previous studies are often compounded by supra-physiological expression of p14ARF, and are complicated by the fact that p14ARF shares its genomic sequence with the p16INK4a tumour suppressor gene. This study demonstrates that p14ARF expression in human cancer and primary cell lines promotes rapid p53-dependent cell cycle arrest, rather than apoptosis. As p14ARF expression did not induce apoptosis, we investigated if p14ARF could modulate the sensitivity of a cell to apoptosis induced by cytotoxic agents. Using a p14ARF-inducible U2OS osteosarcoma cell line model, we examined the impact of p14ARF expression on the apoptotic response of the cell to a panel of thirteen cytotoxic agents. p14ARF expression increased apoptosis caused by a sub-set of agents, including trichostatin A, sodium butyrate, DRB, Adriamycin and UVB radiation. p14ARF-mediated chemosensitivity was p53- and caspase-dependent, and involved the loss of mitochondrial potential. While loss of mitochondrial potential was dependent on p53, it was not blocked by caspase inhibition, demonstrating that caspases play a role downstream of mitochondrial depolarisation. Inhibition of individual components of the apoptotic program showed that p14ARF-mediated chemosensitivity was not strictly dependent on the pro-apoptotic Bax or Fas proteins. We also investigated whether p14ARF could sensitise melanoma to chemotherapeutics in vivo. We investigated the expression level of p14ARF, p16INK4a and MITFm and mutation status of B-RAF, N-RAS and PTEN in melanomas from 30 patients that had undergone isolated limb infusion - a palliative therapeutic strategy that results in much higher response rates than systemic treatment. Expression of p14ARF did not predict response to the drugs actinomycin D and melphalan . Instead, high expression of p16INK4a and presence of activating N-RAS mutation were independent predictors of response to high doses of these chemotherapeutic drugs. This work suggests that p14ARF analogues may be beneficial adjuncts in cancer therapy, but are unlikely to be effective as single agents. Additionally, p14ARF mimetics will only be effective in tumours with intact p53 signalling. Melanomas frequently carry functional p53, and may be susceptible to this mode of treatment providing the apoptotic pathway downstream of p53 is intact or can be restored.

p14ARF

Melanoma

Cancer

Apoptosis

Tumour suppressor

In vitro investigation of the ubiquitination and degradation of p53 by Murine Double Minute 2 (MDM2) and Retinoblastoma Binding Protein 6 (RBBP6)

Jooste, Lauren Sarah

January 2015

>Magister Scientiae - MSc / P53 is one of the most important tumour suppressor proteins in the body which protects the cell against the tumourigenic effects of DNA damage by initiating processes such as apoptosis, senescence and cell cycle arrest. Regulation of p53 is key — so that the abovementioned processes are not initiated inappropriately. The principle negative regulator of p53 is Murine Double Minute 2 (MDM2), a RING finger-containing protein which catalyses the attachment of lysine48-linked poly-ubiquitin chains, targeting it for degradation by the 26S proteasome. It has been found to work in conjunction with the MDM2 homologue MDMX. Retinoblastoma Binding Protein 6 (RBBP6) is a RING finger-containing protein known to play a role in mRNA 3’-end processing, as well as interacting with p53 and another crucial tumour suppressor, pRb. It has previously been shown to cooperate with MDM2 in the ubiquitination and degradation of p53 in vivo and acts as a scaffold. The objectives of this project are to investigate the proposed role of RBBP6 in the MDM2-catalysed ubiquitination of p53 using a fully in vitro ubiquitination system. Due to the difficulty of expressing full length RBBP6 in bacteria, a shortened version, dubbed "R3" was used which includes the RING finger domain but excludes the domain identified in earlier studies as the p53-binding domain. Proteins required to set up the fully in vitro p53 ubiquitination assays – including E1 and E2 enzymes, MDM2, R3, p53 and ubiquitin - were all successfully expressed in bacteria. The active 26S proteasome was successfully purified out of human cell lysates using antibodies targeting the α2-subunit. Cloning, expression and purification results showed that p53, MDM2 and R3 were not very stable proteins to work with — with degradation being initiated almost immediately after expression and purification which progressed during the downstream processing of the proteins. Although levels of intact protein were not always high, they were sufficient for in vitro assays. MDM2 and GST-R3 were both capable of poly-ubiquitinating p53 independently in "partially in vitro" assays using human cell lysate. The fully in vitro ubiquitination of p53 using MDM2 and R3 was established based on the well-known MDM2/MDMX system. When acting together R3 and MDM2 was shown to produce poly-ubiquitination which is lysine-48 linked and recognised by the 26S proteasome leading to degradation. When the proteasome inhibitor MG132 was added, the poly-ubiquitinated p53 was rescued from degradation. R3 was also shown to successfully poly-ubiquitinate p53 independently of MDM2 and also interact with p53 in vitro. These results suggest R3 to be of the same order of importance as that of MDM2 — which is known to be the most important regulator of p53. It would also rule out the proposed model of RBBP6 functioning as a scaffold as it is able to poly-ubiquitinate p53 independent of MDM2. These results allow us to better understand the mechanism in which p53 is down-regulated by E3s. / National Research Foundation (NRF)

