Littérature scientifique sur le sujet « Blast Crisis, BCR, BCR-ABL, bone marrow precursors »

Abstract Several RNA binding proteins (RBPs) have been implicated in the progression of chronic myelogenous leukemia (CML) from the indolent chronic phase to the aggressively fatal blast crisis. In the latter phase, expression and function of specific RBPs are altered at transcriptional or post-translational levels by the increased constitutive kinase activity of the BCR/ABL oncoprotein, resulting in enhanced resistance to apoptotic stimuli, growth advantage and differentiation arrest of CD34+ CML blast crisis (CML-BC) progenitors. In the current study, we identified by RIP (RNA immunoprecipitation)-mediated microarray analysis that mRNA encoding the E2F3 transcription factor associates to the BCR/ABL-regulated RBP hnRNP A1. Moreover, RNA electrophoretic mobility shift and UV-crosslinking assays revealed that hnRNP A1 interacts with E2F3 mRNA through a binding site located in the 3’UTR of both human and mouse E2F3 mRNA. Accordingly, E2F3 protein levels were upregulated in BCR/ABL-transformed myeloid precursor cell lines compared to parental cells in a BCR/ABL-kinase- and hnRNP A1 shuttling-dependent manner. In fact, treatment of BCR/ABL-expressing myeloid precursors with the kinase inhibitor Imatinib (2mM, 24 hr) or introduction of a dominant-negative shuttling-deficient hnRNP A1 protein (NLS-A1) markedly reduced E2F3 protein and mRNA levels. Similarly, upregulation of BCR/ABL expression/activity in the doxycycline inducible TonB2.10 cell line resulted in increased E2F3 protein expression. BCR/ABL kinase-dependent induction of E2F3 protein levels was also detected in CML-BCCD34+ compared to CML-CPCD34+ progenitors from paired patient samples and to normal CD34+ bone marrow samples. Importantly, the in vitro clonogenic potential of primary mouse BCR/ABL+ lineage negative (Lin−) progenitors was markedly impaired in BCR/ABL+ E2F3−/− compared to BCR/ABL-transduced E2F3+/+ myeloid progenitors and upon shRNA-mediated downregulation of E2F3 expression (90% inhibition, P<0.001). Furthermore, subcutaneous injection of shE2F3-expressing BCR/ABL+ cells into SCID mice markedly impaired in vivo tumorigenesis (>80% reduction in tumor burden, P<0.01). Accordingly, BCR/ABL leukemogenesis was strongly inhibited in SCID mice intravenously injected with E2F3 shRNA-expressing 32D-BCR/ABL cells and in mice transplanted with BCR/ABL-transduced Lin− bone marrow cells from E2F3−/− mice. Specifically, we demonstrate that reduced or absent levels of E2F3 resulted in dramatically decreased numbers of circulating BCR/ABL+ cells as determined by nested RT-PCR at 4 weeks post-injection (P=0.0001), normal splenic architecture and bone marrow cellularity and the absence of infiltrating myeloid blasts into non-hematopoietic compartments (i.e. liver). By contrast, SCID mice transplanted with vector-transduced 32D-BCR/ABL cells or BCR/ABL+ E2F3+/+ Lin− BM progenitors showed signs of an overt acute leukemia-like process with blast infiltration of hematopoietic and non-hematopoietic organs. Altogether, these data outline the importance of E2F3 expression for BCR/ABL leukemogenesis and characterize a new potential therapeutic target for the treatment of patients with advanced phase CML.

Abstract The inability of myeloid chronic myelogenous leukemia blast crisis (CML-BC) progenitors to undergo neutrophil differentiation depends on suppression of C/EBPα expression through the translation inhibitory activity of the RNA-binding protein hnRNP-E2. Here we show that “oncogene dosage” is a determinant factor for suppression of differentiation in CML-BC. In fact, high levels of p210-BCR/ABL are required for enhanced hnRNP-E2 expression, which depends on phosphorylation of hnRNP-E2 serines 173, 189, and 272 and threonine 213 by the BCR/ABL-activated MAPKERK1/2. Serine/threonine to alanine substitution abolishes hnRNP-E2 phosphorylation and markedly decreases its stability in BCR/ABL-expressing myeloid precursors. Similarly, pharmacologic inhibition of MAPKERK1/2 activity decreases hnRNP-E2 binding to the 5′UTR of C/EBPα mRNA by impairing hnRNP-E2 phosphorylation and stability. This, in turn, restores in vitro and/or in vivo C/EBPα expression and G-CSF–driven neutrophilic maturation of differentiation-arrested BCR/ABL+ cell lines, primary CML-BCCD34+ patient cells and lineage-negative mouse bone marrow cells expressing high levels of p210-BCR/ABL. Thus, increased BCR/ABL oncogenic tyrosine kinase activity is essential for suppression of myeloid differentiation of CML-BC progenitors as it is required for sustained activation of the MAPKERK1/2-hnRNP-E2-C/EBPα differentiation-inhibitory pathway. Furthermore, these findings suggest the inclusion of clinically relevant MAPK inhibitors in the therapy of CML-BC.

