ALBERT

Description: Background: BCL6 is known as a protooncogene and transcriptional repressor in diffuse large B cell lymphoma, where it is frequently involved in chromosomal rearrangements. We recently identified BCL6 as a novel mediator of drug resistance to tyrosine kinase inhibitors (TKI) in Philadelphia chromosome-positive acute lymphoblastic leukemia (Ph+ ALL) and chronic myeloid leukemia (Duy et al., Nature 2011; Hurtz et al., J Exp Med 2011). In addition,BCL6 directly competes with the tumor suppressor BACH2 for p53 promotor binding to protecting cells from p53-mediated apoptosis in multiple ALL subgroups (Swaminathan et al., Nature Medicine 2013). Based on this, our current study is focusing on the function of BCL6 in different subtypes of human ALL. Results: Analysis of gene expression data from 207 children with high-risk B cell precursor ALL (COG P9906) showed that high expression levels of BCL6 at the time of diagnosis correlated with a poor overall and relapse-free survival (p=0.007). Furthermore, 49 matched sample pairs from patients at diagnosis and relapse showed increased BCL6 levels at relapse compared to diagnosis (p=0.003). To test whether or not there are specific subtypes of leukemia with high BCL6 expression levels, we studied BCL6 expression via western blot and immunohistochemistry staining in Non-Ph+ cell lines and ALL patient samples (n=76). Interestingly, BCL6 levels are particularly elevated in MLL-rearranged (MLLr) ALL cases. In addition, patients from the clinical trial that had high BCL6 levels and had MLL rearrangements had the worst clinical outcome (p=0.0009). We next tested if MLLr oncogenes drive aberrant BCL6 expression. First, we performed a ChIP-analysis using antibodies against MLL, AF4, and ENL, which provided evidence for direct binding to the BCL6 promoter. We then performed a BCL6 Western blot analysis of inducible MLL-AF4-transgenic and retrovirally transduced MLL-ENL pre-B cells, demonstrating that both oncogenes are sufficient to induce ~10-fold upregulation of BCL6 protein levels. Additionally, we used a newly developed conditional BCL6 knock out/reporter mouse model to decipher the function of BCL6. We transduced B cell progenitor cells from BCL6fl/fl mice with MLL-ENL and either with a control or Cre-expression vector. Using the BCL6 reporter capability of the mouse we found that BCL6 is significantly higher expressed in MLL-ENL transduced cells. To test if MLL is required for BCL6 upregulation, we used a conditional MLL knock out mouse and found that after Cre-mediated deletion of MLL, pro-B, mature-B, and MLL-AF4 transduced ALL cells almost lost the ability to upregulate BCL6. Interestingly, using inducible BCL6 transgenic and knockout as well as retrovirally transduced pre-B and ALL cells showed that overexpression of BCL6 leads to higher expression levels of MLL and deletion of BCL6 results in lower expression levels of MLL. Therefore, we conclude that MLL and BCL6 both cooperate and activate each other's expression in an activating feedback loop. Strikingly, Cre-mediated BCL6- deficiency results in apoptosis of MLL-ENL transduced cells. Clinical relevance: To verify if the high BCL6 expression levels in MLL-AF4 patients are important for the disease progression, we transduced primary human ALL xenografts with a dominant-negative BCL6-mutant (BCL6-DN). Expression of BCL6-DN rapidly induced cell cycle arrest and cell death. To test if pharmacological inhibition of BCL6 is of potential use for patients with MLLr leukemia, we treated multiple MLL-AF4 rearranged human xenograft cases with a RI-BPI a BCL6 peptide inhibitor. Strikingly, treatment with RI-BPI not only compromised colony formation in methylcellulose it also prevents leukemia-initiation in transplant recipient mice. RI-BPI also had a strong synergistic effect when combined with the chemotherapy drug Vincristine, which represents the backbone for most high risk regimen in pediatric ALL. Conclusions: These findings identify BCL6 as a central factor in leukemia initiation and survival and its pharmacological inhibition as a novel strategy to treat MLL-rearranged ALL. Aberrant expression of BCL6 in MLLr ALL is the direct consequence of the MLLr oncogenic activity in these cells. Based on these findings, we propose combinations of BCL6 inhibitors with currently used chemotherapeutics as potential approach to reduce the risk of ALL relapse and improve overall outcome. Disclosures Armstrong: Epizyme, Inc: Consultancy. Ernst:Amgen: Other: stocks. Melnick:Janssen: Research Funding.

