Project description:S49 (Neo) cells die by apoptosis following dexamethasone (dex) treatment whereas S49 cells expressing Bcl2 are resistant to glucocorticoid-induced cell death. Provocatively, mimicking the loss of intracellular potassium using a low dose of a microbial toxin that acts as a potassium ionophore in combination with dex overcame the resistance afforded by Bcl2 and killed the cells. The ability of the microbial toxin to trigger apoptosis of S49 (Bcl2) cells depends critically on the duration of dex treatment, as a 48-hour dex treatment sensitized the cells to die whereas a 24-hour exposure did not. To determine how the glucocorticoid signaling profile differs at these two time points, we performed RNAseq on RNA isolated from S49 (Neo) cells and S49 (Bcl2) cells treated with and without dex for 24 and 48 hours.

Project description:Activation of the MYC oncogene is common in B-cell lymphomas, and frequently associated with compensatory events that dampen Myc-induced apoptosis, such as over-expression of anti-apoptotic Bcl2-family proteins. For example, concurrent translocations of MYC and BCL2 in a subset of Diffuse large B-cell lymphoma (DLBCL) lead to the high-grade “double-hit” lymphoma subtype (DHL), characterized by dismal prognosis in the face of current front-line regimens, thus calling for the pursuit of tailored therapeutic strategies. Here, we show that Myc and Bcl2 modulate the sensitivity of B-cells to IACS-010759, a selective inhibitor of mitochondrial respiratory complex I. Myc activation in non-transformed lymphoid precursors suppressed endogenous Bcl2 and sensitized the cells to IACS-010759-induced apoptosis. Treatment with the Bcl2 inhibitor venetoclax also sensitized to IACS-010759, while overexpression of Bcl-2 was protective. IACS-010759 engaged an ATF4-driven Integrated Stress Response (ISR) with dual anti- and pro-apoptotic effects, the latter mediated by the CHOP transcription factor, which contributed to selective killing of Myc-overexpressing cells. In line with the above data, IACS-010759 and venetoclax synergized in killing human DHL cells, and showed strong combinatorial effects in a pre-clinical setting. In a Bcl2-negative Burkitt’s lymphoma cell line, instead, IACS-010759 synergized with the Mcl-1 inhibitor S63845. Altogether, our data point to the combination of IACS-010759 with distinct Bcl2-family inhibitors for therapeutic reactivation of the intrinsic apoptotic pathway in Myc-associated B-cell lymphomas

Project description:Drug-tolerant “persister” tumor cells underlie the emergence of drug-resistant clones contribute to relapse and disease progression; thus, identifying actionable targets that disable persisters and mitigate relapse are a high priority need. Although the BCL2-targeting agent venetoclax (ABT-199) has shown promising responses in mantle cell and double hit B cell lymphomas, resistance often arises, yet mechanistically how this occurs is unclear. Here we report that ABT-199 resistance can evolve from persister clones that have selective deletions at 18q21 that involve the drug target BCL2 and the apoptotic regulators Noxa (PMAIP1) and TCF4. Notably, reprogramming of super enhancers (SE) in persisters contributes to resistance, where there is a selection for SE-directed overexpression of the apoptotic regulator BCL2A1 and oncogenic transcription factors IKZF1 and FOXC1. At the same time, the SE reprogramming confers an opportunity for overcoming ABT-199 resistance. An unbiased drug screen on a platform that recapitulates the lymphoma microenvironment revealed that persisters are vulnerable to inhibitors of transcription initiation and elongation, and especially so to inhibitors of cyclin-dependent kinase 7 (CDK7) that is essential for transcription initiation. Specifically, CDK7 loss or inhibition eliminated the persister phenotype by disabling SE-driven expression of BCL2A1, IKZF1 and FOXC1. Thus, the co-treatment of ABT-199 with CDK7 inhibitors blocked the evolution of drug resistance, and provoked tumor regression in models of mantle cell lymphoma (MCL) and double hit lymphomas (DHL) that overexpress both MYC and BCL2. Together, these findings establish loss of apoptotic regulators and an adaptive transcriptional response as drug resistance mechanisms in lymphoma, more importantly, establish a rationale for transcription inhibition-based combination strategies to prevent and overcome drug resistance in B cell malignancies toward BCL2 inhibitor.

