Leukemic Progenitor Cells Research Articles

Transcriptomic analysis delineates potential regulatory network as therapeutic alternatives in chronic myeloid leukemia

BackgroundChronic myeloid leukemia (CML) relapse and progression after discontinuation of tyrosine kinase inhibitors (TKI) therapy in the chronic phase (CP) are attributed to primitive quiescent leukemic progenitor cells (LPCs). This study aimed to identify key differentially expressed genes (DEGs) involved in molecular pathways alternative to BCR-ABL, which could lead to the eradication of leukemic stem/progenitor cells.MethodsmRNA expression profiling dataset comprising newly diagnosed untreated CP CML leukemic progenitor cell samples n=5 and normal hematopoietic progenitor cell samples n=5 were selected for DEGs identification. A weighted gene co-expression network was constructed to identify significant hub modules. Protein–protein interaction (PPI) network construction and pathway enrichment analysis provided additional information on the biological pathways involved. The genes involved in the resultant PPI network were subjected to a gene transcriptional regulatory network based on transcription factors (TFs) and microRNAs (miRNAs) involved in the target genes.ResultsA total of 709 genes that were differentially expressed among those corresponding to p<0.05 and log2FC>0.5 0.5$$\\end{document}]]>. The WGCNA showed a significant hub module comprising 267 DEGs. The major pathways of the hub genes involved in the PPI network at the highest confidence score >0.9 0.9$$\\end{document}]]> were related to mitochondrial translational elongation. The integrated gene transcriptional regulatory network revealed a TF (ETS1), two miRNAs (miR-34a-5p and miR-205-5p) targeting a hub gene (GFM1) as the highest-order motif or subnetwork in the three-node miRNA feed-forward loop.ConclusionsThe study suggests that the regulatory feed-forward loop may provide a potential therapeutic target in CML. Consequently, the mitochondrial translation pathway may be explored as an alternative to BCR-ABL pathways, which could aid in eliminating or increasing sensitization of CML progenitor/stem cells to TKI treatment.

Targeting IL-1/IRAK1/4 signaling in Acute Myeloid Leukemia Stem Cells Following Treatment and Relapse.

Therapies for acute myeloid leukemia (AML) face formidable challenges due to relapse, often driven by leukemia stem cells (LSCs). Strategies targeting LSCs hold promise for enhancing outcomes, yet paired comparisons of functionally defined LSCs at diagnosis and relapse remain underexplored. We present transcriptome analyses of functionally defined LSC populations at diagnosis and relapse, revealing significant alterations in IL-1 signaling. Interleukin-1 receptor type I (IL1R1) and interleukin-1 receptor accessory protein (IL1RAP) were notably upregulated in leukemia stem and progenitor cells at both diagnosis and relapse. Knockdown of IL1R1 and IL1RAP reduced the clonogenicity and/or engraftment of primary human AML cells. In leukemic MLL-AF9 mice, Il1r1 knockout reduced LSC frequency and extended survival. To target IL-1 signaling at both diagnosis and relapse, we developed UR241-2, a novel interleukin-1 receptor-associated kinase 1 and 4 (IRAK1/4) inhibitor. UR241-2 robustly suppressed IL-1/IRAK1/4 signaling, including NF-κB activation and phosphorylation of p65 and p38, following IL-1 stimulation. UR241-2 selectively inhibited LSC clonogenicity in primary human AML cells at both diagnosis and relapse, while sparing normal hematopoietic stem and progenitor cells. It also reduced AML engraftment in leukemic mice. Our findings highlight the therapeutic potential of UR241-2 in targeting IL-1/IRAK1/4 signaling to eradicate LSCs and improve AML outcomes.

The BIM deletion polymorphism potentiates the survival of leukemia stem and progenitor cells and impairs response to targeted therapies.

One sixth of human cancers harbor pathogenic germline variants, but few studies have established their functional contribution to cancer outcomes. Here, we developed a humanized mouse model harboring a common East Asian polymorphism, the BIM deletion polymorphism (BDP), which confers resistance to oncogenic kinase inhibitors through generation of non-apoptotic splice isoforms. However, despite its clear role in mediating bulk resistance in patients, the BDP's role in cancer stem and progenitor cells, which initiate disease and possess altered BCL-2 rheostats compared to differentiated tumor cells, remains unknown. To study the role of the BDP in leukemia initiation, we crossed the BDP mouse into a chronic myeloid leukemia (CML) model. We found that the BDP greatly enhanced the fitness of CML cells with a three-fold greater competitive advantage, leading to more aggressive disease. The BDP conferred almost complete resistance to cell death induced by imatinib in CML stem and progenitor cells (LSPCs). Using BH3 profiling, we identified a novel therapeutic vulnerability of BDP LSPCs to MCL-1 antagonists, which we confirmed in primary human LSPCs, and in vivo. Our findings demonstrate the impact of human polymorphisms on the survival of LSPCs and highlight their potential as companion diagnostics for tailored therapies.

Hyperactivation of NF-κB signaling in splicing factor mutant myelodysplastic syndromes and therapeutic approaches

The transcription factor NF-κB plays a critical role in the control of innate and adaptive immunity and inflammation. Several recent studies have demonstrated that the mutation of different splicing factor genes, including SF3B1, SRSF2 and U2AF1, in myelodysplastic syndromes (MDS) and acute myeloid leukemia (AML) result in hyperactive NF-κB signaling through the aberrant splicing of different target genes. The presence of U2AF1 and SF3B1 mutations in the bone marrow cells of MDS and AML patients induces oncogenic isoforms of the target gene IRAK4, leading to hyperactivation of NF-κB signaling and an increase in the fitness of leukemic stem and progenitor cells (LSPCs). The potent IRAK4 inhibitor CA-4948 has shown efficacy in both pre-clinical studies and MDS clinical trials, with splicing factor mutant patients showing the higher response rates. Emerging data has, however, revealed that co-targeting of IRAK4 and its paralog IRAK1 is required to maximally suppress LSPC function in vitro and in vivo by inducing cellular differentiation. These findings provide a link between the presence of the commonly mutated splicing factor genes and activation of innate immune signaling pathways in myeloid malignancies and have important implications for targeted therapy in these disorders.