The Philadelphia chromosome is formed by a balanced, reciprocal translocation that pairs sequences from BCR on Chromosome 22 with sequences from ABL on Chromosome 9, resulting in the production of the constitutively active tyrosine kinase (TK) BCR-ABL. Depending on the location of the breakpoint within BCR, three different sizes of BCR-ABL may form, each associated with distinct clinical sequelae. Previous studies identified a functional domain within the BCR sequences preserved by the more-indolent forms of BCR-ABL (i.e., p210 and p230) that demonstrates a constitutive Rho guanine nucleotide exchange factor (RhoGEF) activity. Using the structurally derived S509A mutation, which does not affect TK activity but abrogates RhoGEF signaling, we, subsequently, showed that this feature regulates leukemia progression in mice. The RhoGEF domain was recently reported to contain two missense mutations (F547L and T654K) in a chronic myelogenous leukemia (CML) blast crisis (BC) patient, suggesting that it may play a role in human disease as well. To evaluate the clinical significance of this region, we, therefore, examined p210 BCR-ABL constructs containing these clinically derived RhoGEF mutations (CDRMs), both in isolation and in combination, using a murine bone marrow transplant (mBMT) model of CML. The mutations did not destabilize p210 BCR-ABL expression or TK activity but decreased RhoGEF signaling. Relative to mice transplanted with wild-type (WT) p210 BCR-ABL, those that received the CDRMs exhibited an earlier onset of disease, frequently developing previously unseen dermatologic involvement or myeloid sarcomas, but demonstrated significantly increased survival in an additive manner [Fig. 1]. While mice transplanted with WT p210 BCR-ABL exhibited neutrophilia that progresses to a less-differentiated phenotype at death, disease in the CDRM mice was characterized by eosinophilia and monocytosis with no maturation arrest. The most likely cause of death in mice transplanted with WT p210 BCR-ABL is widespread hematogenous involvement of the lungs resulting in acute respiratory distress. In contrast, mice receiving the CDRMs demonstrated pulmonary involvement which was limited to the bronchovascular bundles or subpleural space. This is consistent with a switch to lymphatogenous spread, likely secondary to skewed differentiation, and it implies an alternate cause(s) of death. To help determine the mechanism responsible for the observed differences in differentiation and maturation arrest, we next studied the CDRMs in vitro using the 32Dcl3 murine myeloid precursor cell line. A growing body of evidence suggests that the DNA damage response can affect lineage restriction in myeloid cells; it is also well-established that the accumulation of DNA damage is necessary for progression to BC. Accordingly, the CDRMs were associated with the restoration of p53 activation and the G1/S cell cycle checkpoint relative to WT p210 BCR-ABL. This suggests that the RhoGEF domain may be responsible for the suppression of the DNA damage response. Because the mBMT phenotype associated with the S509A mutation was distinct from that of the CDRMs, it may indicate that this capability is mediated by some functionality yet to be described. Importantly, the CDRMs were also associated with increased Src family kinase activity, which is thought to be a major mechanism of BCR-ABL-independent TK inhibitor resistance and minimal residual disease. Collectively, these results suggest that the BCR-ABL RhoGEF domain can influence disease progression and response to treatment in human leukemia. Disclosures No relevant conflicts of interest to declare.

