Role of tumour suppressor ING3 in melanoma pathogenesis

Wang, Yemin

05 1900

The type II tumour suppressor ING3 has been shown to modulate transcription, cell cycle control, and apoptosis. To investigate the putative role of ING3 in melanoma development, we examined the expression of ING3 in 58 dysplastic nevi, 114 primary melanomas, and 50 metastatic melanomas with tissue microarray and immunohistochemistry. Overall ING3 was reduced in metastatic melanomas compared with dyslastic nevi and primary melanomas. Reduced nuclear ING3 staining also correlated with melanoma progression, increased cytoplasmic ING3 level, tumour location at sun-exposed sites, and a poorer disease-specific 5-year survival of patients with primary melanoma. Multivariate analysis revealed that nuclear ING3 staining can independently predict patient outcome in primary melanomas. In melanoma cells, ING3 expression was rapidly induced by UV irradiation. Using stable clones of melanoma cells overexpressing ING3, we showed that ING3 significantly promoted UV-induced apoptosis. Unlike its homologues ING1b and ING2, ING3-enhanced apoptosis upon UV irradiation was independent of functional p53. Furthermore, ING3 did not affect the expression of mitochondrial proteins but increased the cleavage of Bid and caspases. Moreover, ING3 upregulated Fas expression and ING3-mediated apoptosis was blocked by inhibiting caspase-8 or Fas activation. Knockdown of ING3 expression decreased UV-induced apoptosis remarkably, suggesting that ING3 plays a crucial role in cellular response to UV radiation. To explore how ING3 is deregulated in advanced melanomas, we examined ING3 expression in metastatic melanoma cells and found that ING3 was downregulated due to a rapid protein turnover in these cells. Further studies demonstrated that ING3 undergoes degradation via the ubiquitin-proteasome pathway. We also demonstrate that ING3 interacts with the SCF (Skp1/Cul1/Roc1/Skp2) E3 ligase complex. Knockdown of Cul1 or Skp2 significantly stabilized ING3 in melanoma cells. In addition, lysine residue 96 is essential for ING3 ubiquitination as its mutation to arginine completely abrogated ING3 turnover and enhanced ING3-stimulatd apoptosis upon UV irradiation. Taken together, ING3 is deregulated in melanomas as a result of both nucleus-to-cytoplasm shift and rapid degradation. The level of ING3 in the nucleus may be an important marker for human melanoma progression and prognosis. Restoration of ING3 expression significantly sensitizes melanoma cells to UV radiation through the activation of Fas/caspase-8 pathway. / Medicine, Faculty of / Medicine, Department of / Experimental Medicine, Division of / Graduate

ING3

Melanoma

Tumour suppressor

Apoptosis

Protein degradation

Tissue microarray

Computational analysis of multilevel omics data for the elucidation of molecular mechanisms of cancer

