Causes and Consequences of Genomic Instability in Prostatic Carcinogenesis

Joshua, Anthony

24 September 2009

The evolution of prostate cancer from normal epithelium via the preneoplastic lesion of high-grade prostatic intraepithelial neoplasia to invasive carcinoma is characterised by a number of particular genomic abnormalities that are predominantly generated in the preneoplastic phase. Whilst there are numerous candidates for the cause of these alterations, telomere dysfunction is thought to be a major contributor. Telomeres are the terminal ends of human chromosomes, and when dysfunctional can lead to break-fusion-bridge cycles and multi-polar mitoses that generate numerical and structural chromosomal instability. The results presented reinforce the association of telomere dysfunction with the generation of certain markers of genomic instability such as abnormalities of the arms of chromosome 8. Furthermore, this work clarifies that the TMPRSSS2-ERG aberrations are not telomere related phenomena and are associated with a genomic deletion in a proportion of cases. Similarly, the PTEN microdeletions did not appear to have an association with telomere attrition. A previously unrecognised association between the telomere length in various types of prostatic epithelia and adjacent stroma is defined, suggesting evidence of a micro-environmental field effect in the generation of prostatic neoplasia. Finally, when examined retrospectively, it appears that telomere attrition, both in the HPIN epithelium and the stroma has independent prognostic value in the diagnosis of prostate cancer after a previous diagnosis of HPIN. Taken together, the research presented suggests important avenues for further research to determine the nature of barriers to the evolution of prostatic carcinogenesis such as oncogene- and telomere-induced senescence that may be exploited for therapeutic gain. These understandings may also help tailor management for prostate cancer such as risk stratification for men with HPIN and the use of targeted agents such as AKT inhibitors and telomerase inhibitors. In more advanced disease, translational application of this work has enabled a clinical trial of cytarabine in the treatment of metastatic hormone refractory prostate cancer.

Prostate Cancer

Genomic Instability

FISH

Telomere

0992

Dissection of the telomere complex CST in Arabidopsis thaliana

Leehy, Katherine

16 December 2013

Telomeres are the ends of linear chromosomes tasked with preventing their recognition by the DNA damage machinery and providing a mechanism to solve the end replication problem. The telomeric DNA is mostly double-stranded, but it terminates in a 3’ protrusion termed the G-overhang. Telomeres utilize telomerase, a reverse transcriptase, to elongate the telomere, and thus, solve the end replication problem. Both the double strand region and the G-overhang are bound by specific proteins to facilitate the objectives of the telomere. First discovered in budding yeast, the CST (Cdc13(CTC1)/Stn1/Ten1) complex binds to the G-overhang and is important for both chromosome end protection and telomere replication. Work reported in this dissertation provided the first evidence that CST was present outside of yeast, which led to its subsequent identification in a number of vertebrates. Here I present the identification and characterization of the three components of CST in Arabidopsis thaliana. Similar to yeast, Arabidopsis CST is required for telomere length maintenance, for preventing telomere recombination and chromosome end-to-end fusions. Mutations in the CST complex result in severe genomic instability and stem cells defects. My research also shows that CST and telomerase act synergistically to maintain telomere length. Together these data provide evidence for an essential role for CST in maintaining telomere integrity. Unexpectedly, I discovered that the TEN1 component of CST may have a more complex role than other members of the heterotrimer. The majority of telomere-related functions we can assay using molecular and cytological approaches are shared by CTC1, STN1 and TEN1, though TEN1 has additional roles in maintaining genome stability, modulating telomerase activity and possibly non-telomeric functions in the chloroplast. I also present genetic evidence that TEN1 and STN1 act in the same pathway for the maintenance of telomere length and chromosome end protection. Interestingly, however, disrupting the STN1/TEN1 interaction reveals a separation of STN1 function for chromosome end protection versus telomere length maintenance. Finally, I describe the design and creation of a library of STN1 and TEN1 mutants that will be used to further characterize their functions and their interaction partners. By disrupting such interactions, it will be possible to elucidate the functional significance of these interactions, and thus, provide new insight into how CST functions in Arabidopsis.