IL-9 secreted by leukemia stem cells induces Th1-skewed CD4+ T cells, which promote their expansion

AbstractIn acute myeloid leukemia (AML), leukemia stem cells (LSCs) and leukemia progenitor cells (LPCs) interact with various cell types in the bone marrow (BM) microenvironment, regulating their expansion and differentiation. To study the interaction of CD4+ and CD8+ T cells in the BM with LSCs and LPCs, we analyzed their transcriptome and predicted cell-cell interactions by unbiased high-throughput correlation network analysis. We found that CD4+ T cells in the BM of patients with AML were activated and skewed toward T-helper (Th)1 polarization, whereas interleukin-9 (IL-9)–producing (Th9) CD4+ T cells were absent. In contrast to normal hematopoietic stem cells, LSCs produced IL-9, and the correlation modeling predicted IL9 in LSCs as a main hub gene that activates CD4+ T cells in AML. Functional validation revealed that IL-9 receptor signaling in CD4+ T cells leads to activation of the JAK-STAT pathway that induces the upregulation of KMT2A and KMT2C genes, resulting in methylation on histone H3 at lysine 4 to promote genome accessibility and transcriptional activation. This induced Th1-skewing, proliferation, and effector cytokine secretion, including interferon gamma (IFN-γ) and tumor necrosis factor α (TNF-α). IFN-γ and, to a lesser extent, TNF-α produced by activated CD4+ T cells induced the expansion of LSCs. In accordance with our findings, high IL9 expression in LSCs and high IL9R, TNF, and IFNG expression in BM–infiltrating CD4+ T cells correlated with worse overall survival in AML. Thus, IL-9 secreted by AML LSCs shapes a Th1-skewed immune environment that promotes their expansion by secreting IFN-γ and TNF-α.

WTAP and m6A-modified circRNAs modulation during stress response in acute myeloid leukemia progenitor cells

N6-methyladenosine (m6A) is one of the most prevalent and conserved RNA modifications. It controls several biological processes, including the biogenesis and function of circular RNAs (circRNAs), which are a class of covalently closed-single stranded RNAs. Several studies have revealed that proteotoxic stress response induction could be a relevant anticancer therapy in Acute Myeloid Leukemia (AML). Furthermore, a strong molecular interaction between the m6A mRNA modification factors and the suppression of the proteotoxic stress response has emerged. Since the proteasome inhibition leading to the imbalance in protein homeostasis is strictly linked to the stress response induction, we investigated the role of Bortezomib (Btz) on m6A regulation and in particular its impact on the modulation of m6A-modified circRNAs expression. Here, we show that treating AML cells with Btz downregulated the expression of the m6A regulator WTAP at translational level, mainly because of increased oxidative stress. Indeed, Btz treatment promoted oxidative stress, with ROS generation and HMOX-1 activation and administration of the reducing agent N-acetylcysteine restored WTAP expression. Additionally, we identified m6A-modified circRNAs modulated by Btz treatment, including circHIPK3, which is implicated in protein folding and oxidative stress regulation. These results highlight the intricate molecular networks involved in oxidative and ER stress induction in AML cells following proteotoxic stress response, laying the groundwork for future therapeutic strategies targeting these pathways.

Activation of non-classical Wnt signaling pathway effectively enhances HLA-A presentation in acute myeloid leukemia.

The escape from T cell-mediated immune surveillance is an important cause of death for patients with acute myeloid leukemia (AML). This study aims to identify clonal heterogeneity in leukemia progenitor cells and explore molecular or signaling pathways associated with AML immune escape. Single-cell RNA sequencing (scRNA-seq) was performed to identified AML-related cellular subsets, and intercellular communication was analyzed to investigate molecular mechanisms associated with AML immune escape. Bulk RNA sequencing (RNA-seq) was performed to screen differentially expressed genes (DEGs) related to hematopoietic stem cell progenitors (HSC-Prog) in AML, and critical ore signaling pathways and hub genes were found by Gene Set Enrichment Analysis (GSEA), Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) enrichment analysis. The mRNA level of the hub gene was verified using quantitative real-time PCR (qRT-PCR) and the protein level of human leukocyte antigen A (HLA-A) using enzyme-linked immuno sorbent assay (ELISA). scRNA-seq analysis revealed a large heterogeneity of HSC-Prog across samples, and the intercellular communication analysis indicated a strong association between HSC-Prog and CD8+-T cells, and HSC-Prog also had an association with HLA-A. Transcriptome analysis identified 1748 DEGs, enrichment analysis results showed that non-classical wnt signaling pathway was associated with AML, and 4 pathway-related genes (RHOA, RYK, CSNK1D, NLK) were obtained. After qRT-PCR and ELISA validation, hub genes and HLA-A were found to be down-regulated in AML and up-regulated after activation of the non-classical Wnt signaling pathway. In this study, clonal heterogeneity of HSC-Prog cells in AML was identified, non-classical wnt signaling pathways associated with AML were identified, and it was verified that HLA-A could be upregulated by activation of non-classical wnt signaling, thereby increasing antigen presentation.

BRD4 degraders may effectively counteract therapeutic resistance of leukemic stem cells in AML and ALL.

Acute myeloid leukemia (AML) and acute lymphoblastic leukemia (ALL) are life-threatening hematopoietic malignancies characterized by clonal expansion of leukemic blasts in the bone marrow and peripheral blood. The epigenetic reader BRD4 and its downstream effector MYC have recently been identified as potential drug targets in human AML and ALL. We compared anti-leukemic efficacies of the small-molecule BET inhibitor JQ1 and the recently developed BRD4 degraders dBET1 and dBET6 in AML and ALL cells. JQ1, dBET1, and dBET6 were found to suppress growth and viability in all AML and ALL cell lines examined as well as in primary patient-derived AML and ALL cells, including CD34+/CD38- and CD34+/CD38+ leukemic stem and progenitor cells, independent of the type (variant) of leukemia or molecular driver expressed in leukemic cells. Moreover, we found that dBET6 overcomes osteoblast-induced drug resistance in AML and ALL cells, regardless of the type of leukemia or the drug applied. Most promising cooperative or even synergistic drug combination effects were seen with dBET6 and the FLT3 ITD blocker gilteritinib in FLT3 ITD-mutated AML cells, and with dBET6 and the multi-kinase blocker ponatinib in BCR::ABL1+ ALL cells. Finally, all BRD4-targeting drugs suppressed interferon-gamma- and tumor necrosis factor-alpha-induced expression of the resistance-related checkpoint antigen PD-L1 in AML and ALL cells, including LSC. In all assays examined, the BRD4 degrader dBET6 was a superior anti-leukemic drug compared with dBET1 and JQ1. Together, BRD4 degraders may provide enhanced inhibition of multiple mechanisms of therapy resistance in AML and ALL.