Fatai, Azeez Ayomide

January 2015

Philosophiae Doctor - PhD / Cancer is a group of diseases that arises from irreversible genomic and epigenomic alterations that result in unrestrained proliferation of abnormal cells. Detailed understanding of the molecular mechanisms underlying a cancer would aid the identification of most, if not all, genes responsible for its progression and the development of molecularly targeted chemotherapy. The challenge of recurrence after treatment shows that our understanding of cancer mechanisms is still poor. As a contribution to overcoming this challenge, we provide an integrative multi-omic analysis on glioblastoma multiforme (GBM) for which large data sets on di erent classes of genomic and epigenomic alterations have been made available in the Cancer Genome Atlas data portal. The rst part of this study involves protein network analysis for the elucidation of GBM tumourigenic molecular mechanisms, identification of driver genes, prioritization of genes in chromosomal regions with copy number alteration, and co-expression and transcriptional analysis. Functional modules were obtained by edge-betweenness clustering of a protein network constructed from genes with predicted functional impact mutations and differentially expressed genes. Pathway enrichment analysis was performed on each module to identify statistical overrepresentation of signaling pathways. Known and novel candidate cancer driver genes were identi ed in the modules, and functionally relevant genes in chromosomal regions altered by homologous deletion or high-level amplication were prioritized with the protein network. Co-expressed modules enriched in cancer biological processes and transcription factor targets were identified using network genes that demonstrated high expression variance. Our findings show that GBM's molecular mechanisms are much more complex than those reported in previous studies. We next identified differentially expressed miRNAs for which target genes associated with the protein network were also differentially expressed. MiRNAs and target genes were prioritized based on the number of targeted genes and targeting miRNAs, respectively. MiRNAs that correlated with time to progression were selected by an elastic net-penalized Cox regression model for survival analysis. These miRNA were combined into a signature that independently predicted adjuvant therapy-linked progression-free survival in GBM and its subtypes and overall survival in GBM. The results show that miRNAs play significant roles in GBM progression and patients' survival finally, a prognostic mRNA signature that independently predicted progression-free and overall survival was identified. Pathway enrichment analysis was carried on genes with high expression variance across a cohort to identify those in chemoradioresistance associated pathways. A support vector machine-based method was then used to identify a set of genes that discriminated between rapidly- and slowly-progressing GBM patients, with minimal 5 % cross-validation error rate. The prognostic value of the gene set was demonstrated by its ability to predict adjuvant therapy-linked progression-free and overall survival in GBM and its subtypes and was validated in an independent data set. We have identified a set of genes involved in tumourigenic mechanisms that could potentially be exploited as targets in drug development for the treatment of primary and recurrent GBM. Furthermore, given their demonstrated accuracy in this study, the identified miRNA and mRNA signatures have strong potential to be combined and developed into a robust clinical test for predicting prognosis and treatment response.

Cancer

Molecular mechanisms

Tumour suppressor gene

Glioblastoma multiforme

Gene ontology

Towards the Investigation of the Effects of Nitration on the Activity of the Human p53 Tumour Suppressor Protein. Nitration of the p53 Tumour Suppressor Protein

Husaini, Roslina

January 2014

Upon responding to cellular stress, p53 protein becomes stabilised and acts as a transcription factor mainly resulting from phosphorylation and acetylation of the protein. Nitration of p53 protein is poorly characterised by comparison with phosphorylation and acetylation. The main aim of this work was to study the effects of nitration on p53 functional activities and on p53-MDM2 protein-protein interactions. Preliminary work was to characterise the nitration of p53 protein over-expressed in E. coli BL21(DE3) which was then purified by a series of column chromatography. GST-MDM2 protein along with control GST protein were also overexpressed in BL21 which were subsequently purified by a single step batch purification before subjected to nitration. Peroxynitrite, a nitrating agent used in this study, was generated in vitro. Preliminary nitration work was carried out using BSA as a model protein as it is easily nitrated owing to its high number of tyrosine residues (19 residues). The present results showed that p53 and GST-MDM2 proteins were hardly nitrated as no strong nitro-tyrosine signals were obtained. This might be due to these proteins, being overexpressed in E. coli, were not properly folded resulting in hidden/cryptic tyrosine residues of which making nitration difficult to achieve. Peroxynitrite was shown to have a degrading property, reducing protein levels of peroxynitrite-treated p53, GST-MDM2 and GST proteins. Immunoprecipitation studies of cancer cell lysates with different p53 status treated with peroxynitrite showed very weak signals of nitro-p53 protein in mutant p53 cells whereby no nitro-p53 protein signal in wild-type p53 MCF7 cells. In addition, NO donor GSNO-treated MCF7 cells showed weak nitro-p53 protein signals. / Ministry of Science, Technology and Innovation (MOSTI) of Malaysia