Telomere

CST

genome stability

Arabidopsis thaliana

telomerase

Molecular alterations during immortalisation of human endothelial cells

Wen, Victoria Wei-Yu, Women's & Children's Health, Faculty of Medicine, UNSW

January 2009

Replicative exhaustion of endothelial cells (ECs) contributes to the pathogenesis of age-related vascular disorders, including atherosclerosis and impaired wound healing. Conversely, abnormal proliferation of ECs underlies the development of EC-derived malignancies, such as haemangioblastoma and angiosarcoma. The central objective of this thesis was to delineate mechanisms that regulate the replicative lifespan of human ECs and molecular alterations that occur during immortalisation of ECs. The gradual shortening of telomeres (chromosome-end structures) is one mechanism that restricts the replicative lifespan of human ECs. Telomere shortening initiates an irreversible growth arrest or senescence through activation of a TP53-mediated DNA damage response. Expression of the cyclin-dependent kinase inhibitor, p16INK4a, is also increased and reinforces senescence via the retinoblastoma pathway. Overexpression of telomerase reverse transcriptase (hTERT) reconstitutes telomerase activity and extends the lifespan of human ECs, but is not sufficient for immortalisation. The current study demonstrated that p16INK4a repression by promoter methylation was a frequent event during immortalisation of hTERT-transduced bone marrow ECs (BMECs), occurring in 5 of 12 clones. Repression of p16INK4a concurred with the development of recurring chromosomal aberrations, which appeared to be a consequence of telomere dysfunction and chromosome fusions. Loss of p16INK4a and the development of a complex karyotype were associated with a more transformed phenotype in hTERT-immortalised BMECs. The investigations described in this thesis were the first to associate loss of p16INK4a expression with the accumulation of chromosome aberrations. Repression of p16INK4a in only a subset of immortal BMECs provided impetus for investigating whether there was a functionally analogous defect in the hTERT-immortalised BMECs that retained p16INK4a expression. In normal human cells, oncogenic Ras upregulates p16INK4a and induces senescence independently of telomere shortening. This thesis demonstrates that the immortal BMECs that retained p16INK4a expression had a defective response to oncogenic Ras, which may have contributed to the immortalisation of these cells. Whole genome and proteome analyses identified additional alterations in gene copy number and protein expression specific to p16INK4a-positive or -negative immortal BMECs. Overall, these investigations provide new insight to the potential consequences of p16INK4a repression during carcinogenesis and describe novel molecular alterations that occur during immortalisation of human ECs.

hTERT

Endothelial

p16INK4a

Immortalisation

Telomere

Telomerase

Telomere length of kakapo and other New Zealand birds : assessment of methods and applications