Acute myeloid leukemia-derived bone marrow mesenchymal cells exhibit improved support for leukemic cell proliferation

IntroductionThe bone marrow (BM) microenvironment plays a significant role in acute myeloid leukemia (AML) genesis and there is evidence that BM mesenchymal stromal cells (BMMSCs) can support leukemia progenitor cell proliferation and survival and provide resistance to cytotoxic therapies. Hypothesis and methodNevertheless, currently unknown are the relevance of the spatial localization of AML cells relative to the BMMSCs and whether BMMSCs from patients with AML and healthy subjects have similar properties. To address these issues, we performed a differential gene expression analysis using RNA-sequencing data generated from healthy donors (HDs) and leukemic BMMSCs. ResultsThe Gene Set Enrichment Analysis (GSEA) revealed that leukemic BMMSCs were associated with the terms “positive regulation of cell cycle”, “angiogenesis” and “signaling by the estimated glomerular filtration rate (eGFR)”, whereas healthy donor (HD)-derived BMMSCs were associated with “programmed cell death in response to the reactive oxygen species (ROS)”, “negative regulation of the cytochrome C from the mitochondria” and “interferon signaling”. Next, we evaluated the mitochondrial superoxide production in AML cells in a co-culture layered model. The superoxide production was reduced in leukemic cells in close contact (adhered to the surface or beneath the cell layer) with BMMSCs, indicating lower oxidative stress. ConclusionTaken together, our results suggest that AML-derived BMMSCs are transcriptionally rewired and can reduce the metabolic stress of leukemic cells.

UBE2N Regulates Oncoprotein Networks in Myeloid Malignancies

Acute myeloid leukemia (AML) and myelodysplastic syndromes (MDS) originate from clonal mutant hematopoietic stem and progenitor cells, referred to as leukemic stem and progenitor cells (LSPCs). Ubiquitination is an essential process for various cellular maintenance functions, including protein degradation and scaffolding, which is often perturbed in a variety of cancers. Ubiquitination of protein substrates involves three related enzymes: the E1 activating enzyme, the E2 conjugating enzyme, and the E3 ligase. In humans, there are up to 40 E2 conjugating enzymes, among which Ubiquitin conjugating enzyme E2 N (UBE2N) stands out as one of the most crucial and overexpressed E2 enzymes in AML cells. Our recent study reported that UBE2N is a druggable target in MDS and AML (Barreyro et al., Science Translational Medicine, 2022), and we found that its catalytic active site cysteine 87 is required for various AML mouse models, including MLL-AF9, FLT3-ITD, AML1-ETO9a, and MN1 (unpublished). These observations indicate that the catalytic function of UBE2N is critical for AML cells but dispensable for normal hematopoiesis. To examine the active state of UBE2N, we investigated the “charged” version of UBE2N, which contains a ubiquitin bound to cysteine 87, in normal hematopoietic cells and in a AML cell line panels. Our findings confirmed that the activated form of UBE2N is highly expressed in human AML cells compared to normal hematopoietic cells. UBE2N exclusively synthesizes Lysine-63 (K63)-linked polyubiquitin chains on target proteins in conjunction with selected E3 ligases, leading to the stabilization and/or activation of protein substrates. To identify the relevant targets of UBE2N in AML, we conducted a ubiquitin-enrichment followed by a proteomic analysis in isogenic UBE2N-deficient AML cells compared to WT AML cells. We identified ~300 proteins that are ubiquitinated by UBE2N. Importantly, UBE2N regulates a network of leukemia-associated oncoproteins, including SYNCRIP, HUWE1, NPM1, TYK2, IKBKG, VAV1, BAX, IGF2BP2, IRF4, IRAK4, RBMX, STAT3, and BTK. UBE2N can interact with various E3 ligases in a cell- and context-dependent manner. To gain insight into the major E3 ligase that cooperates with activated UBE2N in AML, we performed a proximity-based labeling assay followed by mass spectrometry. This interactome screen identified Tripartite motif containing 21 (TRIM21) as the top E3 ligase that partners with UBE2N in AML cells. TRIM21 is overexpressed in AML patients compared to healthy controls. Moreover, deletion of TRIM21 in AML cells impaired cell viability and proliferation in vitro and prolonged survival in a xenograft model in vivo, which phenocopies the loss of UBE2N. Importantly, restoration of TRIM21 rescued the functional defect of UBE2N-deficient AML cells, indicating that the UBE2N-TRIM21 axis is operational in AML. To prioritize the UBE2N-dependent oncoprotein network, we focused on UBE2N-TRIM21 regulated signaling in AML. For this, a gene expression analysis was performed in UBE2N-deficient AML cells that were restored with TRIM21. The top UBE2N-TRIM21 oncoprotein network that emerged was related to interferon-STAT signaling. Additionally, both UBE2N and TRIM21 were found to regulate STAT3 ubiquitination. Deletion or inhibition of UBE2N catalytic activity significantly reduced total and activated STAT3 in AML cells. Finally, the expression of constitutively active STAT3 partially restored the functional defect of AML cells treated with a UBE2N inhibitor, indicating that STAT3 function, a known driver of LSPCs, is regulated via the UBE2N-TRIM21 axis in AML. In summary, our data reveal that UBE2N regulates oncoprotein networks in AML and that inhibiting UBE2N catalytic function, such as with small molecule inhibitors, effectively suppresses LSPCs.