Abstract Introduction/Objective Primary chronic myelogenous leukemia (CML) blast crisis at the initial disease presentation is rare. Most CML blast crisis cases present with increased myeloblasts with a minority of patients showing lymphoblastic leukemia. Differentiating primary CML lymphoblast crisis from de novo acute lymphoblastic leukemia may represent a diagnostic challenge to both pathologists and treating clinicians. This distinction is important as it has significant implications on patient management. Methods/Case Report A 15-year-old male patient was admitted to our University Hospital for hyperleukocytosis. Patient reportedly had weight loss with occasional sweats and cervical lymphadenopathy. She was found to have massive splenomegaly. Peripheral blood showed hyperleukocytosis with predominance of granulocytes at all maturation stages ranging from blast to segmented neutrophils with increased blasts. Subsequent bone marrow findings were consistent with extensive involvement by B-lymphoblastic leukemia. Ten-color Flow cytometry showed approximately 30% blasts with rare lymphocytes and monocytes. The blasts revealed precursor B-lymphoblastic immunophenotypic expression of CD45, CD10, CD19, CD20, CD22, CD34, CD38, CD200, HLA-DR and TdT expression. The results were similar to that of peripheral blood. Granulocytes showed abnormal maturation pattern with increased immature precursors and partial expression of CD4 and CD56 with no abnormalities detected in lymphocytes. In this case, while the bone marrow findings are consistent with B-lymphoblastic leukemia, the peripheral blood findings are consistent with blast phase of chronic myeloid leukemia. Further evaluation by cytogenetic and molecular studies confirmed the presence of Philadelphia chromosome, p210 transcripts, and rearrangement of BCR-ABL1, which supported the impression of precursor B-lymphoblastic leukemia in primary blast phase of CML. The patient was treated with tyrosine kinase inhibitor combined chemotherapy and went into remission. She has been followed up without significant complications for a year. Results (if a Case Study enter NA) NA. Conclusion The diagnosis of CML in primary lymphoblastic crisis is rare and needs to be systemically excluded before giving the diagnosis of de novo BCR-ABL1-positive acute lymphoblastic leukemia. If the patient does not have splenomegaly or previous leukocytosis, it needs cytological examination and extensive molecular analyses.

Abstract Stromal-derived factor-1 (SDF-1) and its receptor, CXCR4, are essential for normal stem/progenitor cell movement, adherence, and retention within the bone marrow environment. Two mechanisms through which BCR-ABL1 are thought to disrupt CXCR4-mediated chemotactic responses have been described in leukemia: the inhibition of CXCR4 expression (Geay et al. 2005, Cancer Res.) and intra-cellular signaling defects without modification of CXCR4 expression (Salgia et al. 1999, Blood; Ptasznik et al. 2002, J. Exp. Med.). These opposing mechanisms suggest that the actual situation is more complex and that new signaling paradigms are needed. To address this, we studied the effects of BCR-ABL1 on SDF-1-dependent, integrin-mediated, migration and adhesion of hematopoietic precursors. Stimulation of BCR-ABL1(−) hematopoietic cells with SDF-1 showed reduced cell adherence to surfaces coated with ICAM-1 (a ligand for the LFA-1 integrin), which was associated with down-regulated expression of activation-dependent epitopes of the β2 integrin, LFA-1, on hematopoietic cells. Inhibition of Lyn expression with siRNA prevented the SDF-1-triggered down-regulation of LFA-1 and cell adherence, indicating that CXCR4 inhibited the function of LFA-1 through Lyn. Expression of BCR-ABL1 in these cells resulted in increased expression of activation-dependent epitopes of LFA-1 and prevented SDF-1-dependent regulatory effects on both LFA-1 affinity and ICAM-1 adherence. Also, expression of BCR-ABL1 prevented Lyn-mediated regulation of cell adhesion to ICAM-1 as well as Lyn-mediated regulation of LFA-1 affinity. These results indicate that BCR-ABL1 constitutively increases the affinity of the LFA-1 integrin to its ligand ICAM-1, locking the integrin into an “active” conformation. The net result is the loss of responsiveness of LFA-1 to SDF-1-induced ‘inside-out’ signaling involving CXCR4 and Lyn kinase. Because in our experiments BCR-ABL1 had no significant effect on the expression of CXCR4 in Mo7e cells, transfected with low and high amounts of p210-BCR-ABL, or in primary BCR-ABL(+) cells from CML blast crisis patients (n=3), we conclude that BCR-ABL1 inhibits CXCR4-triggered ‘inside-out’ integrin signaling rather than CXCR4 expression. Taken together, we propose that BCR-ABL1 disrupts the signaling link between the chemokine receptor, CXCR4 and the β2 integrin LFA-1 so as to inhibit normal SDF-1-mediated chemotaxis and adhesion in hematopoietic cells.