Project description:Combinatorial targeting of MYC/BCL2 double-hit lymphoma with mitochondrial complex I and BCL2 inhibitors

Project description:T-cell acute lymphoblastic leukemia (T-ALL) is an aggressive hematological malignancy, and novel therapeutics are much needed. Profiling patient leukemia’ drug sensitivities ex vivo, we discovered that 44.4% of childhood and 16.7% of adult T-ALL cases exquisitely respond to dasatinib. Applying network-based systems pharmacology analyses to examine signal circuitry, we identified preTCR-LCK activation as the driver of dasatinib sensitivity, and T-ALL-specific LCK dependency was confirmed in genome-wide CRISPR-Cas9 screens. Dasatinib-sensitive T-ALLs exhibited high BCL-XL and low BCL2 activity and venetoclax resistance. Discordant sensitivity of T-ALL to dasatinib and venetoclax is strongly correlated with T-cell differentiation, particularly with the dynamic shift in LCK vs. BCL2 activation. Finally, single-cell analysis identified leukemia heterogeneity in LCK and BCL2 signaling and T-cell maturation stage, consistent with dasatinib response. In conclusion, our results indicate that developmental arrest in T-ALL drives differential activation of preTCR-LCK and BCL2 signaling in this leukemia, providing unique opportunities for targeted therapy.

Project description:SOX9 was identified as a prognostic biomarker particularly in IGH-BCL2 translocated germinal center B cell (GCB) subtypes of the diffuse large B cell lymphoma (DLBCL) and plays a vital role in lymphomagenesis. However, the molecular mechanism that modulating the aberrant expression of SOX9 in this DLBCL subset remains unknown. We have demonstrated that SOX9 enhanced IGH-BCL2 positive DLBCL subset resistance to either chemotherapy or BCL2 inhibitor. Moreover, we found that inhibition of BCL2 downregulates SOX9 in IGH-BCL2 positive DLBCL subset. We further identified that IRF4 is a key regulator to mediate BCL2 induced SOX9 expression, alongside with the chip-seq confirmed that IRF4 is a key transcription factor for SOX9 in DLBCL. In addition, BCL2 promote IRF4 entry into the nucleus by enhancing its protein stability, via downregulating of proteosome ubiquitination process, and, therefore, enforce SOX9-mediated phenotypes. Finally, we showed in DLBCL cell lines and xenografted mice model that in vivo inhibition of IRF4 with hIRF4 antisense oligonucleotide (ASO) repressed lymphomagenesis and DLBCL chemoresistance. Altogether, our data support the conclusion that IRF4 plays an essential role in BCL2 induced upregulation of SOX9 expression, and targeting IRF4 may represent a promising therapeutic strategy to cure relapse and refractory DLBCL in the future.

Project description:Bcl2-induced vascular maturation

Project description:Modulation of pro- and antiapoptotic molecules in double-positive (CD4+CD8+) thymocytes following dexamethasone treatmen

Project description:RNA-seq data for 6 de novo GCB subtype DLBCL patients with BCL2 translocation

Project description:Taking the advantage of the human bone marrow (BM) scRNA-seq in Human cell atlas census of immune cells study, we resolved B lineage into comprehensive human B-cell development stages and identified their landscape in B-ALL. L-asparaginase is the cornerstone of combination protocols in acute lymphoblastic leukemia (ALL). After profiled B cell acute lymphoblastic leukemia (B-ALL) patient drug sensitivities ex vivo and applied network-based systems pharmacology analyses to examine signal circuitry, we revealed that the B-cell differentiation are correlated with the L-asparaginase response in B-ALL. Further multiomics analysis confirmed that L-asparaginase resistant B-ALL had higher percentage of Pre-pro-B like cells and less Pro-B like cells. By targeting BCL2, the key hub genes in Pre-pro-B cell network, Venetoclax combined with L-asparaginase can produce better outcome as demonstrated by in vitro and in vivo evaluations. In conclusion, our results identified B-ALL heterogeneity in L-asparaginase-resistant signature and BCL2 signaling and B-cell maturation stage, consistent with L-asparaginase response, providing unique opportunities for total clonal therapy.