Monoclonal Antibodies Targeting LIGHT Block Ltbr Signalling and Eliminate Acute Myeloid Leukemia Stem Cells

Introduction Acute myeloid leukemia (AML) is a molecular heterogeneous disease that originates from the malignant transformation of a hematogenic stem- or progenitor cells resulting in a leukemia stem cell (LSC). LSCs are a main cause of resistance to therapy and relapse. Despite recent advances in targeted therapy and immunotherapy, prognosis for elderly patients not fit do undergo intensive therapy remains poor. We recently documented that targeting CD70, the ligand of the tumor necrosis factor receptor (TNFR) CD27, by the antibody-dependent cell-mediated cytotoxicity (ADCC)-enhanced monoclonal antibody (mAb) cusatuzumab eliminates LSC. We now studied the role of the related TNFR lymphotoxin b receptor (LTbR) with its ligand LIGHT in the pathogenesis of AML in mice and humans and developed a LIGHT targeting mAb to specifically eliminate LSCs. Experimental design We investigated the impact of LIGHT/LTbR signalling in AML development by using the retrovirally-induced MLL-AF9 syngeneic AML mouse model. Light-, Ltbr -deficient and control MLL-AF9 transduced LSCs were injected intravenously into non-irradiated BL/6 recipient mice. AML development was evaluated by analysing MLL-AF9-GFP-positive leukemic cells in blood, spleen, and bone marrow (BM). BM LSC were phenotypically characterized by FACS and functionally by performing colony forming unit (CFU) assays in vitro and by secondary transplantations of LSCs including limited dilution assays (LDA) in vivo. Correlative survival analysis for LIGHT and LTbR expression was performed on a publicly available gene dataset (GSE6891). LIGHT and LTBR protein expression was analysed on primary AML CD34 + leukemic stem and progenitor cells (LSPCs) and control human CD34 + hematopoietic stem cell and progenitor cells (HSCPs). LIGHT/LTbR signalling was blocked by either siRNA treatment or by treatment with novel LIGHT-targeting mAb. The effect of blocking LIGHT/LTbR-signalling was analysed in vitro by CFU assays, RNA-sequencing and xenotransplant experiments in vivo. LIGHT-targeting mAbs were generated by immunization of llamas and phage display selections followed by cloning of FABs into a human backbone (hIgG1). Clones were selected based on their blocking potency of receptor/ligand interaction using competition ELISA and FACS-based cell binding affinity assays. ADCC-enhanced anti-LIGHT mAbs were generated via POTELLIGENT® technology. Anti-LIGHT mAbs that specifically block the interaction of LIGHT/LTBR with deficiency in effector functions (Fc-death) were produced by amino acid substitutions in the CH2 domain of the parental clone. Results LTbR was expressed by HSCs and AML LSCs. In contrast, LIGHT was only expressed on murine and human LSCs but not normal HSCs. The absence of LIGHT or its receptor LTbR on LSCs resulted in significantly prolonged survival and decreased numbers of LSC in BM of AML mice. Light -/- and Ltbr -/- LSCs had a reduced CFU capacity compared to control LSCs. Similarly, inhibition of LIGHT-signalling on LSCs via LTbR-Ig significantly reduced colony formation. Moreover, secondary transplantation of Light -/-LSCs resulted in prolonged survival compared to Light-proficient LSCs. An LDA analysis revealed a 11-fold reduction of the LSC frequency in BM in the absence of LIGHT or LTBR. Similarly, inhibiting LIGHT signalling by siLIGHT RNA in human AML LSPCs resulted in reduced CFU capacity compared to control siRNA treatment. In addition, a GEO analysis revealed that low LIGHT or LTbR mRNA levels correlated with improved overall survival in AML patients. After immunizations of llamas and phage-display selection three humanized anti-LIGHT mAbs with high blocking and high binding efficiency were selected (mAb10F11 and 12C2 specific for human LIGHT and the cross-reactive murine/human 9F6 mAB). Incubation of LSCs with the blocking mAbs significantly reduced CFU capacity. HSPCs from healthy donors remained unaffected by the treatment. A gene expression analysis revealed that blocking LIGHT/LTbR-signalling in LSCs reduced stemness and promoted differentiation. In addition, ADCC-enhanced mAbs activated NK cells to eliminate LIGHT-expressing LSCs. Our findings reveal that LIGHT/LTbR-signalling is crucial for the pathogenesis of AML and especially for the maintenance and expansion of LSCs. We developed and validated novel LIGHT targeting mAbs in vitro and in vivo for further development in clinical trials.

The Zymogen Form of Caspase-1 Is Required to Fine Tune Excessive Cell-Intrinsic Inflammation in Acute Myeloid Leukemia

Acute Myeloid Leukemia (AML) is characterized by the expansion of clonally-derived mutant hematopoietic stem and progenitor cells. Many patients do not respond to standard chemotherapy because AML cells acquire mutations that exploit inflammatory and cell death pathways, allowing them to evade cell death. Targeted therapies are urgently needed to block AML cell pro-survival and inflammatory signaling for more effective outcomes. One promising area of interest is Caspase-1 (CASP1), a cysteine-aspartic acid protease responsible for cleaving the precursors of interleukin-1β (IL-1β) and Gasdermin D, which induces pyroptosis, into their active mature peptides. In myeloid malignancies, IL-1β levels are significantly elevated, and pyroptosis has been linked to ineffective hematopoiesis as observed in MDS, thereby implicating CASP1. CASP1 is typically expressed as a zymogen (Pro-CASP1) that can be cleaved into an active enzyme. In this report, we present a novel and unexpected role for Pro-CASP1, which appears to be independent of its proteolytic function, in MDS/AML leukemic cells. Pyroptosis, an inflammatory cell death mechanism, is driven by CASP1-mediated osmotic lysis and IL-1b secretion. Notably, CASP1 expression is significantly higher in AML patients compared to healthy hematopoietic cells, and elevated CASP1 expression in AML patients correlates with shorter overall survival. In leukemic cells, CASP1 primarily exists in its zymogen form, lacking the ability to induce pyroptosis. It is thus unexpected that elevated CASP1 expression, which typically leads to heightened susceptibility to pyroptotic cell death, does not result in pyroptosis in leukemic cells, and the underlying mechanisms for this evasion remain unknown. To investigate Pro-CASP1's significance in AML cells, we used CRISPR-Cas9 to create Pro-CASP1 knockout (Pro-CASP1 KO) human isogenic MDS and AML cell lines (THP1 and MDSL). Pro-CASP1 KO MDS/AML cells showed reduced cell growth and leukemic colony forming potential in methylcellulose compared to isogenic WT control cells. When Pro-CASP1 KO THP1 AML cells were transplanted into immunocompromised mice, the loss of Pro-CASP1 significantly reduced leukemic cell burden and extended overall survival. We next preformed experiments to probe the mechanism of action of Pro-CASP1 in AML cells. Previous studies suggest that Pro-CASP1 can function as a scaffold to elicit downstream signaling without cleaving into its activated form. The functional defect in Pro-CASP1 KO THP1 AML cells was rescued with full-length Pro-CASP1, but not with a scaffolding mutant of CASP1, indicating a specific dependency of leukemic cells on the zymogen form of CASP1. To precisely delineate which domains of Pro-CASP1 are essential for AML, we performed a tiled CRISPR dropout screen in MDSL and THP1 cells. The results showed similar CRISPR-Knockout High Sensitivity (CKHS) domain footprints in both cell lines mapping to the N-terminal CARD and the Inter-Domain Linker (IDL) domains. These results indicate that Pro-CASP1's proteolytic function was found to be dispensable, whereas the CARD domain, a scaffolding region, was crucial for leukemogenesis. We next investigated how loss of Pro-CASP1 affects inflammatory signaling in AML cells. Deletion of Pro-CASP1 in THP1 AML cells led to excessive and constitutive activation of NF-kB as indicated by nuclear translocation and phosphorylation of p65/RelA. Restoring NF-kB regulation using the inhibitor of kappa B (IkB) super-repressor (IkB-SR) was sufficient to reverse the leukemic progenitor defect and cell viability in Pro-CASP1 KO AML cells. These findings suggest that Pro-CASP1 is required for AML cells to finetune canonical NF-kB activation. Conversely, loss of Pro-CASP1 results in excessive NF-kB activation that is incompatible with AML, consistent with previous observations (Ellegast et al., Cancer Discovery 2022). In summary, Pro-CASP1 serves as a critical signaling hub, fine-tuning NF-kB pathways independently of its proteolytic function in leukemic cells. Its loss exposes leukemic cells to functional and therapeutic vulnerabilities.