Cancer

Tumour suppressor

Protein

In vitro

Ubiquitination

Role of C-terminal phosphorylation in the regulation of the tumour suppressor IRF-1

Russell, Fiona Margaret M.

January 2013

The transcription factor Interferon Regulatory Factor-1 (IRF-1) has been demonstrated to suppress tumour growth through the regulation of many anti-oncogenic genes. Pro- and anti-apoptotic factors, cell cycle control genes, DNA damage response genes and prometastatic factors are all under the control of IRF-1, which effects both transcriptional activation and repression. In addition to these cell autonomous tumour suppressor activities, IRF-1 is also a key regulator of the immune system and, as such, mediates immune surveillance of tumours. Numerous studies have confirmed that loss or mis-regulation of IRF-1 is a key factor in several different types of cancer. Despite strong evidence for the crucial role of IRF-1 in cancer, and frequent assertions that this protein warrants further investigation as a drug target, very little is known about its regulation. Furthermore, since recent studies have linked upregulation of IRF-1 to the development of autoimmune diseases, it is particularly important that drugs be able to decouple autoimmune and anti-cancer functions of IRF-1 to avoid harmful side effects. This thesis describes how phosphorylation of IRF-1 in its regulatory C-terminal Mf1 domain modulates transactivatory and tumour suppressor activity. Phosphospecific antibodies were developed as tools to study the C-terminal phosphorylation. Using these, it was shown that treatment of cells with Interferon-γ(IFN-γ) not only causes accumulation of IRF-1 protein, but also results in phosphorylation of IRF-1 at two sites in the C-terminal Mf1 domain. Phosphomimetic mutants demonstrated that these phosphorylations enhanced the transactivatory activity of IRF-1 at various promoters, but did not affect repressor activity. Gel shift assays revealed that dual phosphorylation of IRF-1 (IRF-1 D/D) promoted DNAbinding and suggested this was through increased interaction with the cofactor/histone acetylase p300 which induces a conformational change in IRF-1, favouring DNA-binding. Acetylation by p300 appears to be important although it is not yet clear whether this directly or indirectly affects IRF-1 activity. Since the tumour suppressor activity of IRF-1 is of particular interest, the effect of phosphorylation was examined in clonogenic and invasion assays. IRF-1 D/D more efficiently suppressed colony formation in both anchorage dependent and independent assays, and may improve inhibition of invasion in Transwell assays. Thus, cell treatment with the therapeutic agent IFN-γ nduces phosphorylation of IRF-1, resulting in enhanced DNA binding of IRF-1 through improved p300 binding. In cells the outcome is more effective tumour suppression and inhibition of metastasis.