Centre for Cancer Research - Research Publications

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    Characterization of a novel venetoclax resistance mutation (BCL2 Phe104Ile) observed in follicular lymphoma
    Blombery, P ; Birkinshaw, RW ; Nguyen, T ; Gong, J-N ; Thompson, ER ; Xu, Z ; Westerman, DA ; Czabotar, PE ; Dickinson, M ; Huang, DCS ; Seymour, JF ; Roberts, AW (WILEY, 2019-09)
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    Structures of BCL-2 in complex with venetoclax reveal the molecular basis of resistance mutations
    Birkinshaw, RW ; Gong, J-N ; Luo, CS ; Lio, D ; White, CA ; Anderson, MA ; Blombery, P ; Lessene, G ; Majewski, IJ ; Thijssen, R ; Roberts, AW ; Huang, DCS ; Colman, PM ; Czabotar, PE (NATURE PUBLISHING GROUP, 2019-06-03)
    Venetoclax is a first-in-class cancer therapy that interacts with the cellular apoptotic machinery promoting apoptosis. Treatment of patients suffering chronic lymphocytic leukaemia with this BCL-2 antagonist has revealed emergence of a drug-selected BCL-2 mutation (G101V) in some patients failing therapy. To understand the molecular basis of this acquired resistance we describe the crystal structures of venetoclax bound to both BCL-2 and the G101V mutant. The pose of venetoclax in its binding site on BCL-2 reveals small but unexpected differences as compared to published structures of complexes with venetoclax analogues. The G101V mutant complex structure and mutant binding assays reveal that resistance is acquired by a knock-on effect of V101 on an adjacent residue, E152, with venetoclax binding restored by a E152A mutation. This provides a framework for considering analogues of venetoclax that might be effective in combating this mutation.
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    CAF hierarchy driven by pancreatic cancer cell p53-status creates a pro-metastatic and chemoresistant environment via perlecan
    Vennin, C ; Melenec, P ; Rouet, R ; Nobis, M ; Cazet, AS ; Murphy, KJ ; Herrmann, D ; Reed, DA ; Lucas, MC ; Warren, SC ; Elgundi, Z ; Pinese, M ; Kalna, G ; Roden, D ; Samuel, M ; Zaratzian, A ; Grey, ST ; Da Silva, A ; Leung, W ; Mathivanan, S ; Wang, Y ; Braithwaite, AW ; Christ, D ; Benda, A ; Parkin, A ; Phillips, PA ; Whitelock, JM ; Gill, AJ ; Sansom, OJ ; Croucher, DR ; Parker, BL ; Pajic, M ; Morton, JP ; Cox, TR ; Timpson, P ; Johns, AL ; Chantrill, LA ; Chou, A ; Steinmann, A ; Arshi, M ; Dwarte, T ; Froio, D ; Pereira, B ; Ritchie, S ; Chambers, CR ; Metcalf, X ; Waddell, N ; Pearson, J ; Patch, A-M ; Nones, K ; Newell, F ; Mukhopadhyay, P ; Addala, V ; Kazakoff, S ; Holmes, O ; Leonard, C ; Wood, S ; Grimmond, SM ; Hofmann, O ; Christ, A ; Bruxner, T ; Samra, JS ; Pavlakis, N ; High, HA ; Asghari, R ; Merrett, ND ; Pavey, D ; Das, A ; Cosman, PH ; Ismail, K ; O'Connnor, C ; Stoita, A ; Williams, D ; Spigellman, A ; Lam, VW ; McLeod, D ; Kirk, J ; Kench, JG ; Grimison, P ; Cooper, CL ; Sandroussi, C ; Goodwin, A ; Mead, RS ; Tucker, K ; Andrews, L ; Texler, M ; Forest, C ; Epari, KP ; Ballal, M ; Fletcher, DR ; Mukhedkar, S ; Zeps, N ; Beilin, M ; Feeney, K ; Nguyen, NQ ; Ruszkiewicz, AR ; Worthley, C ; Chen, J ; Brooke-Smith, ME ; Papangelis, V ; Clouston, AD ; Barbour, AP ; O'Rourke, TJ ; Fawcett, JW ; Slater, K ; Hatzifotis, M ; Hodgkinson, P ; Nikfarjam, M ; Eshleman, JR ; Hruban, RH ; Wolfgang, CL ; Lawlor, RT ; Beghelli, S ; Corbo, V ; Scardoni, M ; Bassi, C ; Biankin, A ; Dixon, J ; Jamieson, NB ; Chang, DK (NATURE PORTFOLIO, 2019-08-12)
    Heterogeneous subtypes of cancer-associated fibroblasts (CAFs) coexist within pancreatic cancer tissues and can both promote and restrain disease progression. Here, we interrogate how cancer cells harboring distinct alterations in p53 manipulate CAFs. We reveal the existence of a p53-driven hierarchy, where cancer cells with a gain-of-function (GOF) mutant p53 educate a dominant population of CAFs that establish a pro-metastatic environment for GOF and null p53 cancer cells alike. We also demonstrate that CAFs educated by null p53 cancer cells may be reprogrammed by either GOF mutant p53 cells or their CAFs. We identify perlecan as a key component of this pro-metastatic environment. Using intravital imaging, we observe that these dominant CAFs delay cancer cell response to chemotherapy. Lastly, we reveal that depleting perlecan in the stroma combined with chemotherapy prolongs mouse survival, supporting it as a potential target for anti-stromal therapies in pancreatic cancer.