A Phase 1b/2 Trial of Liposomal Cytarabine and Daunorubicin (CPX-351) in Intermediate to High-Risk Acute Myeloid Leukemia for Patients Who Have Failed an Initial Cycle of Induction Chemotherapy

Introduction Acute myeloid leukemia (AML) is a heterogeneous hematologic malignancy with a high rate of recurrence following standard chemotherapy that continues to have a poor prognosis. While there have been numerous recent advances in the treatment of AML, seven days of continuous infusion cytarabine combined with three doses of an anthracycline medication (7+3) remains the most common backbone treatment for younger (&amp;lt;60) patients. Following 7+3 treatment, patients are typically assessed by a bone marrow biopsy 14-21 days after initial treatment, and 20%-30% of patients will have persistent disease at this time. This residual disease is typically treated with an additional round of the same induction treatment at a full or slightly reduced dose. Unfortunately, a complete response (CR) following re-induction is infrequent in intermediate and high-risk AML patients (CR rates of 35% and 18%, respectively). We have performed mass cytometry studies of AML cell cycle state and find that in patients with residual disease at day 14-21 of induction, leukemia stem and progenitor cells have a low proliferative fraction. We hypothesize that this low rate of proliferation reduces the effectiveness of re-induction therapy and could be countered using CPX-351, which is FDA-approved for treatment of therapy-related AML and AML with myelodysplasia-related changes. CPX-351 is a formulation of cytarabine and daunorubicin in a liposomal structure at an optimal 5:1 molar ratio that has been shown to be preferentially absorbed by hematopoietic cells and to persist in serum and bone marrow for significantly longer than traditional 7+3 chemotherapy. We hypothesize that the unique properties of CPX-351 will better target quiescent leukemia stem and progenitor cells and we thus designed a phase 1b/2 study to determine the safety and efficacy of CPX-351 as re-induction treatment for patients with intermediate and high-risk AML with residual disease after a first round of induction. Patients and Methods Eight patients with intermediate or high-risk AML who had failed to achieve hypocellular marrow 14-21 days following initial treatment with traditional 7+3 cytarabine and daunorubicin were treated with CPX-351 re-induction in the phase 1b portion of the study with a CPX-351 dose of daunorubicin 44 mg/m 2 and cytarabine 100 mg/m 2 given two or three times every 48 hours. Concomitant midostaurin (days 8-21) was allowed for patients with FLT3 mutations (Patients #1 and #8). Four patients were ELN intermediate-risk and four adverse-risk; mean blast count before re-induction was 45%. Patients were assessed weekly for signs of toxicity and for treatment response. Samples were collected from bone marrow biopsies performed before and after treatment for correlative mass cytometry studies using a 50-antibody panel to determine cell cycle state, intracellular signaling markers, and DNA damage response. Results Of the eight patients treated to date, six received two doses of CPX-351 and two received three doses. Of the six patients receiving two doses, five achieved a morphologic CR (two with residual genetic alterations), and one patient achieved a CRi. Two patients received three doses of CPX-351, with one achieving a PR and the other MLFS. Five of the eight patients were able to proceed to an allogeneic stem cell transplant. Consistent with previous studies of CPX-351, treatment was well-tolerated, almost all grade 3 or 4 toxicities were due to cytopenias (including two DLTs for delayed count recovery) and the only significant drug-related non-hematologic toxicity was a decrease in cardiac ejection fraction in patient #1. All treated patients survived &amp;gt;150 days and all were able to receive additional AML-directed therapy or HSCT after CPX-351 treatment. Due to slow accrual, hematologic toxicity, and the 100% CR/CRi rate in the two-dose group, the trial was amended to use two doses for the phase 2 portion, and an additional study site was opened. Study accrual is ongoing with a target of 20 additional patients in the phase 2 portion. Conclusion This ongoing phase 1b/2 trial of CPX-351 (liposomal cytarabine and daunorubicin) as re-induction treatment for intermediate and high-risk AML has been safe and tolerable with early treatment outcomes that appear to be much better than reported historical controls. Correlative studies by mass cytometry will further establish the mechanistic reasons for the observed responses.

