Lai N. Chan

Self-Enforcing Feedback Activation between BCL6 and Pre-B Cell Receptor Signaling Defines a Distinct Subtype of Acute Lymphoblastic Leukemia

Studying 830 pre-B ALL cases from four clinical trials, we found that human ALL can be divided into two fundamentally distinct subtypes based on pre-BCR function. While absent in the majority of ALL cases, tonic pre-BCR signaling was found in 112 cases (13.5%). In these cases, tonic pre-BCR signaling induced activation of BCL6, which in turn increased pre-BCR signaling output at the transcriptional level. Interestingly, inhibition of pre-BCR-related tyrosine kinases reduced constitutive BCL6 expression and selectively killed patient-derived pre-BCR(+) ALL cells. These findings identify a genetically and phenotypically distinct subset of human ALL that critically depends on tonic pre-BCR signaling. In vivo treatment studies suggested that pre-BCR tyrosine kinase inhibitors are useful for the treatment of patients with pre-BCR(+) ALL.

Mechanistic rationale for targeting the unfolded protein response in pre-B acute lymphoblastic leukemia

Significance The unfolded protein response (UPR) mitigates endoplasmic reticulum (ER) stress. In this regard, ER stress-inducing agents were found to be highly active in a clinical trial for children with relapsed acute lymphoblastic leukemia (ALL), a disease derived from transformed pre-B cells. To understand the efficacy of ER stress-inducing agents in pre-B ALL, we studied the relevance of the UPR pathway in genetic and patient-derived (xenograft) models of human pre-B ALL. Our studies revealed an unrecognized vulnerability of both normal pre-B cells and pre-B cell-derived ALL cells to genetic or pharmacological blockade of the UPR pathway. Our results establish a mechanistic rationale for the treatment of children with pre-B ALL with agents that block the UPR pathway and induce ER stress. The unfolded protein response (UPR) pathway, a stress-induced signaling cascade emanating from the endoplasmic reticulum (ER), regulates the expression and activity of molecules including BiP (HSPA5), IRE1 (ERN1), Blimp-1 (PRDM1), and X-box binding protein 1 (XBP1). These molecules are required for terminal differentiation of B cells into plasma cells and expressed at high levels in plasma cell-derived multiple myeloma. Although these molecules have no known role at early stages of B-cell development, here we show that their expression transiently peaks at the pre–B-cell receptor checkpoint. Inducible, Cre-mediated deletion of Hspa5, Prdm1, and Xbp1 consistently induces cellular stress and cell death in normal pre-B cells and in pre–B-cell acute lymphoblastic leukemia (ALL) driven by BCR-ABL1- and NRASG12D oncogenes. Mechanistically, expression and activity of the UPR downstream effector XBP1 is regulated positively by STAT5 and negatively by the B-cell–specific transcriptional repressors BACH2 and BCL6. In two clinical trials for children and adults with ALL, high XBP1 mRNA levels at the time of diagnosis predicted poor outcome. A small molecule inhibitor of ERN1-mediated XBP1 activation induced selective cell death of patient-derived pre-B ALL cells in vitro and significantly prolonged survival of transplant recipient mice in vivo. Collectively, these studies reveal that pre-B ALL cells are uniquely vulnerable to ER stress and identify the UPR pathway and its downstream effector XBP1 as novel therapeutic targets to overcome drug resistance in pre-B ALL.

Metabolic gatekeeper function of B-lymphoid transcription factors

B-lymphoid transcription factors, such as PAX5 and IKZF1, are critical for early B-cell development, yet lesions of the genes encoding these transcription factors occur in over 80% of cases of pre-B-cell acute lymphoblastic leukaemia (ALL). The importance of these lesions in ALL has, until now, remained unclear. Here, by combining studies using chromatin immunoprecipitation with sequencing and RNA sequencing, we identify a novel B-lymphoid program for transcriptional repression of glucose and energy supply. Our metabolic analyses revealed that PAX5 and IKZF1 enforce a state of chronic energy deprivation, resulting in constitutive activation of the energy-stress sensor AMPK. Dominant-negative mutants of PAX5 and IKZF1, however, relieved this glucose and energy restriction. In a transgenic pre-B ALL mouse model, the heterozygous deletion of Pax5 increased glucose uptake and ATP levels by more than 25-fold. Reconstitution of PAX5 and IKZF1 in samples from patients with pre-B ALL restored a non-permissive state and induced energy crisis and cell death. A CRISPR/Cas9-based screen of PAX5 and IKZF1 transcriptional targets identified the products of NR3C1 (encoding the glucocorticoid receptor), TXNIP (encoding a glucose-feedback sensor) and CNR2 (encoding a cannabinoid receptor) as central effectors of B-lymphoid restriction of glucose and energy supply. Notably, transport-independent lipophilic methyl-conjugates of pyruvate and tricarboxylic acid cycle metabolites bypassed the gatekeeper function of PAX5 and IKZF1 and readily enabled leukaemic transformation. Conversely, pharmacological TXNIP and CNR2 agonists and a small-molecule AMPK inhibitor strongly synergized with glucocorticoids, identifying TXNIP, CNR2 and AMPK as potential therapeutic targets. Furthermore, our results provide a mechanistic explanation for the empirical finding that glucocorticoids are effective in the treatment of B-lymphoid but not myeloid malignancies. Thus, B-lymphoid transcription factors function as metabolic gatekeepers by limiting the amount of cellular ATP to levels that are insufficient for malignant transformation.