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    Combining BH3-mimetics to target both BCL-2 and MCL1 has potent activity in pre-clinical models of acute myeloid leukemia
    Moujalled, DM ; Pomilio, G ; Ghiurau, C ; Ivey, A ; Salmon, J ; Rijal, S ; Macraild, S ; Zhang, L ; Teh, T-C ; Tiong, I-S ; Lan, P ; Chanrion, M ; Claperon, A ; Rocchetti, F ; Zichi, A ; Kraus-Berthier, L ; Wang, Y ; Hamovic, E ; Morris, E ; Colland, F ; Segal, D ; Huang, D ; Roberts, AW ; Maragno, AL ; Lessene, G ; Geneste, O ; Wei, AH (NATURE PUBLISHING GROUP, 2019-04)
    Improving outcomes in acute myeloid leukemia (AML) remains a major clinical challenge. Overexpression of pro-survival BCL-2 family members rendering transformed cells resistant to cytotoxic drugs is a common theme in cancer. Targeting BCL-2 with the BH3-mimetic venetoclax is active in AML when combined with low-dose chemotherapy or hypomethylating agents. We now report the pre-clinical anti-leukemic efficacy of a novel BCL-2 inhibitor S55746, which demonstrates synergistic pro-apoptotic activity in combination with the MCL1 inhibitor S63845. Activity of the combination was caspase and BAX/BAK dependent, superior to combination with standard cytotoxic AML drugs and active against a broad spectrum of poor risk genotypes, including primary samples from patients with chemoresistant AML. Co-targeting BCL-2 and MCL1 was more effective against leukemic, compared to normal hematopoietic progenitors, suggesting a therapeutic window of activity. Finally, S55746 combined with S63845 prolonged survival in xenograft models of AML and suppressed patient-derived leukemia but not normal hematopoietic cells in bone marrow of engrafted mice. In conclusion, a dual BH3-mimetic approach is feasible, highly synergistic, and active in diverse models of human AML. This approach has strong clinical potential to rapidly suppress leukemia, with reduced toxicity to normal hematopoietic precursors compared to chemotherapy.
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    Targeting enhancer switching overcomes non-genetic drug resistance in acute myeloid leukaemia
    Bell, CC ; Fenne, KA ; Chan, Y-C ; Rambow, F ; Yeung, MM ; Vassiliadis, D ; Lara, L ; Yeh, P ; Martelotto, LG ; Rogiers, A ; Kremer, BE ; Barbash, O ; Mohammad, HP ; Johanson, TM ; Burr, ML ; Dhar, A ; Karpinich, N ; Tian, L ; Tyler, DS ; MacPherson, L ; Shi, J ; Pinnawala, N ; Fong, CY ; Papenfuss, AT ; Grimmond, SM ; Dawson, S-J ; Allan, RS ; Kruger, RG ; Vakoc, CR ; Goode, DL ; Naik, SH ; Gilan, O ; Lam, EYN ; Marine, J-C ; Prinjha, RK ; Dawson, MA (NATURE PORTFOLIO, 2019-06-20)
    Non-genetic drug resistance is increasingly recognised in various cancers. Molecular insights into this process are lacking and it is unknown whether stable non-genetic resistance can be overcome. Using single cell RNA-sequencing of paired drug naïve and resistant AML patient samples and cellular barcoding in a unique mouse model of non-genetic resistance, here we demonstrate that transcriptional plasticity drives stable epigenetic resistance. With a CRISPR-Cas9 screen we identify regulators of enhancer function as important modulators of the resistant cell state. We show that inhibition of Lsd1 (Kdm1a) is able to overcome stable epigenetic resistance by facilitating the binding of the pioneer factor, Pu.1 and cofactor, Irf8, to nucleate new enhancers that regulate the expression of key survival genes. This enhancer switching results in the re-distribution of transcriptional co-activators, including Brd4, and provides the opportunity to disable their activity and overcome epigenetic resistance. Together these findings highlight key principles to help counteract non-genetic drug resistance.