Description: Key Points In B-ALL, cells that express a functional pre-BCR ibrutinib abrogate leukemia cell growth in vitro and in vivo. Effects of ibrutinib in B-ALL not only are mediated through inhibition of BTK but also involve BLK inhibition.

Description: Background and hypothesis: CD25 (IL2RA, interleukin 2 receptor α chain) is a transmembrane protein with a 13aa cytoplasmic tail. CD25 cooperates with β- and γ-chains in binding IL-2, but does not contribute to cytokine signaling. During normal B cell development, CD25 is specifically upregulated on the surface of IL7-dependent pre-B cells and is also expressed on the surface of a subset of human pre-B ALL cases. CD25-expressing ALL is typically associated with poor clinical outcome. For these reasons, we studied the functional significance of CD25 expression on human pre-B ALL cells. Results: Flow cytometry and immunohistochemistry staining on a large panel of patient samples (n=416; MDACC, ECOG) revealed specific cell surface expression of CD25 in Ph+ ALL and Ph-like ALL, which are both high-risk subtypes of ALL. In agreement with selective expression on high-risk subsets, high expression levels of CD25 at the time of diagnosis were predictive of poor overall clinical outcome in these studies (P=0.005). BCR-ABL1 in Ph+ ALL and related tyrosine kinases in Ph-like ALL strongly activate STAT5, which then induces transcriptional activation of the IL2RA locus. Since Stat5 is also active during normal pre-B cell differentiation, we first analyzed B cell development in Il2ra-/- mouse bone marrow. Il2ra-/- B cell development was blocked at the pre-B cell stage, consistent with specific upregulation of CD25 on pre-B cells. In human Ph+ ALL cells, we found IL2RB and IL2RG were not co-expressed with CD25, suggesting a function of CD25 in Ph+ALL that is distinct from IL2 signaling. To test the biological significance of tyrosine kinase/STAT5-induced activation of CD25, we developed an Il2ra-/- mouse model for BCR-ABL1 pre-B ALL. Interestingly, the cytoplasmic tail of CD25 includes phosphorylation sites (S268 and T271) that are known substrates for serine/threonine phosphorylation by PKCα, which was reported to regulate protein phosphatase 2A (PP2A). To investigate interacting proteins with the cytoplasmic tail of CD25, we performed immune precipitation (IP) against the flag-tagged CD25-tail in primary Ph+ ALL cells which were transduced with either a CD25-tail-flag or an EV-flag vector. 2D mass spectrometry and Western blot on the IP products confirmed strong interactions with PKCα and PP2A. Weestern blot analysis confirmed additional interactions with inhibitory phosphatases including PTEN, PTPN6 (SHP1) and Inpp5d (SHIP1) in human Ph+ALL cells. In addition, both 2D MS and Westernblot showed recruitment of the Stat5-feedback inhibitors CISH, SOCS2 and SOCS3 at the CD25 cytoplasmic tail. Studying functional parameters of Il2ra-/-BCR-ABL1 ALL cells, we found impaired proliferation and colony formation capacity and drastically increased increased phosphorylation levels of pABLY412, pSTAT5Y694, pERKT202/Y204, pAKTS473, pP38T180/Y182 and p53. Reconstitution of CD25 expression restored normal phosphorylation levels of these molecules, as well as proliferation and colony formation.In a serial transplant setting, we observed that leukemia initiation in transplant recipients from Il2ra-/- BCR-ABL1 ALL cells required 10- to 100-times higher cell numbers, suggesting that CD25 contributes to leukemia initiation. In addition, CD25 expression is associated with a higher level of drug-resistance: In patient-derived pre-B ALL cells with mixed CD25Low and CD25High populations, the standard chemotherapy agent vincristine selectively induced apoptosis of in CD25Low but not CD25High ALL cells. An anti-CD25 immunotoxin drugs efficiently eradiated CD25High leukemia cells and thereby overcame drug-resistance against vincristine. Conclusions: Our studies identified CD25 as a surface receptor that mediates membrane recruitment of PP2A and CISH, SOCS2, negative feedback regulators of STAT5. CD25 is transcriptionally activated by STAT5 and therefore specifically expressed on high-risk ALL subtypes with oncogenic activation of the Stat5 pathway (Ph+ ALL and Ph-like ALL). We propose that CD25-mediated negative feedback control stabilizes oncogenic tyrosine kinase signaling and mediates drug-resistance in Ph+ ALL and Ph-like ALL cells. Targeted inhibition using CD25-directed immunotoxins may be useful in new approaches to overcome drug-resistance in Ph+ ALL and Ph-like ALL. Disclosures No relevant conflicts of interest to declare.