Horn, Thorsten

January 2008

The age structure of populations is an important and often unresolved factor in ecology and wildlife management. Parameters like onset of reproduction and senescence, reproductive success and survival rate are tightly correlated with age. Unfortunately, age information of wild animals is not easy to obtain, especially for birds, where few anatomical markers of age exist. Longitudinal age data from birds banded as chicks are rare, particularly in long lived species. Age estimation in such species would be extremely useful as their long life span typically indicates slow population growth and potentially the need for protection and conservation. Telomere length change has been suggested as a universal marker for ageing vertebrates and potentially other animals. This method, termed molecular ageing, is based on a shortening of telomeres with each cell division. In birds, the telomere length of erythrocytes has been reported to decline with age, as the founder cells (haematopoietic stem cells) divide to renew circulating red blood cells. I measured telomere length in kakapo, the world largest parrot and four other bird species (Buller’s albatross, kea, New Zealand robin and saddleback) using telomere restriction fragment analysis (TRF) to assess the potential for molecular ageing in these species. After providing an overview of methods to measure telomere length, I describe how one of them (TRF) measures telomere length by quantifying the size distribution of terminal restriction fragments using southern blot of in-gel hybridization (Chapter 2). Although TRF is currently the ‘gold standard’ to measure telomere length, it suffers from various technical problems that can compromise precision and accuracy of telomere length estimation. In addition, there are many variations of the protocol, complicating comparisons between publications. I focused on TRF analysis using a non-radioactive probe, because it does not require special precautions associated with handling and disposing of radioactive material and therefore is more suitable for ecology laboratories that typically do not have a strong molecular biology infrastructure. However, most of my findings can be applied to both, radioactive and nonradioactive TRF variants. I tested how sample storage, choice of restriction enzyme, gel Abstract II electrophoresis and choice of hybridization buffer can influence the results. Finally, I show how image analysis (e.g. background correction, gel calibration, formula to calculate telomere length and the analysis window) can not only change the magnitude of estimated telomere length, but also their correlation to each other. Based on these findings, I present and discuss an extensive list of methodological difficulties associated with TRF and present a protocol to obtain reliable and reproducible results. Using this optimized protocol, I then measured telomere length of 68 kakapo (Chapter 3). Almost half of the current kakapo population consists of birds that were captured as adults, hence only their minimum age is known (i.e. time from when they were found +5 years to reach adulthood). Although molecular ageing might not be able to predict chronological age accurately, as calibrated with minimum age of some birds, it should be able to compare relative age between birds. Recently, the oldest kakapo (Richard Henry) was found to show signs of reproductive senescence. The age (or telomere length) difference to Richard Henry could have been used to approximate the remaining reproductive time span for other birds. Unfortunately, there was no change of telomere length with age in cross sectional and longitudinal samples. Analysis of fitness data available for kakapo yielded correlations between telomere length and fledging success, but they were weak and disappeared when the most influential bird was excluded from analysis. The heavy management and small numbers of kakapo make conclusions about fitness and telomere length difficult and highly speculative. However, telomere length of mothers and their chicks were significantly correlated, a phenomena not previously observed in any bird. To test if the lack of telomere loss with age is specific to kakapo, I measured telomere length of one of its closest relatives: the kea (Chapter 4). Like kakapo, telomere length did not show any correlation with age. I then further assessed the usefulness of molecular ageing in birds using only chicks and very old birds to estimate the maximum TL range in an additional long lived (Buller’s albatross) and two shorter lived species (NZ robin and saddleback). In these Abstract III species, telomere length was on average higher in chicks than in adults. However, age matched individuals showed high variations in telomere length, such that age dependent and independent telomere length could not be distinguished. These data and published results from other bird species, coupled with the limitations of methodology I have identified (Chapter 2), indicate that molecular ageing does not work in most (if not all) birds in its current suggested form. Another way to measure telomere length is telomere Q-PCR, a real-time PCR based method. Measurement of the same kakapo samples with TRF and Q-PCR did not result in comparable results (Chapter 4). Through experimentation I found that differences in amplification efficiency between samples lead to unreliable estimation of telomere length using telomere Q-PCR. These differences were caused by inhibitors present in the samples. The problem of differential amplification efficiency in Q-PCR, while known, is largely ignored by the scientific community. Although some methods have been suggested to correct for differing efficiency, most of these introduce more error than they eliminate. I developed and applied an assay based on internal standard oligonucleotides that was able to corrected EDTA induced quantification errors of up to 70% with high precision and accuracy (Chapter 5). The method, however, failed when tested with other inhibitors commonly found in DNA samples extracted from blood (i.e. SDS, heparin, urea and FeCl3). PCR inhibition was highly selective in the probe-polymerase system I used, inhibiting amplification of genomic DNA, but not amplification of internal oligonucleotide or plasmid standards in the same reaction. Internal standards are a key feature of most diagnostic PCR assays to identify false negatives arising from amplification inhibition. The differential response to inhibition I identified greatly compromises the accuracy of these assays. Consequently, I strongly recommend that researchers using PCR assays with internal standards should verify that the target DNA and internal standard actually respond similarly to common inhibitors.