CYB5D2 Possesses Tumour Suppressing Activities

Shen, Yen Ting

04 1900

<p>Loss of chromosome 17p is frequently observed in various cancers. One of the most commonly mutated targets p53 is on chromosome 17p13.1. However, studies have also reported loss of the 17p13.2 region in breast and medulloblastoma, thereby suggesting the residence of potential tumour suppressors in 17p13.2. Cytochrome b5 domain containing 2 (CYB5D2) is located on 17p13.2 implying CYB5D2 being a candidate tumour suppressor. CYB5D2 (neuferricin) belongs to the family of membrane associated progesterone receptors (MAPR). The archetypal member of the family, progesterone receptor membrane component 1 (PGRMC1), has been shown to play a role in domains independently of its function in mediating progesterone signalling. Consistent with this, CYB5D2 was reported to promote neurogenesis and inhibit the proliferation of Neuro2a cells. However, its role in tumorigenesis remains unknown.</p> <p>To investigate the role of CYB5D2 in tumorigenesis, western blot analysis was performed on 20 matched clear cell renal cell carcinomas (ccRCC) and the adjacent non-tumour kidney (ANK) tissues; significant down-regulation of CYB5D2 was demonstrated in ccRCC in comparison to ANK tissues, an observation that was confirmed by immunohistochemistry (IHC) analysis of 9 pairs of ccRCC-ANK tissues. Ectopic expression of CYB5D2 inhibited the proliferation and the invasion of A498 ccRCC along with the inhibition of AKT activation. Collectively, the above results support the possibility of CYB5D2 being a potential tumour suppressor.</p> <p>In support of the results obtained in ccRCC, we were able to show a significant reduction of CYB5D2 in cervical squamous carcinoma compared to normal cervical tissues in our analysis of CYB5D2 expression in 35 cervical squamous tumours. In vitro, overexpression and knockdown of CYB5D2 inhibited and enhanced the invasion of HeLa cells, respectively. As a member of the MAPR family, CYB5D2 contains the signature motif of the family, the cytochrome b5 (cyt-b5) like heme/steroid binding domain. This domain is known for heme binding and research in our laboratory has shown the residue D86 being critical for heme association. Ssubstitution of D86 with G (D86G) abolished not only CYB5D2's ability to bind heme but also its capacity of inhibiting HeLa cell invasion. Taken together, we provide evidence that CYB5D2 possesses activities in suppressing tumorigenesis, at least for the tumorigenesis of ccRCC and cervical squamous carcinoma.</p> / Master of Science (MSc)

CYB5D2

tumour suppressor

renal cell carcinoma

cervical cancer

Genetics

Genetics

The tumour suppressor ASPP2 plays a novel role in the maintenance of epithelial cell polarity

Sottocornola, Roberta

January 2010

ASPP2 has been identified as a haploinsufficient tumour suppressor in mice, and an activator of the apoptotic function of the p53 family. Yeast two-hybrid experiments have also shown that ASPP2 interacts with a large number of proteins involved in other major signalling pathways. The mechanism(s) of action of ASPP2 are therefore complex, and likely to involve more than just the stimulation of the apoptotic programme. Since a study previously conducted in our laboratory revealed that the deletion of ASPP2 in vivo leads to severe hydrocephalus in the J129/C57BL6 background (Vives et al., 2006), it can be hypothesised that ASPP2 safeguards the normal development of the mammalian central nervous system (CNS), in addition to its role as a tumour suppressor. Deletion of ASPP2 leads to the development of hydrocephalus, most probably by affecting tight junctions (TJs) in the choroid plexus, thereby impairing its blood-cerebrospinal fluid (CSF) barrier function. TJ defects are likely to be the underlying cause of the loss of cell polarity observed in the neuroepithelium of several areas of the CNS. As cell polarity plays a key role in multiple aspects of CNS development, ASPP2 appears to be required for the proper lamination of the cerebral cortex and retina.