Description: The Sox4 transcription factor mediates early B-cell differentiation. Compared with normal pre-B cells, SOX4 promoter regions in Ph+ ALL cells are significantly hypomethylated. Loss and gain-of-function experiments identified Sox4 as a critical activator of PI3K/AKT and MAPK signaling in ALL cells. ChIP experiments confirmed that SOX4 binds to and transcriptionally activates promoters of multiple components within the PI3K/AKT and MAPK signaling pathways. Cre-mediated deletion of Sox4 had little effect on normal pre-B cells but compromised proliferation and viability of leukemia cells, which was rescued by BCL2L1 and constitutively active AKT and p110 PI3K. Consistent with these findings, high levels of SOX4 expression in ALL cells at the time of diagnosis predicted poor outcome in a pediatric clinical trial (COG P9906). Collectively, these studies identify SOX4 as a central mediator of oncogenic PI3K/AKT and MAPK signaling in ALL.

Description: Abstract 2167 Poster Board II-144 The transcriptional repressor BCL6 was discovered as a potent protooncogene in diffuse large B-cell lymphoma (DLBCL) and is also expressed in normal germinal center (GC) B cells. BCL6 protects DLBCL and GC B cells against DNA damage-induced apoptosis by suppressing target genes including p53, p21, ATR and p27. In preliminary experiments for this study, we found that treatment of BCR-ABL1-driven Ph+ ALL cells with Imatinib results in a 60- to 90-fold up-regulation of BCL6, reaching protein levels as high as in DLBCL and GC B cells. Since the oncogenic BCR-ABL1 kinase also drives leukemic transformation in CML cells, we studied regulation of BCL6 in human CML cells upon TKI-treatment. Like in Ph+ ALL, TKI-treatment resulted in rapid BCL6 mRNA and protein upregulation in CML cells, albeit to lesser degree than in Ph+ ALL and DLBCL. We hypothesized that upregulation of BCL6 in CML cells in response to TKI-treatment serves the same function as in DLBCL and protects from p53-mediated apoptosis. Through transcriptional repression of p53, p21, ATR and p27 as in DLBCL, upregulation of BCL6 in response to TKI-treatment would represent a defense mechanism of CML cells to evade TKI-induced cell death. We tested the role of BCL6 in CML in a genetic loss-of-function experiment: To this end, myeloid progenitor cells from bone marrow of BCL6+/+ and BCL6-/- mice were transformed with BCR-ABL1. Compared to their BCL6+/+ counterparts, BCL6-/- mouse CML cells were highly sensitive to Imatinib-treatment. In a complementary approach, we treated human CML cells with either Imatinib alone or with a novel BCL6 peptide inhibitor (Retro-inverso BCL6-peptide inhibitor, RI-BPI). Consistent with findings in BCL6-/- mouse CML cells, also human CML cells were significantly sensitized to Imatinib by BCL6 inhibition (using 5 mmol/l RI-BPI). Of note, the BCL6 inhibitory peptide RI-BPI alone induced no significant toxicity in human CML cells but synergized with Imatinib-treatment. Since RI-BPI alone had no cytotoxic effect on CML cells, we tested whether loss of BCL6 function affects self-renewal capacity of CML cells. This possibility was explored in two complementary colony formation assays: In one set of experiments, we tested the ability of BCL6+/+ and BCL6-/- mouse CML cells to form colonies in semisolid methylcellulose agar. The comparison between BCL6+/+ (94 ± 11 colonies) and BCL6-/- (