Abstract Abstract 2738 Tyrosine kinase inhibitors (TKIs) have become frontline therapy for CML; however, alternative therapies are required, as TKIs do not induce long-term response in CML patients undergoing blastic transformation and are ineffective against Philadelphia-positive (Ph+) quiescent stem cells, which show innate resistance to BCR-ABL1 kinase inhibitors. Therapeutic targets of interest are survival factors conferring resistance to TKI-induced apoptosis and/or those increasing proliferation of leukemic progenitors. We previously reported (Harb JG et al., ASH 2007) that genetic inactivation of Bcl-x did not inhibit BCR-ABL1 leukemogenesis in an inducible mouse model of CML. Thus, we hypothesize that BCR/ABL mediated post-translational modification and inactivation of pro-apoptotic BAD negates the requirement for the anti-apoptotic function of Bcl-xL in stem/progenitor cells from SCLtTA-BCR/ABL1/Bcl-x−/− mice. Following this rationale, we tested if simultaneous pharmacologic BAD activation and Bcl-xL inhibition may be an efficient way of killing CML stem/progenitor cells. To test this, loss of Bcl-xL function with increased levels of active BAD was achieved by expressing Bcl-x shRNA in 32D-BCR/ABL mouse myeloid precursors that were then treated with LY294002 (LY), which suppresses the inhibitory effects of PI-3K/Akt activation on BAD. Flow cytometric analysis of Annexin V+ cells revealed that levels of apoptosis were three times higher in BCR-ABL1+ cells expressing the Bcl-x shRNA when compared with vector-transduced BCR-ABL1+ cells. As expected, increased levels of dephosphorylated (active) BAD at the mitochondrial membrane were found in LY-treated BCR-ABL+ cells. Interestingly, co-treatment of Bcl-x shRNA-expressing BCR-ABL1+ cells with LY and the Bcl-xL/Bcl-2 antagonist ABT-263 (ABT) did not further promote apoptosis, suggesting that decreased survival of BCR-ABL1+ cells was dependent on downregulation of Bcl-xL and not Bcl-2. To determine efficacy of combined pharmacologic Bcl-xL inhibition and BAD activation, 32D-BCR/ABL and K562 cells were treated with compounds expected to activate BAD upon inhibition of PI-3K/Akt/mTOR-generated signals, used alone or in combination with ABT. Individually, at suboptimal doses, LY, Rapamycin (RAP), mTORC1/2 inhibitor PP242, and ABT were tolerated with apoptosis levels lower than 20%. Notably, when combined with ABT, all three efficiently induced apoptosis (∼90% Annexin V+) of BCR-ABL1+ cells. As with LY, increased levels of active BAD were found at the mitochondrial membrane of RAP- and PP242-treated BCR-ABL1+ cells. We found that PP242 downregulated p-Akt (92%), Mcl-1 (67%) and Bcl-xL (51%) more efficiently than RAP or LY. It has been shown that PP242 impairs the clonogenic potential of TKI-resistant mononuclear BM CML-BC cells; however, its effects when used alone or in combination with ABT on survival of normal and leukemic hematopoietic stem (HSCs) and progenitor cells is still unknown. Thus, HSC-enriched (CD34+/CD38-) and progenitor (CD34+) CML-BC cell fractions were isolated from bone marrow and peripheral blood and used in colony forming (CFC) assays with ABT, PP242 or ABT/PP242. ABT alone did not suppress colony formation of Ph+ CD34+/CD38− cells, while PP242 reduced it by nearly 50%. Conversely, ABT/PP242 combination decreased Ph+ stem and progenitor colony formation by ∼80%. Furthermore, the self-renewal of Ph+ CD34+/CD38− cells was markedly impaired by ABT/PP242 as demonstrated by the 80% decrease in replating efficiency. To assess if non-leukemic stem cells would tolerate ABT/PP242, colony assays were performed with LSK from wild type mice treated with ABT, PP242, RAP and ABT/PP242. We did not find a significant effect of ABT or PP242 on clonogenic potential when given as single agents. More importantly, combined treatment decreased CFC output by only 35% while RAP, which has an acceptable toxicity profile as it has been used in clinical trials for patients unresponsive to TKIs, decreased LSK colony forming potential by 50%. In summary, our data showing that combined treatment with the mTORC1/2 inhibitor/BAD activator PP242 and the BCl-xL/Bcl-2 antagonist ABT-263 markedly induces apoptosis of BCR-ABL+ cell lines, in HSCs and in progenitors from CML-BC patients. This approach warrants further pre-clinical investigation aimed at inclusion in clinical protocols for treating blast crisis CML. Disclosures: No relevant conflicts of interest to declare.