616.994027

ABCB5 and the regulation of p16INK4a by non-coding RNA

Braker, Paul

January 2014

p16INK4a (p16) traps the cell at the restriction point of the cell cycle by binding to cyclin-dependent kinase 4/6 thus preventing the phosphorylation of the retinoblastoma protein (pRB). As p16 accumulates the cell stops dividing and becomes senescent. This study investigates the modulation of p16 function by the putative membrane protein ABCB5 and a group of five putative oncogenic microRNAs (oncomiRs). ABCB5 is a poorly characterised member of the B-subfamily of human ATP Binding Cassette transporters. ABCB5 is reportedly transcribed into four transcripts, one of which could potentially encode a full-length transporter (ABCB5fl) whilst a second could encode a half-transporter (ABCB5β). The other two transcripts (ABCB5α and ABCB5γ) could only encode short polypeptides. Exogenous expression of ABCB5fl and ABCB5β was achieved in HEK293T cells, but the recombinant protein expressed poorly and localised to the endoplasmic reticulum. Point mutations introduced into the ATP catalytic domain failed to improve expression levels suggesting that protein function was not deleterious to the cell. Exogenous expression in HEK293T cells also allowed commercial antibodies purportedly raised against ABCB5 isoforms to be tested. Several were found not to recognise ABCB5 necessitating re-interpretation of published data. However, one antibody recognised both ABCB5fl and ABCB5β, and was subsequently used to evaluate protein expression levels in other cell types.siRNA knockdown of ABCB5 in human mammary epithelial cells (HMECs) caused a concomitant reduction in p16 expression and an increase in cellular proliferation. Differential siRNAs and RT-qPCR analyses demonstrated ABCB5β to be the relevant transcript with respect to the reduction in p16 expression; however, no native ABCB5β protein was detected in HMECs. Together these data lead to the hypothesis that the ABCB5β transcript may act as a long noncoding RNA to regulate p16. Exogenous expression of each of five distinct putative oncomiRs in HMECs was found to increase cellular proliferation and, surprisingly, increase p16 expression. These results mirror a phenotype commonly observed in p16-positive basal-like breast cancer (BLBC), an aggressive form of breast cancer with poor prognosis and few treatment options. Bioinformatic analysis of the predicted target genes for these oncomiRs identified multiple transcriptional regulators of pRB. These predictions, together with the work performed in a cellular model of p16-positive BLBC, suggest that the oncomiRs may cause unrestricted cell proliferation by indirectly reducing transcription of the pRB gene, RB1. In the absence of pRB, p16 expression is induced via a previously reported oncogeneinduced senescence-like positive feedback loop. These data, and previously published observations, suggest that a similar mechanism may explain the basis of p16-positive BLBC.

572.8

Metabolic remodelling driven by MYC overexpression regulates the p53 tumour suppressor response

Edwards-Hicks, Joy

January 2018

The MYC onocogene is frequently overexpressed in human cancer due to its capacity to promote cell growth and cell proliferation. MYC overexpression activates the p53 tumour suppressor pathway, which resists the pro-tumourigeneic program elicited by MYC. How MYC overexpression engages p53 is yet to be elucidated, and in this study I carried out a large metabolic siRNA screen to determine whether p53 responds to a specific MYC-driven metabolic pathway. Two clear lipid metabolic pathways emerged from the siRNA screen: PPARγ/arachidonate metabolism and de novo sphingolipid synthesis. Knockdown or inhibition of PPARγ increased p53 levels, and PPARγ ligands decreased following MYC overexpression. Knockdown of ceramide synthesis depleted p53 levels, and MYC overexpression increased de novo ceramide synthesis. This demonstrated that MYC-driven ceramide synthesis positively regulates p53, and highlights the role of cell metabolism in the tumour suppressor response to MYC deregulation.