Description: Chronic graft-versus-host disease (GVHD) in patients with allogeneic hematopoietic cell transplantation (HCT) is an immune-mediated syndrome. Both CD4+ T and B cells are required for disease induction, but details of this interaction have not been fully defined. Other groups have reported that germinal centers are enlarged in mice with chronic GVHD and that GC formation is required for induction of the disease. On the other hand, patients with chronic GVHD have a predominance of IgG1 in the serum with little evidence of IgG somatic hypermutation by one year after HCT, suggesting a lack of GC formation (Suzuki et al: Blood. 1996;87:1873-1880; Glas et al: Blood. 2000; 96:1064-1069). Consistently, we observed that GCs were not detectable in mice with chronic GVHD, including MHC-matched C57BL/6 (H-2b) recipients given LP/J (H-2b) grafts and BALB/c (H-2d) recipients given DBA/2 (H-2d) or B10D2 (H-2d) grafts, and MHC-mismatched BALB/c (H-2d) recipients given C57BL/6 (H-2b) grafts. Furthermore, BALB/c recipients given grafts from BCL6-deficient (BCL6 fl/fl Mb1-Cre) C57BL/6 (H-2b) donors lacking the ability to form GC developed chronic GVHD with similar severity to recipients given control BCL6-sufficient grafts. Consistent with lack of GC formation, recipients of BCL6-deficient grafts had profound reduction of serum IgG2b and IgG2c but moderate reduction of IgG1 as compared to recipients given control BCL6-sufficient grafts. The presence of IgG1 indicates extrafollicular CD4+ T and B interaction, which is Stat-3 dependent. Further experiments showed BALB/c recipients given grafts from Stat3-deficient (Stat-3 fl/fl CD4-Cre) C57BL/6 donors did not develop chronic GVHD. Taken together, these results indicate that GC formation is not required for development of chronic GVHD and that extrafollicular CD4+ T and B interaction can induce chronic GVHD. This work is supported by NIH R01 AI066008 and The Beckman Research Institute Excellence Award (to D. Zeng). Disclosures Forman: Mustang: Research Funding; Amgen: Consultancy. Martin:Neovii: Research Funding; RegImmune: Research Funding; Enlivex: Consultancy; Janssen: Consultancy; Pfizer: Consultancy; Pharmacyclics: Consultancy.

Description: Oncogenic lesions in hematopoietic progenitor cells give rise to B-cell or myeloid malignancies. While often transformed by the same oncogenes, B-cell and myeloid leukemias markedly differ in biological and clinical characteristics. Our metabolic analyses revealed that B-cell-unlike myeloid-leukemia cells are massively restricted in their glycolytic capacity. Low glycolytic reserves in B cells resulted in a state of chronic energy depletion and engaged the energy sensor LKB1-AMPK. Myeloid cells strongly activated glucose transport through insulin receptor (INSR)-AKT signaling and lacked activity of LKB1-AMPK, reflecting energy abundance. Conversely, B-cells lacked INSR-AKT signaling and were critically dependent on LKB1-AMPK-mediated glucose uptake. Cre-mediated deletion of Lkb1 caused acute glycolytic exhaustion and cell death in B-lineage but increased glycolysis, energy levels and proliferation in myeloid leukemia. C/EBPa-mediated conversion of B-cell into myeloid identity reversed the detrimental effects of Lkb1-deletion and restored glycolysis, energy levels and survival of B→myeloid reprogrammed cells. In 〉80% of B-lineage leukemia cases, we found genetic lesions of transcription factors (e.g. deletion of PAX5, IKZF1, rearrangement of MLL) that caused a B→myeloid lineage shift. While previously of unknown functional significance, these lesions relieved B-cell-specific transcriptional repression of molecules that mediate glucose uptake and utilization (INSR, GLUT1, HK2, G6PD) and amplified glycolytic energy supply for transforming oncogenes. Likewise, glucocorticoid receptor (NR3C1)-mediated inhibition of glucose uptake and glycolysis was strictly dependent on a B-lymphoid transcriptional program. B→myeloid lineage conversion abolished NR3C1 expression and activity, which provides a mechanistic explanation for the empiric finding that glucocorticoids are highly active in the treatment of B-cell-but not myeloid malignancies. In conclusion, B-cell-specific restriction of glycolytic energy supply represents a previously unrecognized metabolic barrier against malignant transformation and reveals LKB1-AMPK as a novel target for the treatment of human B-lineage leukemia. Disclosures No relevant conflicts of interest to declare.

