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- Bensberg, Maike, 1993-
(author)
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DNA methylation in T cell leukaemia
- 2024
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Doctoral thesis (other academic/artistic)abstract
- T cell acute lymphoblastic leukaemia (T-ALL) is a predominantly paediatric cancer that stems from malignant transformation of developing T cells. While the disease has an overall survival rate of 80%, the intense chemotherapy treatment causes severe toxicity and long-term side effects. Furthermore, the survival rate for patients in relapse is less than 25%. Consequently, there is a need for improved therapy options to reduce treatment-related side effects and improve the survival rate of relapsed patients. Targeting aberrant DNA methylation with hypomethylating agents (HMAs) has been successful in the treatment of myelodysplastic syndromes and acute myeloid leukaemia but has not been routinely used in the treatment of T-ALL, despite DNA hypomethylation being observed in T-ALL patients. In this work, we employed a comprehensive set of molecular and sequencing-based techniques to explore the possibilities of HMAs as a treatment option for T-ALL.We made the discovery that the DNA demethylating enzyme ten-eleven translocation 2, TET2, is downregulated or completely silenced in primary T-ALL. Moreover, the TET2 promoter was highly methylated in a group of patients, suggesting that TET2 itself can be silenced through DNA methylation in T-ALL. By treatment with HMAs, TET2 was demethylated in T-ALL cell lines and was one of few genes that was activated upon loss of DNA methylation, indicating that TET2 expression is regulated by DNA methylation in T-ALL cell lines. The development of a novel HMA, the DNMT1-specific inhibitor GSK-3685032, offers a tool to reveal the mechanism of action of the traditional HMAs, 5- azacytidine and decitabine, and to study the effects of acute loss of DNA methylation on cancer cells. We found that 5-azacytidine and decitabine are cytotoxic to T-ALL cells primarily by creating DNA double strand breaks. In contrast, GSK did not prompt a DNA damage response and instead reduced global DNA methylation to as little as 18% with limited cytotoxicity only occurring after levels of DNA methylation had dropped below 30%, a level of demethylation not achieved with DEC or AZA.T-ALL is more than two times more common in boys than girls and mutations in X-linked tumour suppressor genes that escape X inactivation, have been suggested as an underlying cause for the observed sex-bias. In theory, these aberrations would be more detrimental in XYmale cells than in XX-female cells due to the presence of an extra protective copy of the gene in females. We profiled DNA methylation during T cell development and created a map of sex-specific gene expression and expression from the inactive X chromosome, finding that some, but not all, suggested tumour suppressor genes in fact escape X inactivation. These results highlight the importance of profiling the healthy cells that T-ALL arises from to correctly judge the functional impact of gene dysregulation in cancer.In the last study, we aimed to investigate the role of N6-adenine methylation (6mdA) during T cell differentiation. While 6mdA is common in bacteria it is much rarer in humans. Nevertheless, 6mdA has previously been associated with several cellular processes, including cancer progression. Our study calls the presence of 6mdA in mammals into question by exposing limitations of the techniques used in its analysis. We show that contamination with bacterial DNA or 6mAcontaining RNA, nonspecific antibody binding, and low precision of third-generation sequencing techniques all hinder the detection and investigation of rare DNA modifications, such as 6mdA.Together, this work is an in-depth study of the function and the potential of DNA methylation in the biology of healthy and malignant T cells.
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| 2. |
- Haider, Zahra, 1988-
(author)
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DNA methylation signatures in precursor lymphoid neoplasms : with focus on clinical implications & the biology behind
- 2019
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Doctoral thesis (other academic/artistic)abstract
- Precursor lymphoid neoplasms, namely acute lymphoblastic leukemias (ALL) and lymphoblastic lymphomas (LBL), are characterized by an aggressive proliferation of malignant progenitor B- or T-cells. To improve risk classification at diagnosis, better prognostic and treatment stratifying biomarkers are needed. Altered DNA methylation pattern is a hallmark of neoplastic transformation, and has been employed as a molecular prognostic and predictive marker in various cancers, including hematological malignancies. Our research group previously identified a CpG island methylator phenotype (CIMP) panel that classified pediatric T-ALL patients into prognostic subgroups.The aim of this thesis was to evaluate distinct DNA methylation signatures in precursor lymphoid neoplasms, and to validate the prognostic value of CIMP classification in separate patient cohorts. Additionally, the biological mechanisms underlying the distinct CIMP methylation signatures in these malignancies were investigated.The prognostic relevance of CIMP classification was validated in an independent Nordic cohort of pediatric T-ALL patients. Combination of CIMP status with minimal residual disease (MRD) status, could further dissect the high-risk MRD positive T-ALL patients into two CIMP subgroups with significantly distinct outcomes. Furthermore, CIMP classification at diagnosis was shown to predict overall survival in relapsed BCP-ALL patients. CIMP methylation signatures were also identified in T-LBL patients, indicating a broader relevance of CIMP based classification in lymphoid malignancies. Investigating the biology behind CIMP methylation signatures showed the association of CIMP status with the proliferative history of the leukemic cells. A differential transcriptomic analysis revealed a correlation of CIMP subgroups with known T-ALL drivers, as well as with novel genes in T-ALL biology. Finally, we identified distinct DNA methylation patterns and genetic aberrations in T-ALL and T-LBL that might contribute to the different clinical presentation of these two diseases. In conclusion, we validated the prognostic significance of CIMP methylation signature in precursor lymphoid malignancies and identified transcriptomic profiles that associated with the subgroups. DNA methylation is a strong candidate for further risk classification in lymphoid neoplasms and our findings can contribute to the identification of new potential targets for treatment.
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