PTEN opposes negative selection and enables oncogenic transformation of pre-B cells

Phosphatase and tensin homolog (PTEN) is a negative regulator of the phosphatidylinositol 3-kinase (PI3K) and protein kinase B (AKT) signaling pathway and a potent tumor suppressor in many types of cancer. To test a tumor suppressive role for PTEN in pre-B acute lymphoblastic leukemia (ALL), we induced Cre-mediated deletion of Pten in mouse models of pre-B ALL. In contrast to its role as a tumor suppressor in other cancers, loss of one or both alleles of Pten caused rapid cell death of pre-B ALL cells and was sufficient to clear transplant recipient mice of leukemia. Small-molecule inhibition of PTEN in human pre-B ALL cells resulted in hyperactivation of AKT, activation of the p53 tumor suppressor cell cycle checkpoint and cell death. Loss of PTEN function in pre-B ALL cells was functionally equivalent to acute activation of autoreactive pre–B cell receptor signaling, which engaged a deletional checkpoint for the removal of autoreactive B cells. We propose that targeted inhibition of PTEN and hyperactivation of AKT triggers a checkpoint for the elimination of autoreactive B cells and represents a new strategy to overcome drug resistance in human ALL.

SOX4 enables oncogenic survival signals in acute lymphoblastic leukemia

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.

Loss of Pax5 exploits Sca1-BCR-ABLp190 susceptibility to confer the metabolic shift essential for pB-ALL

Preleukemic clones carrying BCR-ABLp190 oncogenic lesions are found in neonatal cord blood, where the majority of preleukemic carriers do not convert into precursor B-cell acute lymphoblastic leukemia (pB-ALL). However, the critical question of how these preleukemic cells transform into pB-ALL remains undefined. Here, we model a BCR-ABLp190 preleukemic state and show that limiting BCR-ABLp190 expression to hematopoietic stem/progenitor cells (HS/PC) in mice (Sca1-BCR-ABLp190) causes pB-ALL at low penetrance, which resembles the human disease. pB-ALL blast cells were BCR-ABL-negative and transcriptionally similar to pro-B/pre-B cells, suggesting disease onset upon reduced Pax5 functionality. Consistent with this, double Sca1-BCR-ABLp190+Pax5+/- mice developed pB-ALL with shorter latencies, 90% incidence, and accumulation of genomic alterations in the remaining wild-type Pax5 allele. Mechanistically, the Pax5-deficient leukemic pro-B cells exhibited a metabolic switch toward increased glucose utilization and energy metabolism. Transcriptome analysis revealed that metabolic genes (IDH1, G6PC3, GAPDH, PGK1, MYC, ENO1, ACO1) were upregulated in Pax5-deficient leukemic cells, and a similar metabolic signature could be observed in human leukemia. Our studies unveil the first in vivo evidence that the combination between Sca1-BCR-ABLp190 and metabolic reprogramming imposed by reduced Pax5 expression is sufficient for pB-ALL development. These findings might help to prevent conversion of BCR-ABLp190 preleukemic cells.Significance: Loss of Pax5 drives metabolic reprogramming, which together with Sca1-restricted BCR-ABL expression enables leukemic transformation. Cancer Res; 78(10); 2669-79. ©2018 AACR.