Description: Background and Hypothesis: The transcriptional repressor and proto-oncogene BCL6 is a therapeutic target in subtypes of diffuse large B cell lymphoma (DLBCL) and modulates drug-resistance in Philadelphia chromosome-positive acute lymphoblastic leukemia (Ph+ ALL; Duy et al., Nature 2011). BCL6 was shown to be a critical factor that bypasses p53-dependent senescence and thereby enables RAS-driven transformation of mouse embryonic fibroblasts (Shvarts et al., Genes Dev. 2002). Given that ~50% of pediatric ALL cases carry genetic lesions that lead to hyperactivated RAS-ERK signaling (Zhang et la., Blood 2012), we examined the role of BCL6 in RAS-driven pre-B ALL and identified a novel mechanism by which RAS-ERK signaling can mediate BCL6 expression. Results: Using a doxycycline-inducible TetOn- NRASG12D vector system, we found that inducible activation of RAS-ERK signaling strongly upregulated BCL6 expression at both the mRNA (~350-fold) and protein (~50-fold) levels in murine pre-B cells. Increases in BCL6 expression were abrogated upon treatment with a MEK inhibitor (PD325901). In addition, Cre-mediated deletion of Mapk1 suppressed upregulation of BCL6 expression upon imatinib treatment in BCR-ABL1-driven pre-B ALL cells. These findings suggested that elevated expression of BCL6 is a consequence of ERK activation. Previously, we demonstrated that BCL6 expression is negatively regulated by STAT5 in BCR-ABL1 pre-B ALL (Duy et al., Nature 2011). Interestingly, oncogenic NRASG12D inhibited phosphorylation of STAT5-Y694 by activating the inhibitory protein tyrosine phosphatase Ptpn6. Cre-mediated deletion of Ptpn6 induced STAT5 activity. Furthermore, loss of Ptpn6 function abrogated upregulation of BCL6 expression induced by imatinib in BCR-ABL1 pre-B ALL. Taken together, RAS-ERK signaling induces BCL6 expression by suppressing STAT5 activity. To directly test the role of BCL6 in RAS-transformed pre-B ALL, we generated a novel mouse model for inducible Cre-mediated deletion of Bcl6 exons 5-10, flanked by loxP sites. Inducible deletion of Bcl6 in NRASG12D-transformed pre-B ALL cells led to rapid depletion from the cell culture and reduced colony forming ability in vitro. These findings suggested that BCL6 is required for maintenance of fully established RAS-transformed ALL. Notably, we found that initiation of NRASG12D-driven leukemia in vivo depends on BCL6 as NRASG12D ALL failed to give rise to leukemia in the absence of Bcl6 in transplant recipient mice. Studying a diagnostic (KRAS wild-type) and a relapsed (KRASG12V) sample from one pre-B ALL patient revealed increased BCL6 expression in KRASG12V relapsed ALL cells. In addition, selective sensitivity to PD325901 and a retro inverso BCL6 peptide inhibitor (RI-BPI) was observed in KRASG12V relapsed ALL cells. Finally, RI-BPI prolonged overall survival of recipient mice transplanted with KRASG12V relapsed ALL cells in vivo. Conclusions: In summary, we demonstrated a novel mechanism by which oncogenic RAS signaling induces expression of BCL6, and showed that BCL6 is critical for RAS-driven transformation in pre-B ALL. Importantly, ALL clones often acquire drug resistance and activating mutations in the RAS pathway (Bhojwani and Pui, Lancet Oncol. 2013). Our findings suggest that pharmacological inhibition of BCL6 may provide a novel therapeutic avenue to overcome drug-resistance and prevent leukemia relapse after initial remission in RAS-driven ALL. Disclosures Melnick: Janssen: Research Funding.