Abstract BACKGROUND Extramedullary blast crisis (BC) of Ph’+ CML is infrequent and commonly affects bone, lymphoid tissue, skin and soft tissues and central or peripheral nervous system. Most of nodal lymphoid tumors occuring in the setting of CML derive from T-cell precursors and represent the evolution of CML to a lymphoid nodal BC. CASE HISTORY In February 2004, a 52 year-old patient underwent diagnostic wide biopsy of a nasopharingeal mass that caused severe acute respiratory symptoms. At the histological examination, the nasopharyngeal mucosa exhibited a diffuse pattern of infiltration by neoplastic cells with a characteristic single-file arrangement. The cells showed typical convoluted nuclei with one or two nucleoli and abundant cytoplasm (L2, lymphoblasts). The malignant cell population expressed a preT-cell immunophenotype: cytoplasmic CD3(+), CD43 (+), TdT (+/−), CD34(+), CD4(−), CD8(−). Thus, the diagnosis of T-cell LL was formulated. Whole-body CT scan revealed nasopharingeal mass, retropharyngeal, laterocervical, axillary, inguinal enlarged nodes and splenomegaly. Laboratory tests indicated leukocytosis (58,000/μl) with a differential WBC count typical of CML in chronic phase (myeloblasts &lt;1%). This diagnosis was confirmed by a low alkaline phosphatase value (score: 1), histological features of bone marrow (BM) biopsy, classical cytogenetics (presence of the Ph’ in 100% of 25 metaphases analysed and absence of other cytogenetic abnormalities) and FISH evaluation (D-FISH bcr-abl in interphase and metaphase, Oncor probe). The nested RT-PCR (JQ Guo et al., Leukemia;2002,15:2447) disclosed the presence of the hybrid protein p210 (b2,a2), but not that of p190. A laterocervical node was excised to perform cytogenetic and molecular analyses in order to determine whether the T-cell LL was an unrelated disease or the expression of an extramedullary BC. The histology confirmed the presence of a uniform population of T-lymphoblasts in which classical cytogenetic analysis disclosed the following kariotype: 49,XY,t(9;22)(q34;q11),+9,+19,+der(22)t(9;22)(q34;q11) and 50–52,XY t(9;22)(q34;q11),+6+9,+9q+,+19,+20,+22q−. The FISH analysis showed the presence of bcr-abl gene in all cells analyzed and the presence of multiple copies of this gene as well as of double Ph’ chromosome. Nested RT-PCR showed the presence of both p210 and p190 transcripts. These findings indicated that the T-cell LL was an extramedullary BC of a CML simultaneously diagnosed in chronic phase in BM and peripheral blood. The patient was initially treated with vincristine, daunomicine, asparaginase and prednisone combined with Gleevec (800mg/die). Consolidation therapy, consisting of high-dose Ara-C (4g/m2 for 4 days) and mithoxantrone (10mg/m2 for 2 days), followed by a mieloablative course with mithoxantrone (60 mg/m2) and melphalan (180 mg/m2) and autologous stem cell support (ASCT) was administered after an initial clinical response. Gleevec was given during the entire treatment period. A fugacious complete clinical-hematological and a partial cytogenetic (FISH: 12% of cells bcr-abl+) and molecular (number of bcr-abl/104 ABL copies= 184, real-time quantitative RT-PCR: J Gabert et al., Leukemia;2003:1) remission was documented after ASCT. The patient refused further consolidation treatment with Gleevec and died, due to progressive disease, in December 2004.