Influence of genotoxic drug-induced post-translational modifications on mutant p53 stability and oncogenic activities

Estevan Barber, Anna

January 2018

The tumour suppressor p53 is often disrupted by missense mutations that can result in p53 protein accumulation and acquisition of novel oncogenic activities. Various studies have demonstrated that DNA-damaging drugs currently used in the clinic aimed at activating wild type p53, can also stabilise and activate mutant p53 oncogenic functions and thereby paradoxically enhance tumour progression, resulting in poor response to the treatment. In this study we aimed to investigate whether, like in wt p53, post-translational modifications (PTMs) drive such drug-induced mutant p53 accumulation and activation. For this purpose, we generated plasmids expressing non-phosphorylatable and phospho-mimic versions of R175H mutant p53 and tested them in different cell line models. We demonstrated that in response to DNA damage mutant p53 is accumulated and phosphorylated and these phenomena appeared to be mediated by ATM and ATR kinases. DNA-damage induced acetylation was also observed and occurred in a S15 phosphorylation-dependent manner. This suggested a role of the HAT p300, which is recruited by phosphorylated S15. Of note, other works have shown that p300 is required to trigger some oncogenic functions of mutant p53. We then aimed at developing systems to explore mutant p53 functions and their dependence on PTMs. Although we showed that cell growth is compromised upon endogenous mutant p53 depletion, exogenous expression of mutant p53 or its phosphorylation-site forms did not result in a successful rescue in our experimental conditions, thus we were unable to use this strategy to test the effect of PTMs. Ectopic expression of R175H mutant p53 or its phosphorylayion-site versions did not interfere with the growth rate and response to chemotherapy of the p53-null cell line H1299. We also found that mutant p53 phosphorylation does not affect subcellular localisation of mutant p53 and mutant p53-mediated inhibition of p63. Interestingly, ectopically expressed mutant p53 enhanced cell migration in H1299 cells. Notably, our results suggested an apparent threshold effect of mutant p53 levels required to induce migration. Due to the difficulty of obtaining cell lines expressing similar levels of the different phosphorylation-site mutants, the determination of the role of phosphorylation in mutant p53-induced migration was not conclusive. Remarkably, we found that, while S15 and S20 phosphorylation decreased MDM2-dependent degradation, only phosphorylated S20 interfered with CHIP-induced turnover in H1299 cells. Overall our data suggest that, despite exhibiting opposite biological effects, mutant and wt p53 can share upstream regulatory mechanisms and thus present phosphorylation as a promising target to prevent mutant p53 stabilisation and activation and improve response to therapy. Our results also highlight the challenge of developing a good system for determining the effects of the mutant p53 protein and its regulation by PTMs.

An investigation of p53’s differential activation of cell cycle arrest and apoptosis

Zhang, Yuan

January 2008

The p53 tumour suppressor protein lies at the hub of a very complex network of cellular pathways including apoptosis, cell cycle arrest, DNA repair and cellular senescence. However, the mechanism of why and how p53 switches between apoptosis and cell cycle arrest, thereby determining a cell’s fate, remains a mystery to us. To enable us to investigate this ability of p53 to switch between cell cycle arrest and apoptosis, we developed a model which demonstrates similar p53 expression patterns but different functional outcomes. Treating cells with Cisplatin (a common chemotherapeutic drug) and Nutlin-3 (an MDM-2 inhibitor) results in similar high levels of p53 accumulation but different cellular responses. Cisplatin-treated cells undergo apoptosis while Nutlin-treated cells enter cell cycle arrest. Using this model, we explored the localization of p53 and in particular a C-terminal Ser 392 moiety in an attempt to identify how p53 is able to preferentially activate cell cycle arrest or apoptotic pathway.