telomere

real-time PCR

ageing

aging

kakapo

The role of Alternative Lengthening of Telomeres in human cancer

Henson, Jeremy D

January 2006

Doctor of Philosophy / Activation of a telomere maintenance mechanism is a vital step in the development of most cancers and provides a target for the selective killing of cancer cells. Cancers can use either telomerase or Alternative Lengthening of Telomeres (ALT) to maintain their telomeres and inhibition of either telomere maintenance mechanism can cause cancer cells to undergo senescence or apoptosis. Although telomerase inhibitors are undergoing clinical trials, on commencing this study very little was known about the role of ALT in cancer, what proteins were involved in its mechanism and regulation and how it could be targeted clinically. The primary aim of this thesis was to develop an assay for ALT suitable for examining archived tumour specimens and to begin using it to examine the prevalence and clinical significance of ALT in cancer. This assay and gene expression analysis was also used to identify genes that are involved in or associated with the activation of the ALT mechanism, to contribute towards the overall goal of an ALT cancer therapy. The ALT mechanism involves recombination mediated replication and ALT cells have a marked increase in a range of recombinational events specifically at their telomeres. Presumably, as a consequence of this the telomere lengths of ALT cells are very heterogeneous and on average long. This can be detected by terminal restriction fragment (TRF) Southern analysis, which has been used previously as the definitive test for ALT activity. However, TRF analysis requires intact genomic DNA and is unsuitable for tumour specimens which are commonly archived by paraffin embedding. Another hallmark of ALT is ALT-associated PML bodies (APBs) which are the subset of PML bodies that contain telomeric DNA. Work done in this study to consolidate APBs as a hallmark of ALT, combined with published data, showed 29/31 ALT[+], 3/31 telomerase[+] and 0/10 mortal cell lines/strains are APB[+]. The three APB[+]/telomerase[+] cell lines identified here had an order of magnitude lower frequency of APB[+] nuclei than the ALT[+] cell lines. APBs may be functionally linked to the ALT mechanism and contain the recombination proteins that are thought to be involved in the ALT mechanism. This study, in collaboration with Dr W-Q Jiang, strengthened this functional link by demonstrating that loss of ALT activity (as determined by TRF analysis) coincided with the disruption of APBs. The detection of APBs was developed into a robust assay for ALT in archived tumour specimens using a technique of combined immunofluorescence and telomere fluorescence in situ hybridisation. It was demonstrated that the APB assay concurred exactly with the standard assay for ALT (TRF analysis) in 60 tumours for which TRF analysis gave unequivocal results. The APB assay may be a more appropriate technique in the case of tumour specimen heterogeneity, which may explain why the APB assay was able to give definitive results when TRF analysis was equivocal. We demonstrated that intratumoral heterogeneity for ALT does exist and this could explain why about 3% of tumours in this study were APB[+] but with more than a ten-fold reduction in the frequency of APB[+] nuclei. This study also made the novel discovery of single stranded C-rich telomeric DNA inside APBs which potentially could be used to make the APB assay more suitable for routine pathology laboratory use. The APB assay was used to show that ALT is a significant concern for oncology. ALT was utilised in approximately one quarter of glioblastoma multiforme (GBM), one third of soft tissue sarcomas (STS) including three quarters of malignant fibrous histiocytomas (MFH), half of osteosarcomas and one tenth of non-small cell lung carcinomas (NSCLC). Furthermore, the patients with these ALT[+] tumours had poor survival; median survivals were 2 years for ALT[+] GBM, 4 years for ALT[+] STS including 3.5 years for ALT[+] MFH and 5 years for ALT[+] osteosarcoma. ALT[+] STS and osteosarcomas were also just as aggressive as their ALT[-] counterparts in terms of grade and patient outcome. ALT status