Combining Allogeneic Gamma Delta T Cells with a Phosphoantigen Prodrug Promotes Apoptosis of Acute Myeloid Leukemia Stem and Progenitor Cells

Despite recent therapeutic advances, patients with relapsed/refractory acute myeloid leukemia (r/r AML) have limited treatment options and poor prognosis. Leukemic stem cells (LSCs) are considered as relapse-initiating cells and the “culprit” of treatment resistance. Allogeneic and autologous gamma delta (γδ) T cell-based therapies have been explored for a long time and proven to be safe in patients through multiple clinical trials. However, quite a few AML blasts obtained from r/r AML patients show resistance to γδ T cell-mediated cytotoxicity. Novel strategies targeted LSCs may improve efficacy of γδ T cell-mediated r/r AML therapy. Given that γδ T cells exert antitumor capacity via multiple pathways, to identify the way matters most in the resistance of γδ T cell-mediated cytotoxicity, we examined the median fluorescence intensity (MFI) of the ligands expressed in tumor cells by flow cytometry, including butyrophilin 3A (BTN3A), butyrophilin 2A1 (BTN2A1), the human MHC class I chain-related genes (MICA and MICB), the unique-long 16 binding proteins (ULBP1, ULBP2/5/6, ULBP3), Fas, the receptor of TNF-related apoptosis-inducing ligand (TRAIL) DR5, CD112 and CD155. The cytotoxicity activity of γδ T cells was measured by flow cytometry-based killing assay or bright-lite luciferase assay system after coculturing with AML cell lines and blasts at an appropriate effector to target (E:T) ratio. Then we employed a Support Vector Machine model to predict the killing efficiency and identified that BTN3A and BTN2A1 play the predominant role in γδ T cell-mediated cytotoxicity based on the Shapley additive explanation. BTN3A and BTN2A1 are the key ligands in the γδ TCR-phosphoantigen (pAg) recognition activity. PAgs, which are produced in tumor cells function as “molecular glues” to promote heteromeric association of BTN3A1 and BTN2A1 (Yuan L et al., BioRxiv 2022). To promote the γδ T cell-mediated cytotoxicity targeting r/r AML, here we synthesized a pAg prodrug, which show great plasma stability and membrane permeability. We anticipate this small molecule would lead pAg accumulation in tumor cells and cause increased γδ T cell activation. To identify the killing efficacy of pAg prodrug-induced γδ T cell activation, we select KG-1α (a human leukemia stem cell-like cell) as target cell. Zoledronate (ZOL), which is employed to stimulate γδ T cells in multiple γδ T cell-based clinical trials, is used in our killing assay as compared group. As expected, combining γδ T cells with pAg prodrug or ZOL both significantly improved the percent of specific killing when the E:T ratio is 1:1. The pAg prodrug showed more potent activity than ZOL group with EC50 value of 0.1 nM vs 17.93μM. And the specific killing percent of pAg prodrug group is 83.26±2.1 % (1 nM), comparing with negative control 15.17±3.4 % (only γδT cells). Futhermore, at relatively low E:T ratio (1:4), γδ T cells with pAg prodrug remain excellent cytotoxicity when targeting MV411 cell and OCI-AML3 cell, which are widely used in r/r AML research. After coculturing with primary leukemia stem and progenitor cells (CD34 +) obtained from r/r AML patients for 6~8 h, the apoptosis percentage of CD34 + leukemia cells was 42.34% comparing with negative control (only γδT cells) 2.53%. Then we evaluated the in vivo efficacy of combining γδT cells and pAg prodrug in NSG mice bearing MV411 cells. Compared with only γδT cells-treated group, combination with pAg prodrug presented better tumor clearing. To elucidate the pathway of pAg prodrug-mediated killing, we tested mitochondria apoptosis related events. After treated by γδ T cells with pAg prodrug, KG-1α cells showed loss of mitochondrial outer membrane potential and increasingly actived caspase 3/7. Meanwhile, pAg prodrug directly activates effector γδ T cells with increased secretion of CD107a and IFN-γ. Considering the possibility of toxicity towards normal hematopoietic stem and progenitor cells, we conducted colony-forming units (CFUs) assay. After treatment with γδT cells and pAg prodrug, the number of CFUs of CD34 + cells from cord blood was not effected compared with the CD34 + cells only group. Overall, we explored the predominant factor in γδ T cell-mediated killing and synthesized a pAg prodrug to improve the killing efficacy. We demonstrated that combining γδ T cells with pAg prodrug has effectively promoted apoptosis of AML stem and progenitor cells sparing normal hematopoietic stem and progenitor cells.

Synthetic Lethal Interactions with IRAK4 Inhibition in Myeloid Malignancies

Overexpression of immune-related genes is widely reported in acute myeloid leukemia (AML). Research from our lab and others has demonstrated that AML leukemic stem and progenitor cells (LSPC) rely on innate immune signaling through IRAK4 (reviewed in Bennett et al., Blood 2023). Moreover, AML LSPCs express a hypermorphic isoform of IRAK4 (IRAK4-L), due to U2AF1- and SF3B1-dependent mis-splicing. Building on this preclinical evidence, several IRAK4 inhibitors are now undergoing clinical trials in AML patients. In Phase-1 findings with a selective IRAK4 inhibitor (CA-4948; Curis Therapeutics), it was found that MDS and AML patients with splicing factor mutations responded best to monotherapy IRAK4 inhibition, although the overall response rate with monotherapy was modest. These findings suggest that IRAK4 is a relevant target in myeloid malignancies, but the identification of synthetic lethal dependencies may be crucial in revealing effective combination therapies. In this study, we sought to identify synthetic lethal interactions upon IRAK4 inhibition in AML. For this, we first generated isogenic AML cells that are proficient (WT THP1) or deficient for IRAK4 (IRAK4 KO THP1) using site-directed mutagenesis with CRISPR-Cas9. Deletion of IRAK4 resulted in a modest (~50%) reduction in leukemic colony formation and negligible differences in growth potential. We used the isogenic WT and IRAK4 KO AML cells to screen for synthetic lethal interactions by performing a 2400+ drug in vitro screen. Hits were prioritized for potency in IRAK4 KO cells vs WT AML cells, degree of fitness, and overall effect. Among these hits, the Cereblon E3 ligase modulator (CELMoD) CC-885 emerged as the top target. Independent validation confirmed that CC-885 significantly decreased proliferation and viability of isogenic IRAK4 KO MDS (MDSL) and AML (THP1) cells by approximately 3-4-fold compared to WT MDS or AML cells. Colony formation in methylcellulose after treatment with CC-885 was also significantly reduced in IRAK4 KO compared to WT MDS and AML cells. Based on Caspase-3 activation and AnnexinV staining, CC-885 induced significantly more apoptosis of IRAK4 KO cells as compared to WT AML cells. We extended our synthetic lethal analysis to a clinical-stage IRAK4 inhibitor (CA-4948). MDS and AML cells were treated with CA-4948 concurrently with CC-885 or pretreated for 7 days prior to treatment with CC-885. Unexpectedly, we found that only prior exposure of the AML cells to the IRAK4 inhibitors resulted in sensitivity to CC-885. These findings indicate that IRAK4 inhibition reprograms AML cells so that they acquire a synthetic lethal interaction with CC-885. CC-885 is known to target multiple substrates for degradation by the ubiquitin proteasome, including IKZF1, IKZF3, CK1a, and GSPT1. We compared the effect of CC-885 to CC-90009, a CELMoD with GSPT1 specific activity in the isogenic IRAK4 KO and WT AML cell lines. CC-90009 did not result in complete cell death up to concentrations of 10mM in both WT and IRAK4 KO, suggesting that the selective sensitivity of IRAK4 KO AML cells to CC-885 is not due to inhibition of GSPT1. In support of these interpretations, IRAK4 deficient AML cells exhibit increased protein expression of IKZF2 and IKZF3, but not GSPT1 or CK1a. Given the unique responses of IRAK4 KO cells to CELMoDs, we posited that IRAK4 inhibition alters the neosubstrate profile of CELMoDs in AML cells. Total proteome characterization of CC-885 treated WT and IRAK4 KO THP1 cells by mass spectrometry identified a significant decrease in 90 protein substrates in IRAK4 KO cells treated with CC-885 as compared to WT cells treated with CC-885. These findings suggest that IRAK4 inhibition alters the pool of neosubstrates in AML cells for certain CELMoDs. Overall, our study demonstrates that IRAK4 is a therapeutic target in AML, but that combination therapies, such as with certain CELMoDs, will be necessary to achieve better clinical responses.

