Bone marrow (BM) microenvironment contributes to the regulation of normal hematopoiesis through a finely tuned balance of self-renewal and differentiation processes, cell-cell interaction and secretion of cytokines that during leukemogenesis are altered and favor tumor cell growth. In pediatric acute myeloid leukemia (AML), chemotherapy is the standard of care, but still >30% of patients relapse. The need to accelerate the evaluation of innovative medicines prompted us to investigate the mesenchymal stromal cells (MSCs) role in the leukemic niche to define its contribution to the mechanisms of leukemia escape. We generated humanized three-dimensional (3D) niche with AML cells and MSCs derived from either patients (AML-MSCs) or healthy donors. We observed that AML cells establish physical connections with MSCs, mediating a reprogrammed transcriptome inducing aberrant cell proliferation and differentiation, and severely compromising their immunomodulatory capability. We confirmed that AML cells modulate h-MSCs transcriptional profile promoting functions similar to the AML-MSCs when co-cultured in vitro, thus facilitating leukemia progression. Conversely, MSCs derived from BM of patients at time of disease remission showed recovered healthy features, at transcriptional and functional levels, including the secretome. We proved that AML blasts alter MSCs activities in the BM niche, favoring disease development and progression. We discovered that a novel AML-MSCs selective CaV1.2 channel blocker drug, Lercanidipine, is able to impair leukemia progression in 3D niche both in vitro and when implanted in vivo, if used in combination with chemotherapy, supporting the hypothesis that synergistic effects can be obtained by dual targeting approaches.
In pediatric acute myeloid leukemia (AML), intensive chemotherapy and allogeneic hematopoietic stem cell transplantation are the cornerstones of treatment in high-risk cases, with severe late effects and a still high risk of disease recurrence as the main drawbacks. The identification of targeted, more effective, safer drugs is thus desirable. We performed a high-throughput drug-screening assay of 1280 compounds and identified thioridazine (TDZ), a drug that was highly selective for the t(6;11)(q27;q23) MLL-AF6 (6;11)AML rearrangement, which mediates a dramatically poor (below 20%) survival rate. TDZ induced cell death and irreversible progress toward the loss of leukemia cell clonogenic capacity in vitro. Thus, we explored its mechanism of action and found a profound cytoskeletal remodeling of blast cells that led to Ca2+ influx, triggering apoptosis through mitochondrial depolarization, confirming that this latter phenomenon occurs selectively in t(6;11)AML, for which AF6 does not work as a cytoskeletal regulator, because it is sequestered into the nucleus by the fusion gene. We confirmed TDZ-mediated t(6;11)AML toxicity in vivo and enhanced the drug’s safety by developing novel TDZ analogues that exerted the same effect on leukemia reduction, but with lowered neuroleptic effects in vivo. Overall, these results refine the MLL-AF6 AML leukemogenic mechanism and suggest that the benefits of targeting it be corroborated in further clinical trials.
Summary Patients with acute myeloid leukemia (AML) carrying high-risk genetic lesions or high residual disease levels after therapy are particularly exposed to the risk of relapse. Here, we identified the long non-coding RNA CDK6-AS1 able to cluster an AML subgroup with peculiar gene signatures linked to hematopoietic cell differentiation and mitochondrial dynamics. CDK6-AS1 silencing triggered hematopoietic commitment in healthy CD34+ cells, whereas in AML cells the pathological undifferentiated state was rescued. This latter phenomenon derived from RUNX1 transcriptional control, responsible for the stemness of hematopoietic precursors and for the block of differentiation in AML. By CDK6-AS1 silencing in vitro, AML mitochondrial mass decreased with augmented pharmacological sensitivity to mitochondria-targeting drugs . In vivo, the combination of tigecycline and cytarabine reduced leukemia progression in the AML-PDX model with high CDK6-AS1 levels, supporting the concept of a mitochondrial vulnerability. Together, these findings uncover CDK6-AS1 as crucial in myeloid differentiation and mitochondrial mass regulation.
In pediatric acute myeloid leukemia (AML), fusions involving lysine methyltransferase 2A (KMT2A) are considered hallmarks of aggressive AML, for whom the development of targeted specific therapeutic agents to ameliorate classic chemotherapy and obtain a complete eradication of disease is urgent. In this study, we investigated the antiapoptotic proteins in a cohort of 66 pediatric AML patients, finding that 75% of the KMT2A-r are distributed in Q3 + Q4 quartiles of BCL-2 expression, and KMT2A-r have statistically significant high levels of BCL-2, phospho-BCL-2 S70, and MCL-1, indicating a high anti-apoptotic pathway activation. In an attempt to target it, we tested novel drug combinations of venetoclax, a B-cell lymphoma-2 (BCL-2) inhibitor, in KMT2A-MLLT3, for being the most recurrent, and KMT2A-AFDN, for mediating the worst prognosis, rearranged AML cell lines. Our screening revealed that both the bromodomain and extra-terminal domain (BET) inhibitor, I-BET151, and kinase inhibitor, sunitinib, decreased the BCL-2 family protein expression and significantly synergized with venetoclax, enhancing KMT2A-r AML cell line death. Blasts t (6; 11) KMT2A-AFDN rearranged, both from cell lines and primary samples, were shown to be significantly highly responsive to the combination of venetoclax and thioridazine, with the synergy being induced by a dramatic increase of mitochondrial depolarization that triggered blast apoptosis. Finally, the efficacy of novel combined drug treatments was confirmed in KMT2A-r AML cell lines or ex vivo primary KMT2A-r AML samples cultured in a three-dimensional system which mimics the bone marrow niche. Overall, this study identified that, by high-throughput screening, the most KMT2A-selective drugs converged in different but all mitochondrial apoptotic network activation, supporting the use of venetoclax in this AML setting. The novel drug combinations here unveiled provide a rationale for evaluating these combinations in preclinical studies to accelerate the introduction of targeted therapies for the life-threatening KMT2A-AML subgroup of pediatric AML.