was not found to be associated with response to chemotherapy in osteosarcomas or survival in STS. ALT was however, less prevalent in metastatic STS. The APB assay was a prognostic indicator for GBM and was correlated with three fold increased median survival in GBM (although this survival was still poor). ALT was more common in lower grade astrocytomas (88% ALT[+]) than GBM (24% ALT[+]) and ALT[+] GBM had an identical median age at diagnosis to that reported for secondary GBM. It is discussed that these data indicate that ALT was indirectly associated with secondary GBM and is possibly an early event in its progression from lower grade astrocytoma. This is relevant because secondary GBM have distinct genetic alterations that may facilitate activation of the ALT mechanism. Putative repressors of ALT could explain why this study found that ALT varied among the different STS subtypes. ALT was common in MFH (77%), leiomyosarcoma (62%) and liposarcoma (33%) but rare in rhabdomyosarcoma (6%) and synovial sarcoma (9%). ALT was not found in colorectal carcinoma (0/31) or thyroid papillary carcinoma (0/17) which have a high prevalence of telomerase activity and a reduced need for a telomere maintenance mechanism (low cell turnover), respectively. A yeast model of ALT predicts that one of the five human RecQ helicases may be required for ALT. Using the APB assay to test for the presence of ALT in tumours from patients with known mutations in either WRN or RECQL4 it was demonstrated that neither of these RecQ helicases is essential for ALT. Although p53 and mismatch repair (MMR) proteins have been suggested to be possible repressors of ALT, there was no apparent increase in the frequency of ALT in tumours from patients with a germline mutation in p53 codon 273 or in colorectal carcinomas that had microsatellite instability and thus MMR deficiency. Also contrary to being a repressor of ALT but consistent with its ability to interact with a protein involved in the ALT mechanism, the MMR protein MLH1, was demonstrated to be present in the APBs of an ALT[+] cell line. To further test for genes that may be involved in the ALT mechanism or associated with its activation, RNA microarray was used to compare the gene expression of 12 ALT[+] with 12 matched telomerase[+] cell lines; 240 genes were identified that were significantly differentially expressed (p<0.005) between the ALT[+] and telomerase[+] cell lines. Only DRG2 and SFNX4 were significantly differentially expressed after adjusting for the estimated false positive rate. Overall, DRG2, MGMT and SATB1 were identified as most likely to be relevant to the ALT[+] tumours and Western analysis indicated that DRG2 and MGMT levels were down-regulated after activation of ALT and up-regulated after activation of telomerase, whereas SATB1 protein levels appeared to be up-regulated after immortalisation but to a higher degree with activation of ALT compared to telomerase. Since lack of MGMT is known to be a determinant of temozolomide sensitivity in GBM, the possibility that ALT and the APB assay could be used to predict temozolomide sensitivity is discussed. The microarray data was consistent with MGMT expression being suppressed by EGF (p < 0.05), indicating that caution may be needed with combining EGFR inhibitors with temozolomide in ALT cancers. One ALT[+] cell line which did not express MGMT had TTAA sequence in its telomeres. This could possibly have resulted from mutations due to lack of MGMT expression and a possible role for MGMT in the ALT mechanism is discussed. Further analysis of the microarray data identified two groups of co-regulated genes (p < 5x10-5): CEBPA, TACC2, SFXN4, HNRPK and MGMT, and SIGIRR, LEF1, NSBP1 and SATB1. Two thirds of differentially expressed genes were down-regulated in ALT. Chromosomes 10 and 15 had a bias towards genes with lower expression in ALT while chromosomes 1, 4, 14 and X had a bias towards genes with higher expression levels in ALT. This work has developed a robust assay for ALT in tumour specimens which was then used to show the significance of ALT in sarcomas, astrocytomas and NSCLC. It has also identified genes that could possibly be molecular targets for the treatment of ALT[+] cancers.

