Molecular alterations on chromosome 8 in hepatocellular carcinoma

陳國龍, Chan, Kok-lung.

January 2002

published_or_final_version / Pathology / Master / Master of Philosophy

Liver - Cancer - Genetic aspects.

Molecular genetics.

Chromosomes.

Diet, MGMT and SMAD7 gene variants and breast, prostate and colorectal cancer risk : results from the EPIC-Norfolk study

Loh, Yet Hua

January 2010

No description available.

614

Genome wide copy number and gene expression profiling using archived tissue for molecular marker studies in breast cancer

Iddawela, Mahesh Yasantha Bandara

January 2011

No description available.

616.99

CDKN2Ap16 and familial cancer

Sun, Sophie.

January 1996

CDKN2A/p16 is a cell cycle inhibitor which blocks abnormal cell growth and proliferation. The CDKN2A gene is frequently mutated or deleted in a wide variety of tumour types. Germline mutations have also been identified in familial atypical multiple mole melanoma (FAMMM) pedigrees. However, the role of CDKN2A in hereditary cancer is uncertain. To explore the relationship between CDKN2A germline mutations and risk of cancer, 75 families with cancers at multiple sites were analysed for germline mutations in the CDKN2A gene. A Met53Ile mutation was found in a non-FAMMM kindred with multiple cancers, including one case of melanoma. The Met53Ile mutation has been previously reported in three Australian FAMMM kindreds. A known Ala148Thr polymorphism was also detected in 5 individuals. No other families were found to have CDKN2A alterations. There were no reported CDKN2A mutations in families without cases of melanoma. Analysis of microsatellite markers adjacent to CDKN2A on chromosome 9p21 revealed that this family shares a common haplotype with one other family with this mutation, suggesting that Met53Ile is a founder mutation. These results suggest that while CDKN2A mutations are not restricted to FAMMM pedigrees, they are very rare or absent in families with individuals without melanoma.

Cancer -- Genetic aspects.

Cell cycle.

Melanoma.

The immune response against p53 protein in cancer patients /

Naor, Naftaly

January 1993

Mutations in the p53 gene are known to be associated with a wide range of human tumors. In some primary tumors and established cell lines, stable mutant p53 protein is expressed at high levels, whereas, in normal cells unstable wild-type p53 protein is expressed at very low levels. Sera from some patients with breast and colon tumors contain anti-p53 antibodies. It is unclear whether changes in p53 structure, or its increased level in tumors, causes p53 to become antigenic. In our study we tested sera from patients with various types of cancer for anti-p53 antibodies. Examination of the sera was made by Western blot, and the results were confirmed by rescreening sera with immunoprecipitation. Both techniques revealed the presence of anti-p53 antibodies in some sera from lung and ovary cancer patients, as well as in the sera from patients with breast or colon cancers. Clearly, patients with various cancer tumors are able to produce anti-p53 antibodies. It was unclear whether this humoral immune response is against mutant or wild type p53. To provide a better definition of this immune response, we have examined the anti-p53 response from cancer patients against mutant and wild type p53 in the native and denaturated state. Western blot and Immunoprecipitation analysis showed that the anti-p53 sera recognise both wild type and mutant p53 conformational and denaturation resistant epitopes. Taken together, these data demonstrate that the mutant p53 is not more antigenic than the wild type p53. This provides strong evidence that the antibody response is not directed solely against the altered conformation in mutant p53.

Immune response.

Phosphoproteins.

Cancer -- Genetic aspects.

Studies of tumourigenesis in the multiple endocrine neoplasia type 1 and hyperparathyroidism-jaw tumour syndromes

Walls, Gerard V.

January 2011

No description available.

A Comparative Study of Four Genealogies to Determine Predisposition to Cancer

Andrew, Vivian Wilson

January 1941

This study was made in an effort first, to determine the mode of transmission of the inheritance of a predisposition to cancer as revealed through the analyses of four separate human genealogies, and second, to make a comparative study of the genealogies to determine whether the mode of transmission is the same.

cancer

biology

inheritance

genealogy

Cancer -- Genetic aspects.

Landscape of the p53 transcriptome and clinical implications

Regunath, Kausik

January 2020

The tumor suppressor protein p53, known as the ‘guardian of the genome’, transcriptionally regulates the expression of numerous genes, both coding and non-coding, in response to diverse forms of cellular stress. While numerous reports have been published characterizing the protein coding genes that are transcriptionally regulated by p53, the non-coding targets of p53 are less well-studied. In this thesis, high throughput transcriptome sequencing of cell lines was performed following treatment with different drugs in order to induce p53. Utilizing a combination of de novo transcriptome discovery and mapping to a comprehensive annotation of transcripts named the MiTranscriptome, an extensive catalog of long non-coding RNAs (lncRNAs) was identified. This set of lncRNAs, called p53LTCC (p53 LncRNA Transcriptome from Cultured Cells) are derived from an integrative analysis of RNA-Seq and ChIP-Seq data. It has been previously shown that while the mutation status of p53 may not be a significant predictor of cancer patient survival, a mutant p53 gene expression signature is associated with poor prognosis in many types of cancer. Moreover, the use of attractor metagenes has revealed that the increased expression of metagenes associated with epithelial-mesenchymal transition (EMT), mitotic instability (chromosomal/genomic instability) and lymphocyte infiltration are associated with poor prognosis. Since the p53 pathway is impaired in one way or the other in most tumors, a classifier based on a p53 metagene derived from our p53LTCC was developed that could differentiate between tumor and normal samples based on gene expression. Using machine learning approaches, diagnostic classifiers that could distinguish tumor and normal samples with a high degree of accuracy were developed. Also, while expression of individual long non-coding RNAs had low correlation with patient survival in different cancers, a lncRNA signature that was derived from the catalog of p53 targets had significant prognostic utility for cancer patient survival. Since p53 plays a central role in cancer etiology and it is mutated in over 50% of all cancers, we hypothesized that the lncRNA targets of p53 may have vital functions in effectuating the p53 pathway. Indeed, functional studies of two of the lncRNA targets of p53 showed that they play a role in p53-mediated regulation of cell cycle progression in response to DNA damage and are associated with the regulation of reactive oxygen species (ROS) levels in response to oxidative stress. Although the focus of the experimental studies was to elucidate the role of lncRNAs in the p53 pathway, careful analysis of the transcriptome sequencing results revealed insights into the role of different p53 targets (both coding and non-coding) in different contexts to enable a versatile response to diverse stresses. Not only were we able to identify novel targets of p53, the data showed that there are many p53 targets that are unique to each type of stress. There is also a core transcriptional lncRNA program that is activated by p53 regardless of the context. Finally, during the course of my computational studies, I made numerous observations from bioinformatics analysis of high throughput datasets from different sources that has allowed me to validate many of the experimental results derived by my colleagues (in cell-culture based assays) using cancer patient derived datasets. In order to streamline the workflow of such analysis, I have developed a tool for rapid exploratory data visualization of high throughput datasets for cancer genomics (REDVis) that enables users with minimal programming skills to quickly visualize gene expression, mutation, survival or other clinical, demographic or molecular characterization data for the analysis.

Biology

Genomes

Cancer--Genetic aspects

Tumors

The immune response against p53 protein in cancer patients /

Naor, Naftaly

January 1993

No description available.

Immune response.

Phosphoproteins.

Cancer -- Genetic aspects.

CDKN2Ap16 and familial cancer

Sun, Sophie.

January 1996

No description available.

Cancer -- Genetic aspects.

Melanoma.

Cell cycle.