Defective Necroptosis Mediates Chemotherapy Resistance in AML

Acute myeloid leukemia (AML) is a hematopoietic malignancy that can affect individuals of any age and, if left untreated, is always fatal. Standard induction chemotherapy, known as “7+3,” using drugs like cytarabine (Ara-C) and an anthracycline (daunorubicin or idarubicin), is typically given to young and fit older patients. While this treatment regimen has shown positive outcomes in patients who respond to it, relapse and refractory disease remain the primary causes of death. Prognostic classification, which combines cytogenetic and mutational status, can estimate overall and event-free survival but is not effective in predicting induction failure. Despite decades of research and treatment with 7+3 chemotherapy, the reasons behind variable treatment responses in AML patients remain unclear, especially for those who experience induction failure. Understanding these mechanisms could aid in risk-adapted treatment decisions and the identification of new therapeutic targets. Recent research has investigated gene expression and signaling patterns in leukemic cells at the time of diagnosis to categorize patients according to their response to chemotherapy. Notably, increased NF-kB signaling at diagnosis has been linked to chemotherapy resistance. NF-kB is a family of transcription factors involved in regulating genes linked to cancer cell survival, proliferation, and therapy resistance. However, the exact mechanism by which NF-kB activation contributes to chemotherapy failure and resistance in AML is yet to be determined. Using publicly available datasets, we found that AML patients undergoing induction failure exhibited elevated expression of TNFAIP3/A20, which is driven by NF-kB signaling and leads to a worse prognosis for patients undergoing 7+3 chemotherapy. In experiments with primary AML samples, it was observed that A20-High AML are resistant to Doxorubicin treatment, whereas A20-Low AML samples are sensitive to Doxorubicin. Knockdown of A20 in A20-High AML samples resulted in increased cell sensitivity to Doxorubicin, suggesting that elevated A20 expression reduces AML cells' response to the Doxorubicin both in vitro and in vivo. To understand why A20 is overexpressed in AML, we investigated its requirement on AML cell function in various models, including human AML cell lines, patient-derived samples, and mouse models of AML. Deletion or knockdown of A20 led to reduced leukemic progenitor function, cell viability, and AML development in vitro and in vivo. A20 is a dual ubiquitin-editing protein that regulates signaling pathways by acting either as a deubiquitinase to modulate NF-kB signaling or as an E3 ligase to control necroptosis. Further analyses revealed that A20 prevents necroptosis by targeting the necroptosis effector, RIPK1, for degradation through the proteasome in AML. Preventing necroptosis, either pharmacologically or genetically, restored the viability and clonogenicity of A20-deficient AML cells in vitro and in vivo. Notably, Doxorubicin, but not AraC, induced necroptosis in AML cells, which is suppressed in leukemic clones expressing A20. Examination of single-cell RNA-sequencing data from AML patients before and after Doxorubicin treatment confirmed the persistence of A20-expressing clones during treatment. These findings demonstrate that NF-kB-driven overexpression of A20 contributes to failed induction chemotherapy in AML, highlighting the therapeutic potential of targeting an alternative cell death pathway in AML.

The nonessential amino acid cysteine is required to prevent ferroptosis in acute myeloid leukemia

AbstractCysteine is a nonessential amino acid required for protein synthesis, the generation of the antioxidant glutathione, and for synthesizing the nonproteinogenic amino acid taurine. Here, we highlight the broad sensitivity of leukemic stem and progenitor cells to cysteine depletion. By CRISPR/CRISPR-associated protein 9–mediated knockout of cystathionine-γ-lyase, the cystathionine-to-cysteine converting enzyme, and by metabolite supplementation studies upstream of cysteine, we functionally prove that cysteine is not synthesized from methionine in acute myeloid leukemia (AML) cells. Therefore, although perhaps nutritionally nonessential, cysteine must be imported for survival of these specific cell types. Depletion of cyst(e)ine increased reactive oxygen species (ROS) levels, and cell death was induced predominantly as a consequence of glutathione deprivation. nicotinamide adenine dinucleotide phosphate hydrogen oxidase inhibition strongly rescued viability after cysteine depletion, highlighting this as an important source of ROS in AML. ROS-induced cell death was mediated via ferroptosis, and inhibition of glutathione peroxidase 4 (GPX4), which functions in reducing lipid peroxides, was also highly toxic. We therefore propose that GPX4 is likely key in mediating the antioxidant activity of glutathione. In line, inhibition of the ROS scavenger thioredoxin reductase with auranofin also impaired cell viability, whereby we find that oxidative phosphorylation–driven AML subtypes, in particular, are highly dependent on thioredoxin-mediated protection against ferroptosis. Although inhibition of the cystine-glutamine antiporter by sulfasalazine was ineffective as a monotherapy, its combination with L-buthionine-sulfoximine (BSO) further improved AML ferroptosis induction. We propose the combination of either sulfasalazine or antioxidant machinery inhibitors along with ROS inducers such as BSO or chemotherapy for further preclinical testing.