Cancer

Telomere

Development and characterization of a new assay to examine telomere-protein interactions in vivo /

Bourns, Brenda,

January 1997

Thesis (Ph. D.)--University of Washington, 1997. / Vita. Includes bibliographical references (leaves [116]-123).

Yeast telomere structure : genetic analysis implicating a novel terminus-specific factor in telomeric silencing /

Wiley, Emily A.

January 1996

Thesis (Ph. D.)--University of Washington, 1996. / Vita. Includes bibliographical references (leaves [95]-102).

Telomeric chromatin structure and function in Schizosaccharomyces pombe /

Tuzon, Creighton T.

January 2005

Thesis (Ph.D. in Biochemistry) -- University of Colorado at Denver and Health Sciences Center, 2005. / Typescript. Includes bibliographical references (leaves 93-103). Free to UCDHSC affiliates. Online version available via ProQuest Digital Dissertations;

Structure, Function and Evolution of Filamentous Fungal Telomerase RNA

January 2011

abstract: Telomerase ribonucleoprotein is a unique reverse transcriptase that adds telomeric DNA repeats to chromosome ends. Telomerase RNA (TER) is extremely divergent in size, sequence and has to date only been identified in vertebrate, yeast, ciliate and plant species. Herein, the identification and characterization of TERs from an evolutionarily distinct group, filamentous fungi, is presented. Based on phylogenetic analysis of 69 TER sequences and mutagenesis analysis of in vitro reconstituted Neurospora telomerase, we discovered a conserved functional core in filamentous fungal TERs sharing homologous structural features with vertebrate TERs. This core contains the template-pseudoknot and P6/P6.1 domains, essential for enzymatic activity, which retain function in trans. The in vitro reconstituted Neurospora telomerase is highly processive, synthesizing canonical TTAGGG repeats. Similar to Schizosaccharomycetes pombe, filamentous fungal TERs utilize the spliceosomal splicing machinery for 3' processing. Neurospora telomerase, while associating with the Est1 protein in vivo, does not bind homologous Ku or Sm proteins found in both budding and fission yeast telomerase holoenzyme, suggesting a unique biogenesis pathway. The development of Neurospora as a model organism to study telomeres and telomerase may shed light upon the evolution of the canonical TTAGGG telomeric repeat and telomerase processivity within fungal species. / Dissertation/Thesis / Ph.D. Biochemistry 2011

Biochemistry

Filamentous fungi

RNA

Telomerase

Telomere

Leukocyte telomere length and accelerated aging as predictors for the onset of psychosis

Amirfathi, Felix

01 November 2017

Leukocyte telomere length is an emerging marker for pathologically accelerated cellular aging. First discovered to be associated with aging-related disorders, such as type 2 diabetes mellitus and cardiovascular disease, in young individuals, leukocyte telomeric degeneration is also garnering growing attention in psychiatric illnesses. Comorbid metabolic symptoms and physiological dysregulation observed in schizophrenia patients imply a plausible association between pathological telomere biology and psychosis. Available data on the relationship between leukocyte telomere length and schizophrenia is limited largely to small-sample, cross-sectional studies unable to fully account for the large body of potentially confounding factors on telomere length (psychotropic medication, chronic stress and history of trauma, comorbidities, paternal age, substance use, subject-level variables). The most comprehensive meta-analysis to date reveals a significant trend of shortened telomeres in schizophrenia patients as compared to healthy controls. Some findings suggest a linear relationship between telomeric attrition and disease chronicity/severity. However, overall findings are insufficient to gauge the potential of leukocyte telomere length as a predictive, diagnostic biomarker in this patient population. Future longitudinal studies with carefully controlled covariates are required to verify the promising potential of a new marker for schizophrenia onset and a possible new direction for adjunctive antipsychotic treatment.

Psychology

Aging

Biomarker

Leukocyte

Psychosis

Schizophrenia

Telomere