Abstract Abstract 2901 FTY720 is a sphingosine analog proposed by the FDA for treating Multiple Sclerosis patients because of its immunosuppressive activity, which depends on its ability to prevent lymphocyte egress into the peripheral blood. To act as an immunosuppressive drug, FTY720 undergoes sphingosine kinase 2 (SPHK2) phosphorylation and internalization upon interaction with the sphingosine-1-phosphate receptor 1 (S1PR1). FTY720 also acts as a potent activator of protein phosphatase 2A (PP2A), a tumor suppressor found inactivated in chronic and blast crisis CML with wild type or imatinib/dasatinib-resistant BCR-ABL1, Ph+ B-ALL, KitD816V AML, Jak2V617F+ MPDs and other leukemias/lymphomas. FTY720 treatment of cell lines and primary progenitors isolated from bone marrow of patients with these malignancies, markedly suppressed leukemic cell proliferation/survival and induced apoptosis in a PP2A-dependent manner. Notably, long-term treatment with FTY720 of mice carrying these hematopoietic malignancies significantly prolonged survival and restored normal myelopoiesis without exerting any toxic effect in hematopoietic and non-hematopoietic organs. However, in vivo administration of FTY720 strongly, albeit reversibly, decreases the number of circulating B and T lymphocytes. Here we report that a synthetically phosphorylated FTY720 (FTY720-P) is unable to induce neither PP2A activation nor apoptosis of BCR-ABL1-, Jak2V617F-, or KitD816V-expressing myeloid precursors, indicating that FTY720 phosphorylation is dispensable for its anti-leukemic activity. Thus, we functionally characterize two FTY720 derivatives, QC-FTYSM and OSU-2S, which were synthesized as molecules unable to undergo SPHK2 phosphorylation. Treatment (2.5 uM; 24h) of FTY720-sensitive 32D-BCR/ABL cells with QC-FTYSM and OSU2S results in ∼80% and 40%, respectively, more efficient suppression of BCR-ABL1 expression and kinase activity than that observed with FTY720. Moreover, QC-FTYSM, OSU-2S and FTY720 (2.5uM; 0–60h) induce a progressive block of proliferation and marked induction of apoptosis of 32D-BCR/ABL cells. In fact, a 96%, 98%, and 79% decrease in viability is observed after treatment with QC-FTYSM, OSU-2S and FTY720, respectively. Notably, viability of non-transformed myeloid 32Dcl3 cells is not significantly affected by treatment with FTY720 or its derivatives. Consistent with the ability of FTY720 to induce apoptosis through rescue of PP2A activity, phosphatase assays show identical ability of FTY720, QC-FTYSM and OSU-2S to restore PP2A functionality. In fact, comparable and marked decrease in the amount of inactive Y307-phosphorylated PP2Ac was detected in 32D-BCR/ABL cells treated with FTY720 or its derivatives. To formally demonstrate that QC-FTYSM and OSU-2S lack immunosuppressive activity, we first assessed their ability to be internalized upon interaction/association with the S1PR1 receptor. Thus, cells were transduced with a GFP-tagged S1PR1 and treated with either QC-FTYSM, OSU-2S, or, as positive control, FTY720-P. Confocal microscopy revealed that treatment FTY720-P resulted in a strong S1PR1 internalization. Conversely, exposure of the cells to QC-FTYSM and OSU-2S did not alter the S1PR1 membrane localization, indicating that these molecules did not undergo SHPK2 phosphorylation. Further demonstration of the inability of these compounds to act as immunosuppressive molecules was gained upon in vivo administration of a single dose of FTY720, QC-FTYSM or OSU-2C (10 mg/kg) to wild type FVB/N mice. As expected, percentage of B220+/CD19+ circulating B-cells decreased of ∼90% in FTY720-treated animals. Conversely, the percentage of B-cells after exposure to QC-FTYSM and OSU-2S remained unchanged (≤ 1% decrease). Likewise, the number or CD4+ and CD8+ cells also was not affect by treatment with the QC-FTYSM compound. Note that effect of OSU-2S on T-cells and the toxicity profile and anti-leukemic activity of these drugs in healthy animals and mouse models of deadly leukemias (e.g. T315I+ and blast crisis CML and Ph+ ALL) as well as Ph− MPDs are currently being assessed. Altogether our data indicate that QC-FTYSM and OSU-2S represent two potentially powerful and safe drugs which could be introduced in the current therapeutic protocols for different types of hematopoietic and non-hematopoietic malignancies characterized by functional inactivation of the PP2A tumor suppressor. Disclosures: No relevant conflicts of interest to declare.