Erythroid Kruppel-Like Factor and the Cell Cycle: A Role beyond Globin Gene Regulation

Michael Tallack

Unknown Date

Erythropoiesis, the process of producing mature erythrocytes from the haematopoietic stem cells (HSCs) that reside in the bone marrow, is tightly regulated at both the cell and molecular level by a well defined set of extracellular cytokine signals and intracellular transcription factors. Diseases affecting erythropoiesis are among the most commonly inherited conditions and result from disturbances to the cellular and molecular events that normally regulate this process. Erythroid Kruppel-like factor (EKLF/KLF1) is a transcription factor that is essential for erythropoiesis. EKLF is the founding member of the Kruppel-like factor family of transcription factors that bind to GC rich CACC-Box elements within gene promoters and activate transcription. The β-like globin genes are critical targets of EKLF through its binding at sites within the proximal promoters and the upstream locus control region (LCR) enhancer. Mice lacking EKLF die prior to birth by E16 with a phenotype that closely resembles the human disease thalassaemia. Thalassaemia is due to mutations in the α or β-globin genes, leading to globin chain imbalance, red cell destruction and ineffective erythropoiesis. However, restoration of expression of γ-globin (a β-like gene) failed to prevent embryonic lethality in EKLF knockout mice and suggested that additional target genes were critical to erythropoiesis. This thesis describes investigation into the transcriptional network of EKLF and an in depth analysis of previously uncharacterised phenotypes present in the EKLF knockout mouse. I have identified a suite of target genes for EKLF that include critical components of the cells cycle. I have also tested the hypothesis that EKLF is able to function in vivo as a tumour suppressor gene. Additionally, I report a role for EKLF in the determination of cell fate within the haematopoietic system and describe the development of a new approach to globally understanding erythroid transcription factor function. A previously performed microarray transcriptional profiling study provided a set of potential target genes for EKLF. I have expanded on this study by identifying that the cell cycle genes p18INK4c, and E2f2 are direct transcriptional targets of EKLF, where binding of EKLF occurs at the promoter and a novel intronic enhancer region, respectively. I have also described a previously undiscovered cell cycle phenotype of aberrant entry into S-phase in EKLF -/- erythroid cells that is directly related to abrogated expression of E2f2. The Kruppel-like factor family of genes have been implicated as players in the tumour process. By constructing a model for the loss of EKLF within HSCs in vivo, I have tested whether EKLF is functional as a tumour suppressor. The loss of EKLF in vivo was found to be insufficient to generate erythroleukaemia, however did result in erythroid hyperplasia, extramedullary haematopoieis and a mild macrocytic anaemia. In addition to regulation of erythropoiesis, EKLF performs a critical role in the lineage choice for a megakaryocyte-erythroid progenitor (MEP) between the megakaryocytic and erythroid lineages. This thesis describes that in the absence of EKLF, MEPs fail to commit properly to either lineage and proceed along a promiscuous pathway sharing the hallmarks of both megakaryocytes and erythroid cells. A detailed molecular mechanism for this phenotype remains undetermined, but is likely to involve interactions with the megakaryocyte transcription factor Fli1 and other members of the Kruppel-like factor family, such as BKLF (KLF3). While the transcriptional mechanisms that drive erythropoiesis have been slowly discovered, the development of chromatin immunoprecipitation (ChIP) assays and next generation DNA sequencing technology has presented the potential to rapidly enhance the progression of these studies. In this thesis I describe the development of ChIP-seq using Applied Biosystems SOLiD technology, an approach to rapidly identify binding sites for erythroid transcription factors in an unbiased genome wide approach. The work described in this thesis has expanded the transcriptional network of EKLF to include critical components of the cell cycle and has suggested many additional target genes from ChIP-seq requiring validation. As one of the major transcription factor players during erythropoiesis, EKLF performs many critical functions that include the regulation of the cell cycle, lineage selection and erythroid development. I suggest that current and future studies of EKLF function will influence our understanding of erythropoiesis and refine our understanding of human conditions such as thalassaemia and erythroleukaemia.

Eklf

Transcription Factor

Erythropoiesis

cell cycle

E2f

p18INK4c

Tumour Suppressor

Megakaryopoiesis

chromatin immunoprecipitation

Erythroleukaemia