ERK1/2 Inhibition Overcomes Resistance to Venetoclax in AML By Inhibiting Drp1 Dependent Mitochondrial Fission

Background: Primary or secondary resistance to venetoclax is frequently associated with mutational/non-mutational activation of MAPK pathways. ERK1/2 are terminal kinases in MAPK pathway and may be an appropriate target regardless of the upstream mechanisms that activate the pathway. ERK1/2 mediated phosphorylation of Drp1 promotes mitochondrial fission and MAPK-driven tumor growth in RAS driven solid cancers (Kashatus et al., Mol Cell. 2015). However, the role of Drp1 dependent mitochondrial dynamics in therapeutic resistance in AML is unexplored. Methods: ERK1/2 was inhibited using Compound 27 (ERKi, Heightman et al., J Med Chem. 2018), an analog of ASTX029 (Munck et al., Mol Cancer Ther. 2021) in vitro and using ASTX029 in vivo. Preclinical models of venetoclax resistance and primary patient samples (n=8) were used to assess the synergy of concomitant Bcl2 and ERK1/2 inhibition (ERKi). In addition, a comprehensive analysis of alteration of signaling pathways, apoptotic signatures and DNA damage responses in response to ERKi+/-venetoclax were analyzed by mass cytometry based proteomic analysis (CyTOF) and immunoblotting. The potential clinical relevance of ERK1/2 inhibition to overcome venetoclax resistance was confirmed in a PDX model of AML (established from an AML patient who relapsed after venetoclax/decitabine treatment). Mitochondrial images were acquired using super-resolution imaging with OMX-Blaze followed by quantification with Imaris. Results : We previously reported the synergy of ERK1/2 inhibition using Compound 27 with venetoclax at inducing apoptosis in RAS mutated and/or venetoclax resistant AML cells including venetoclax resistant isogenic lines (Sharma et al., Blood 140; Supplement 1, 2022). Venetoclax+ERKi depleted leukemia progenitor cells in primary AML samples (CI:0.03-0.23) and impaired clonogenic growth of NRAS mutant PDX cells. In a PDX mouse model of post venetoclax/decitabine-relapsed AML, ASTX029+venetoclax treatment improved survival compared to vehicle (median survival 76.5 days vs. 50 days, p=0.0006) and venetoclax alone (median survival 76.5 days vs. 51.5 days, p=0.0065) (Figure 1) with corresponding reduction in leukemia burden in bone marrow (p&amp;lt;0.0001) and spleen (p&amp;lt;0.0001). CyTOF analysis using PDX bone marrow showed decreased expression of Mcl-1 and pMcl-1-T163 and an increased expression of BIM in response to ERKi+/-venetoclax (Figure 1). To maintain stemness in AML, mitochondrial ROS mitigation and Drp1-mediated mitochondrial fission are crucial (Schimmer et al., Cell Stem Cell. 2018). The inhibition of ERK1/2 resulted in decreased pDrp1-Ser616, along with an increase in mitochondrial length (p&amp;lt;0.001) suggesting impaired mitochondrial fission. This was accompanied by a decrease in mitochondrial membrane potential (p&amp;lt;0.0001) and an increase in mitochondrial ROS (p&amp;lt;0.0001). Overexpression (OE) of a phospho-mimetic i.e. Drp1-Ser616Glu-Ser637Ala led to shorter mitochondrial length (Figure 2), suggesting enhanced fission, a distinct metabolic phenotype with decreased ROS production and decreased mitochondrial depolarization with venetoclax+/- ERKi. Finally, Drp1 phospho-mimetic OE reversed apoptosis induction by venetoclax +/- ERKi (Figure 2) as compared to the wild-type and phospho-null (Ser616Ala) Drp1 (p&amp;lt;0.001) expressing cells, supporting the role of mitochondrial fission in resistance to venetoclax. Conclusion: The increased mitochondrial fission driven by ERK1/2 mediated phosphorylation of Drp1 contributes to venetoclax resistance in AML and inhibiting ERK1/2/Drp1 axis overcomes resistance to venetoclax by inhibiting mitochondrial fission (Figure 2). These data provide a strong rationale for the combination of ERK1/2 and Bcl-2 inhibitors in the treatment of AML.

Dietary γ-mangostin triggers immunogenic cell death and activates cGAS signaling in acute myeloid leukemia

Immunogenic cell death (ICD), one of cell-death types through release of damage-associated molecular patterns from dying tumor cells, activates tumor-specific immune response and elicits anti-tumor immunity by traditional radiotherapy and chemotherapy. However, whether natural products could induce ICD in leukemia is not elucidated. Here, we report dietary γ-mangostin eradicates murine primary leukemic cells and prolongs the survival of leukemic mice. As well, it restrains primary leukemic cells and CD34+ leukemic progenitor cells from leukemia patients. Strikingly, γ-mangostin attenuates leukemic cells by inducing ICD as characterized by expression of HSP90B1, ANXA1 and IL1B. Additionally, γ-mangostin accelerates cytoplasmic chromatin fragments generation, promoting DNA damage response, and enhances cGAS activation, leading to up-regulation of chemokines. Meanwhile, it induces HDAC4 degradation and acetylated histone H3 accumulation, which promotes chemokines transcription. Ultimately, CD8+ T cell is activated and recruited by γ-mangostin-induced chemokines in the microenvironment. Our study identifies γ-mangostin triggers ICD and activates cGAS signaling through DNA damage response and epigenetic modification. Therefore, dietary γ-mangostin would act as a potential agent to provoke anti-tumor immunity in the prevention and treatment of leukemia.

Immune Surveillance of Acute Myeloid Leukemia Is Mediated by HLA-Presented Antigens on Leukemia Progenitor Cells.

The elimination of therapy-resistant leukemia stem and progenitor cells (LSC) remains a major challenge in the treatment of AML. This study identifies and functionally validates LSC-associated HLA class I and HLA class II-presented antigens, paving the way to the development of LSC-directed T cell-based immunotherapeutic approaches for patients with AML. See related commentary by Ritz, p. 430 . This article is featured in Selected Articles from This Issue, p. 419.