Abstract The bone marrow provides an essential regulatory microenvironment for adult hematopoiesis, however the relationship between the bone marrow microenvironment and malignant hematopoiesis remains poorly understood. To investigate the interactions between leukemia and the bone marrow microenvironment we utilized a mouse model of blast-crisis chronic myelogenous leukemia (BC-CML), in which primitive normal murine hematopoietic cells are modified to leukemic cells by expressing the translocation products BCR/ABL and Nup98/HoxA9. The presence of each translocation was confirmed by their co-expression of Green Fluorescent Protein (GFP) and Yellow Fluorescent Protein (YFP) respectively. Ten days after injection of GFP+/YFP+ leukemic cells into strain-matched immunocompetent, non-myeloablated recipient mice, 50% of the bone marrow was composed of leukemic cells as determined by flow cytometric analysis. Histologic analysis of the contralateral tibiae and femora demonstrated not only progressive replacement of the bone marrow by leukemic cells, but also a significant bone loss. Histomorphometric analysis confirmed 50% decreased trabecular bone volume in leukemic mice compared to control mice that were not injected with leukemic cells (bone volume/total volume (%): 12±2 vs 26±2 p=0.01). Interestingly, numerous multi-nucleated osteoclasts were observed in the bone marrow of leukemic mice and were localized adjacent to leukemic cells, suggesting that leukemic cells may affect osteoclastogenesis and result in massive bone loss. To test this hypothesis, we first measured the expression of known regulators of osteoclastogenesis, including RANKL, in our leukemic cells by quantitative RT-PCR analysis. Compared to GFP−/YFP− cells, GFP+/YFP+ cells have 3-fold increased expression of RANKL, a major osteoclastogenic cytokine. We then examined if leukemic cells can give rise to osteoclasts in the presence of RANKL and M-CSF in vitro and found that these cells were unable to differentiate into osteoclasts themselves. To determine if leukemic cells can induce osteoclastogenesis of normal osteoclast progenitors, we cocultured spleen-derived osteoclast precursors from wild-type mice with GFP+/YFP+ leukemic cells or GFP−/YFP− non-leukemic cells in osteoclastic differentiating media containing optimal concentrations of M-CSF and RANKL. As expected, there was abundant formation of mature osteoclasts, identified as TRAP+ multinucleated cells, in control cultures containing non-leukemic cells and osteoclast precursors. Leukemic cells significantly increased TRAP+ mono-nucleated osteoclast precursors (No. TRAP+ mononucleated cells/well: 34±3.3 vs 20±6.0 in non-leukemic cells, p=0.0136). Under this culture condition, we did not observe increased mature osteoclast formation by leukemic cells. Surprisingly, we found that osteoclast precursors strongly prolonged the survival of leukemia cells. In control cultures without a feeder layer of osteoclast precursors there were no viable leukemia cells present after 6 days in culture while in the co-culture system viable leukemia cells were still abundant after 6 days in culture, identifiable by their expression of GFP/YFP (No. GFP+/YFP+/high power field: 0 vs 142±6.4, p&lt;0.01). In summary, in a murine model of BC-CML, there was a rapid loss of trabecular bone and an increase in the number of osteoclasts. Expression of osteoclast-regulating cytokines in leukemic cells favored osteoclastogenesis, however modified cells did not themselves give rise to osteoclasts, while increasing the population of normal immature osteoclasts. In turn, osteoclast progenitors prolonged survival of leukemic cells in vitro. Taken together, these data strongly suggest reciprocal synergistic interactions of leukemic cells with osteoclast progenitors in the bone microenvironment. These previously unrecognized interactions could be exploited to modify disease progression, providing a novel approach for leukemia treatment.

Abstract Background In advanced human malignancies, RNA sequencing (RNA-seq) has uncovered deregulation of adenosine deaminase acting on RNA (ADAR) editases that promote therapeutic resistance and leukemia stem cell (LSC) generation. Chronic myeloid leukemia (CML), an important paradigm for understanding LSC evolution, is initiated by BCR-ABL1 oncogene expression in hematopoietic stem cells (HSCs) but undergoes blast crisis (BC) transformation following aberrant self-renewal acquisition by myeloid progenitors harboring cytokine-responsive ADAR1 p150 overexpression. Emerging evidence suggests that adenosine to inosine editing at the level of primary (pri) or precursor (pre)-microRNA (miRNA), alters miRNA biogenesis and impairs biogenesis. However, relatively little is known about the role of inflammatory niche-driven ADAR1 miRNA editing in malignant reprogramming of progenitors into self-renewing LSCs. Methods Primary normal and CML progenitors were FACS-purified and RNA-Seq analysis as well as qRT-PCR validation were performed according to published methods (Jiang, 2013). MiRNAs were extracted from purified CD34+ cells derived from CP, BC CML and cord blood by RNeasy