Medical Biology - Theses

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End date: 2019 × Start date: 2019 × Type: PhD thesis × Subject: MCL1 × Subject: apoptosis ×

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    Control of the Intrinsic Pathway of Apoptosis
    Djajawi, Tirta ( 2019)
    Apoptosis is a cellular process of programmed cell death. The intrinsic pathway of apoptosis is triggered by mitochondrial outer membrane permeabilization, a point of no return that coincides with the release of cytochrome c into the cytosol where it activates the main effectors of cellular destruction: the caspases. The mitochondrial pathway that is centered on MOMP is tightly regulated by BCL2 family proteins, which includes some members that promote apoptosis and others that inhibit it. The interplay between these proteins with opposing roles determines whether a cell will die or survive. In a healthy cell, pro-survival BCL2 proteins inhibit the effector proteins BAX and BAK. BH3-only proteins are activated in response to cellular stress and promote apoptosis by neutralizing pro-survival proteins. Targeting BCL2 proteins to provoke apoptotic cell death has proven to be a successful strategy for cancer therapy with the BCL2-selective drug venetoclax exhibiting remarkable efficacy in treating cancers that rely on BCL2 for their survival. MCL1, a protein related to BCL2, is likewise critical for the survival of many cancer cells, making it another attractive anti-cancer drug target. Selective MCL1 inhibitors have been developed and are currently being evaluated in clinical trials to establish their safety and efficacy. Safety is a particular concern for MCL1 inhibitors because MCL1 is also essential for the survival of many cells in critical organs and tissues throughout the body. It remains to be seen if a sufficient therapeutic window will exist when MCL1 is targeted systemically. An alternative and potentially safer strategy to modulate MCL1 survival function would be to target pathways that regulate its activity in particular contexts. In Chapter 3 and 4, I focus on one such mechanism of MCL1 regulation: its turnover by the ubiquitin proteasome system. My work in Chapter 3 elucidated details of how MCL1 protein turnover is regulated by BH3-only protein NOXA. Using CRISPR-Cas9 screen, I discovered that the mitochondrial E3 ligase MARCH5, the E2 conjugating enzyme UBE2K and the mitochondrial outer membrane protein MTCH2 co-operate to mark MCL1 for degradation by the proteasome. I also demonstrated that this pathway is constitutively active in cells where NOXA is abundantly expressed and showed that manipulating NOXA expression in those cells impacts on MCL1 survival function. Having successfully demonstrated the power of CRISPR-Cas9 screen in Chapter 3, I undertook further screens in Chapter 4 to identify proteins, such as deubiquininating enzymes (DUBs), that might serve to enhance MCL1 protein stability. I did not identify any strong hits from these screens, possibly because multiple DUBs act redundantly on MCL1. Consistent with this hypothesis, only mild impacts on MCL1 protein stability were observed upon deleting DUBs previously reported to act on MCL1. Finally, in Chapter 5, I investigated how BH3 mimetics mimic the activity of BH3-only proteins to induce apoptosis. I studied how selective BH3 mimetic compounds perturb interactions throughout the BCL2 protein network beyond their direct protein targets. I showed that these second order impacts are crucial for effective killing. Apoptosis induced by the BCL2 selective inhibitor venetoclax, for example, typically also involves inhibition of MCL1. The impact on MCL1 in this context occurs as a consequence of displacing BH3-only proteins normally bound to BCL2.
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    The role of HECTD1 and MCL-1 in the regulation of normal and malignant haematopoiesis
    Brennan, Margs ( 2019)
    Cellular processes important for haematopoiesis are frequently perturbed in malignant cells. Accordingly, healthy immature progenitor cells and malignant cancer cells often share certain properties, e.g. rapid proliferation and self-renewal. Deciphering these developmental pathways can provide information about the critical drivers involved in neoplastic transformation and sustained cancer cell growth. Results in this thesis addresses the role of two proteins, HECTD1 and MCL-1, in haematopoiesis and haematological malignancies. HECTD1 is an E3 ubiquitin ligase required for mouse embryonic development, as homozygous loss of Hectd1 leads to embryonic lethality. HECTD1 is widely expressed in diverse tissues, including haematopoietic cells. However, its role in adult tissues in vivo has not been described. Therefore, we generated mice in which HECTD1 deletion was restricted to the haematopoietic system of adult mice. Analysis of these mice at steady state revealed small perturbations in certain T cell subsets. However, competitive reconstitution experiments revealed that HECTD1 deletion affects the haematopoietic stem and progenitor cell (HSPC) populations. Serial transplantation assays showed that loss of HECTD1 results in a defect in the self-renewal properties of mouse HSPCs. Interestingly, RNA sequencing of Hectd1-/- HSPCs revealed that HECTD1-deficiency led to increased expression of interferon regulated genes, suggesting that HECTD1 plays a critical role in the maintenance of HSPC populations by negatively regulating the interferon signalling pathway. Additionally, I employed the MLL AF9 mouse model of acute myeloid leukaemia and showed that HECTD1-deficiency significantly delayed the latency of tumour development in vivo compared to control mice. MCL-1 is a pro-survival regulator of the intrinsic apoptosis pathway. MCL-1 expression is integral to the survival of many different blood cell types, and to the development and sustained growth of many haematological malignancies. Recently a highly specific MCL-1 inhibitor, S63845, showing 6-fold higher affinity to human MCL-1 compared to mouse MCL-1 was described. To accurately test the efficacy and tolerability of S63845 in preclinical models of disease, we developed a humanised Mcl 1 (huMcl-1) mouse strain in which the genomic region of the murine Mcl-1 locus was replaced with the coding regions for human MCL-1. These mice are phenotypically indistinguishable from wild-type mice, and the intrinsic apoptotic pathway remains intact in their cells. However, as anticipated, huMcl-1 mice were more sensitive to S63845 than wild-type mice. To test whether malignant cells from the humanised MCL-1 mice also show higher sensitivity to S63845, we generated Eµ-Myc lymphomas on a huMcl-1 background. Lymphoma cell lines derived from huMcl-1;Eµ-Myc mice were ~6 times more sensitive to S63845 in vitro compared to Eµ-Myc lymphoma cells expressing mouse MCL-1. Transplantation of huMcl-1;Eµ-Myc lymphoma cells into huMcl-1 mice and treatment with S63845 resulted in tumour-free survival in >60% of mice. Furthermore, combining low doses of S63845 with sub-optimal doses of cyclophosphamide led to almost complete tumour regression. These results show that our huMcl-1 mouse model represents a valuable preclinical tool to test MCL-1 inhibitors, either alone or in combination with other anti-cancer agents, for a broad range of cancers, allowing accurate prediction of efficacy against tumour cells and on target toxicity to normal tissues.