Chemotherapy still remains the pillar of treatment of children with AML, a disease in which refinements in diagnostic approaches, minimal residual disease monitoring, and patient stratification have resulted into remarkable progresses during the past decade. However, most of the recently tested, novel anti-leukemia agents failed during pre-clinical and clinical validation phases, and one main limit in AML field is the inappropriateness of current preclinical models used to study drug efficacy, this jeopardizing the advance of phase II and III clinical trials, especially for children. In light of this consideration, we aimed at creating novel robust in vitro and in vivo approaches to discover or to re-assess alternative treatments to improve the portfolio of agents active in childhood AML. For this purpose, we developed new protocols for long-term 3D-AML cultures to perform more predictable high throughput drug screening in vitro, and, once identified the best compounds, to create new pre-clinical in vivo models. We set up the bone marrow (BM) endosteal niche by using a biomimetic 3D structure, made up of engineered hydroxyapatite and collagen I, where we seeded mesenchymal stromal cells derived either from AML patients (AML-MSCs) or from healthy BM donors (h-MSCs), together with osteoblasts, endothelial cells and finally AML blasts. We studied AML cell proliferation and clonogenicity cultured in 3D. We obtained results from twenty 3D long-term cultures of different primary AML, confirming blast proliferation up to 21 days. Clonogenic potential and immunophenotype preservation of the original AML blasts was also documented. At the same time, we compared AML-MSCs with h-MSCs, finding that AML-MSCs exhibited a higher proliferation rate (40% increase proliferation at 72 and 96 hours, p<0.001), and commitment to osteogenic differentiation, this latter occurring after 7 days with respect to 21 days of h-MSCs (p<0.01). To better characterize AML-MSCs features supporting AML cell growth, we cultured AML-MSCs and h-MSCs in an inflammatory environment (IL1β, IL6 and TNFα), observing that AML-MSCs did not exert anti-inflammatory activity by HUVEC tube formation assay (n=6, p<0.001). This latter finding was supported by a peculiar secretome profile defined by mass-spectrometry revealing factors as SERPINE1, CHI3L1, TIMP1, and PTX3 being differentially secreted. Thus, a drug targeting of AML-MSCs would be desirable, and we performed a screening of 480 compounds. This screening identified 17/480 active compounds capable of reducing AML-MSCs proliferation without toxicity over h-MSCs and AML blasts. We identified one main compound able to selectively reduce AML-MSCs proliferation, that, when combined to novel therapeutic agents for AML, such as the Quizartinib, I-BET inhibitor and Dasatinib in the 3D cultures, showed a synergistic effect (CI=0.5, p<0.05) towards FLT3-ITD, MLL-rearranged or c-KIT mutated AML. We then proceeded with two pilot studies in order to define the use of this 3D-AML cultures in in vivo setting. We implanted these organoids in the back of NSG mice and monitored leukemia engraftment in the scaffolds, as well as AML dissemination in peripheral blood. We documented the niche being vascularized and well organized by immunohistochemical staining for mCD31, hCD45 and hOPN, whereas we had a low rate of success in AML dissemination out of the niche (1 AML out of 14 implanted in 15 months). On the contrary, we observed that AML cells proliferated in the 3D up to 9 months after implantation, suggesting that this system is more suitable for an easy and quick in loco drug testing. Thus, we implanted AML, after being transduced with luciferase, in the 3D niche in NSG mice and monitored luciferase activity during intra-peritoneal drug treatments. We evaluated some new and old compounds known to target leukemia cells and documented a significant reduction of luciferase in the 3D when a drug was active, supporting our 3D scaffolds as a novel useful in vivo system to screen selected drugs before the prioritization of the best one to be used in a pre-clinical setting in PDXs. In conclusion, our data support the possibility to work with long-term 3D cultures of AML in vitro to identify new drugs, and we attribute to AML-MSCs a crucial supportive role to be further considered in in vivo settings for novel combo strategies. Finally, these findings could help test new compounds to be validated in future clinical trials. Disclosures Locatelli: Novartis: Consultancy, Membership on an entity's Board of Directors or advisory committees; Bellicum: Consultancy, Membership on an entity's Board of Directors or advisory committees; Amgen: Honoraria, Membership on an entity's Board of Directors or advisory committees; Miltenyi: Honoraria; bluebird bio: Consultancy.
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