microKit (QIAGEN) and let-7 expression was evaluated by qRT-PCR using miScript Primer assay (QIAGEN). CD34+ cord blood (n=3) were transduced with lentiviral human JAK2, let-7a, wt-ADAR1 and mutant ADAR1, which lacks a functional deaminase domain. Because STAT signaling triggers ADAR1 transcriptional activation and both BCR-ABL1 and JAK2 activate STAT5a, nanoproteomics analysis of STAT5a levels was performed. Engrafted immunocompromised RAG2-/-γc-/- mice were treated with a JAK2 inhibitor, SAR302503, alone or in combination with a potent BCR-ABL1 TKI Dasatinib, for two weeks followed by FACS analysis of human progenitor engraftment in hematopoietic tissues and serial transplantation. Results RNA-seq and qRT-PCR analysis in FACS purified BC CML progenitors revealed an over-representation of inflammatory pathway activation and higher levels of JAK2-dependent inflammatory cytokine receptors, when compared to normal and chronic phase (CP) progenitors. Moreover, RNA-seq and qRT-PCR analysis showed decreased levels of mature let-7 family of stem cell regulatory miRNA in BC compared to normal and CP progenitors. Lentiviral human JAK2 transduction of CD34+ progenitors led to an increase of ADAR1 transcript levels and to a reduction in let-7 family members. Interestingly, lentiviral human JAK2 transduction of normal progenitors enhanced ADAR1 activity, as revealed by RNA editing-specific qRT-PCR and RNA-seq analysis. Moreover, qRT-PCR analysis of CD34+ progenitors transduced with wt-ADAR1, but not mutant ADAR1 lacking functional deaminase activity, reduced let-7 miRNA levels. These data suggested that ADAR1 impairs let-7 family biogenesis in a RNA editing dependent manner. Interestingly, RNA-seq analysis confirmed higher frequency of A-to-I editing events in pri- and pre-let-7 family members in CD34+ BC compared to CP progenitors, as well as normal progenitors transduced with human JAK2 and ADAR1-wt, but not mutant ADAR1. Lentiviral ADAR1 overexpression enhanced CP CML progenitor self-renewal and decreased levels of some members of the let-7 family. In contrast, lentiviral transduction of human let-7a significantly reduced self-renewal of progenitors. In vivo treatments with Dasatinib in combination with a JAK2 inhibitor, significantly reduced self-renewal of BCR-ABL1 expressing BC progenitors in the bone marrow thereby prolonging survival of serially transplanted mice. Finally, a reduction in ADAR1 p150 transcripts was also noted following combination treatment only suggesting a role for ADAR1 in CSC propagation. Conclusion This is the first demonstration that intrinsic BCR-ABL oncogenic signaling and extrinsic cytokines signaling through JAK2 converge on activation of ADAR1 that drives LSC generation by impairing let-7 miRNA biogenesis. Targeted reversal of ADAR1-mediated miRNA editing may enhance eradication of inflammatory niche resident cancer stem cells in a broad array of malignancies, including JAK2-driven myeloproliferative neoplasms. Disclosures Jamieson: J&J: Research Funding; GSK: Research Funding.

Chronic myeloid leukaemia (CML) is caused by the BCR-ABL hybrid gene. The molecular mechanisms leading from chronic phase (CP) to blast crisis (BC) are not understood. However, both the presence and the levels of BCR-ABL seem to be important for CML progression. BCR-ABL is under the transcriptional control of BCR promoter. Here we focused on the gene expression control of BCR and BCR-ABL upon myeloid differentiation in healthy donors (HDs), CP and BC patients. As previously reported, BCR-ABL is downregulated during myeloid maturation in CP patients. A similar pattern was detected for BCR (but not for ABL) in CP-CML and in HD, thus suggesting that the two genes may be under a similar transcriptional control. In BC this mechanism is similarly impaired for both BCR-ABL and BCR. These data indicate the presence of an ‘in trans’ deregulated transcription of both BCR and BCR-ABL promoters, associated with CML progression. The results of the luciferase assay indicate that the region comprised between 420 and 900 bp from the coding ATG site is required to achieve a basal transcription level. Previous studies suggest that a putative SP1 binding site could have a role in the basal promoter activity. In fact, an almost complete absence of transcriptional activity was measured in delta1041 and delta1271 constructs, lacking both the main transcription start site and the putative SP1 binding region. We hypothesize that SP1 could be responsible for the basal promoter activity, present in the delta541 and in longer constructs. The ChIP assay confirmed the SP1-binding to the BCR promoter. The presence of 10 additional putative protein binding sites (PBSs), along the BCR promoter is also known from previous works. Six of these putative PBSs are localized in the region between −1443 to −1202 bp, which appears to be critical from in silico studies. In fact, only in presence of a 221 bp region upstream from delta241, a strong luciferase signal could be detected, suggesting that the promoter region between −1443 and −1202 bp from the coding ATG is indeed critical to achieve the highest level of expression.