Investigating telomerase regulation in human breast cancer cells : a search for telomerase repressor sequences localised to chromosome 3P

Linne, Hannah Louise

January 2015

Cellular immortality is one of the ten hallmarks of human cancer and has been shown to be an essential prerequisite for malignant progression (Hanahan and Weinberg., 2011, Newbold et al., 1982, Newbold and Overell., 1983). In contrast, normal human somatic cells proliferate for a limited number of population doublings before entering permanent growth arrest known as replicative senescence. This is thought to be due to the progressive shortening of telomeric sequences with each round of cell division. Over 90% of human tumours, but not the majority of human somatic cells, have been found to express telomerase activity (Kim et al., 1994). The rate-limiting component of the human telomerase enzyme is the telomerase reverse transcriptase subunit, which is encoded by the hTERT gene. Transfection of hTERT cDNA into normal human fibroblasts and epithelial cells may sometimes be sufficient to confer cellular immortality (Newbold., 2005, Stampfer and Yaswen., 2002). Therefore, de-repression of hTERT and telomerase re-activation are thought to be critical events in human carcinogenesis and is the predominant mechanism by which cancer cells maintain their proliferative capacity. Previously, our group has shown that introduction of a normal, intact copy of human chromosome 3 into the 21NT primary breast cancer cell line by microcell-mediated monochromosome transfer (MMCT), is associated with strong telomerase repression and induction of cell growth arrest within the majority of hybrid clones (Cuthbert et al., 1999). Structural mapping of chromosome 3 within telomerase-positive revertent clones revealed two regions of deletion: 3p21.3-p22 and 3p12-p21.1, thought to harbour the putative telomerase repressor sequence(s). Subsequent studies showed that the chromosome 3p-encoded telomerase repressor sequence(s) mediates its function by means of transcriptional silencing of hTERT, in part, through chromatin remodelling of two sites within intron 2 of the hTERT gene (Ducrest et al., 2001, Szutorisz et al., 2003). Attempts to achieve positional cloning of hTERT repressor sequences on chromosome 3p identified two interesting candidates; the histone methyltransferase SETD2 and an adjacent long non-coding RNA (lncRNA) sequence known as FLJ/KIF9-AS1 (Dr. T. Roberts, unpublished data). Through MMCT-mediated introduction of intact chromosomes 3 and 17 into the 21NT cell line, I have demonstrated that at least two as yet unidentified telomerase repressor sequences (one located on each of these two normal chromosomes) may function to repress telomerase activity within the same breast cancer cell line, which suggests that multiple, independent telomerase regulatory pathways may be inactivated within the same cancer type. Furthermore, by examining the consequences of forced SETD2 and FLJ expression within the 21NT cell line, together with siRNA-mediated knockdown of SETD2 within a single telomerase-repressed 21NT-chromosome 3 hybrid, I have provided evidence to show that neither of these two candidate genes may function as a regulator of hTERT transcription. Through interrogation of relevant literature, a set of four candidate 3 telomerase regulatory genes (BAP1, RASSF1A, PBRM1 and PARP-3) were selected for further investigation based on their location within the 3p21.1-p21.3 region together with their documented role in the epigenetic regulation of target gene expression. Using mammalian expression vectors containing candidate gene cDNA sequences, my colleague Dr. T. Roberts and I demonstrated that forced overexpression of BAP1 and PARP-3 within the 21NT cell line is associated with consistent, but not always sustained, repression of hTERT transcriptional activity and telomerase activity. It is therefore possible that at least two sequences may exist on chromosome 3p that function collectively to regulate hTERT expression within breast cancer cells. Finally, using an in vitro model of human mammary epithelial cell (HMEC) immortalization, involving the targeted abrogation of two pathologically relevant genes, p16 and p53 to generate a series of variant clones at different stages of immortal transformation (developed by my colleague Dr. H. Yasaei), I have shown that single copy deletions on chromosome 3p are a frequent, clonal event, specifically associated with hTERT de-repression and immortal transformation. Subsequent high-density single nucleotide polymorphism (SNP) array analysis of immortal variants carried out by Dr. H. Yasaei, identified a minimal common region of deletion localized to 3p14.2-p22. Together, these findings provide additional evidence to show that chromosome 3p may harbour critical hTERT repressor sequences, that are lost as an early event during breast carcinogenesis.

616.99

Molecular Studies of Irradiation and SN-38 on Colorectal Cancer

Wallin, Åsa

January 2008

Colorectal cancer (CRC) is one of most common cancer diseases worldwide. In Swedenapproximately 5,000 new cases of CRC are generated each year, which makes it the thirdmost common cancer disease among both men and women. The past decades ofimproved treatment strategies have considerably increased the five-year survival for CRCpatients. However more could be achieved in this area, in particular for metastatic CRC,which is the cause of most CRC-related deaths. Therefore it is important to study thebiological response to certain treatments induced in CRC to find valuable predictiveand/or prognostic factors to select patients for better suited treatments. The aim of this thesis was to gain insight into the molecular changes that occurfollowing irradiation or treatment with SN-38 in rectal cancer patients or colon cancercell lines by studying the RNA expression, protein expression, DNA cell cycledistribution and apoptotic response. The expression of phosphatase of regenerating liver(PRL) proteins was investigated in rectal cancers from 125 patients included in arandomized clinical trial of preoperative radiotherapy (RT). Increased expression of PRLswas seen at the invasive margin of primary and metastatic cancers compared with theinner area of the tumors. Moreover, strong PRL staining at the invasive margin correlatedto distant recurrence and worse survival of patients in the RT group but not in non-RTgroup (Paper I). Radiosensitivity was studied by treating KM12C, KM12SM andKM12L4a colon cancer cell lines with radiation. KM12C is of low metastatic naturecompared with the highly metastatic KM12SM and KM12L4a. Upregulation of ΔNp73and PRL-3 might contribute to the radioresistant phenotype in KM12C. In contrast,KM12L4a shows a high frequency of apoptosis and lack of upregulation of ΔNp73, PRL-3 and survivin, which might explain its radiosensitive phenotype (Paper II). KM12C,KM12SM and KM12L4a were treated with SN-38 which inhibits topoisomerase 1 (topo-1). The results show that SN-38 induces G2/S arrest and possess the capacity to triggerapoptosis in the three cell lines (Paper III). To further elucidate SN-38 effect on these celllines, the gene expression profile following SN-38 treatment was studied. Oligonucleotidearrays consisting of ~27,000 spots were hybridized with sample and reference cDNA.Both unsupervised and supervised hierarchical clustering analysis, and functional analysiswere performed. Supervised hierarchical clustering gives a strong signal of 1453discriminated genes, the vast majority being upregulated. Both upregulated anddownregulated genes point toward a favorable impact of SN-38 regarding the apoptoticpathways. For example RhoB and Bax are upregulated together with downregulation ofKras and survivin, which promotes apoptosis (Paper IV). In conclusion, PRLs may be valuable biomarkers for RT resistance, predicting apoor prognosis in rectal cancer patients. Targeting radio-resistance factors, such asΔNp73 and survivin may contribute to an increased sensitivity to RT. SN-38 affects cellproliferation and apoptosis.

Colorectal cancer (CRC)

molecular changes

SN-38

Oncology

Onkologi

Development of a Non-Invasive Proteomic Approach to Profiling Molecular Changes in the Microenvironment to Investigate Stages of Breast Health

George, Amy L.

January 2020

Early detection of breast cancer is critical for increasing survival rates. However, currently available screening strategies provide ambiguous results, leaving invasive tissue biopsy procedures necessary for definitive diagnosis. Considerable efforts have investigated using nipple aspirate fluid (NAF), a liquid biopsy rich in proteins representative of the breast microenvironment, as a non-invasive source of early detection biomarkers. However, by using traditional two-dimensional discovery proteomic approaches, many technical challenges of using NAF have limited analysis of large sample sizing: such as low expressed volume (<10µL) or insufficient analytical material (<200µg protein). Following non-invasive collection by manual massage, we developed a one-dimensional sample preparation workflow that reduced sample handling steps, minimised sample losses and increased sample throughput to 96-samples by using a PVDF-membrane based system, which was ideally suited to the NAF proteome. Samples were prepared within a single working day, and results correlated significantly with conventional in-solution protocols. ​Proteins typically associated with the dysregulation of innate immune response and haemostatic pathways had a significantly altered proteome profile in response to breast cancer. Overall, our new workflow will allow future studies to take a more high-throughput approach, revealing biomarkers for breast cancer early detection, and providing a real impact.

Breast cancer

Biomarkers

Proteomics

Nipple aspirate fluid

Liquid biopsy

Non-invasive

Molecular changes

Microenvironment