B-cell identity as a metabolic barrier against malignant transformation

B-lineage and myeloid leukemia cells are often transformed by the same oncogenes, but have different biological and clinical characteristics. Although B-lineage acute lymphoblastic leukemia (B-ALL) cells are characterized by a state of chronic energy deficit, myeloid leukemia cells show abundant energy reserve. Interestingly, fasting has been demonstrated to inhibit selectively the development of B-ALL but not myeloid leukemia, further suggesting that lineage identity may be linked to divergent metabolic states in hematopoietic malignancies. The B-lymphoid transcription factors IKZF1, EBF1, and PAX5 are essential for early B-cell development and commitment to B-cell identity. However, in >80% of human pre-B-ALL cases, the leukemic clones harbor genetic lesions of these transcription factors. The significance of these defects has only recently been investigated. Here, we discuss the unexpected function of a B-lymphoid transcriptional program as a metabolic barrier against malignant transformation of B-cell precursor cells. The metabolic gatekeeper function of B-lymphoid transcription factors may force silent preleukemic clones carrying potentially oncogenic lesions to remain in a latent state. In addition, this program sets the threshold for responses to glucocorticoids in pre-B-ALL. Finally, the link between the tumor-suppressor and metabolic functions of B-lymphoid transcription factors is matched by observations in clinical trials: obesity and hyperglycemia are associated with poor clinical outcome in patients with pre-B-ALL.

Author Correction: Metabolic gatekeeper function of B-lymphoid transcription factors

Author(s): Chan, LN; Chen, Z; Braas, D; Lee, J-W; Xiao, G; Geng, H; Cosgun, KN; Hurtz, C; Shojaee, S; Cazzaniga, V; Schjerven, H; Ernst, T; Hochhaus, A; Kornblau, SM; Konopleva, M; Pufall, MA; Cazzaniga, G; Liu, GJ; Milne, TA; Koeffler, HP; Ross, TS; Sanchez-Garcia, I; Borkhardt, A; Yamamoto, KR; Dickins, RA; Graeber, TG; Muschen, M | Abstract: In Fig. 3c of this Letter, the the effects of CRISPR-Cas9-mediated deletion of NR3C1, TXNIP and CNR2 in patient-derived B-lineage leukaemia cells were shown. For curves depicting NR3C1 (left graph), data s for TXNIP (middle graph) were inadvertently plotted. This figure has been corrected online, and the original Fig. 3c is shown as Supplementary Information to this Amendment for transparency. The error does not affect the conclusions of the Letter. In addition, Source Data files have been added for the Figs. 1-4 and Extended Data Figs. 1-10 of the original Letter.

Abstract 93: Transcriptional control of glucocorticoid responses in leukemia

Glucocorticoids (GCs) are central to all major therapy regimens for pre-B cell-derived acute lymphoblastic leukemia (ALL), but have no activity in myeloid leukemia. Such divergent responses represent an empirically established clinical standard; however, neither the mechanism by which GCs induce cell death nor the biological basis for the distinct responses in B-cell and myeloid leukemias is clear. Studying patient-derived samples revealed that NR3C1 (glucocorticoid receptor) levels were 6- to 20-fold higher in pre-B ALL compared to chronic myeloid leukemia (CML). High levels of Nr3c1 were reduced upon B- to myeloid-lineage conversion, suggesting that regulation of NR3C1 expression and GC responsiveness depend on a B-cell transcriptional program. B-cell transcription factors (e.g. PAX5, IKZF1) are critical for B-cell development, yet they are genetically lesioned in more than 80% of pre-B ALL cases. Despite such high frequency, the significance of these inactivating lesions remains elusive. Combining ChIP-seq and RNA-seq analyses, we identified a novel B-cell transcriptional program for activation of NR3C1 and its transcriptional target TXNIP (a negative regulator of glucose uptake). Reconstitution of PAX5 or IKZF1 expression in haploinsufficient patient-derived pre-B ALL cells increased NR3C1 and TXNIP levels. Conversely, expression of dominant negative mutant of PAX5 or IKZF1 abolished NR3C1 expression. Loss of Nr3c1 or Txnip in murine BCR-ABL1-driven pre-B ALL cells resulted in survival advantage in competitive growth assays. Importantly, loss of Nr3c1 or Txnip significantly elevated glucose uptake, lactate production and cellular ATP levels. These findings suggest that GCs induce cell death by exacerbating glucose and energy depletion. Notably, reconstitution of PAX5 or IKZF1 rendered haploinsufficient patient-derived pre-B ALL cells more sensitive to dexamethasone (dex) treatment. In contrast, dominant-negative PAX5 or IKZF1 largely de-sensitized pre-B ALL cells expressing wildtype PAX5 or IKZF1. These findings suggest that B-cell transcription factors set the threshold for GC responsiveness in pre-B ALL. Since relapsed ALL cells often acquire GC resistance, drug-combinations may be useful to prevent GC-resistance. As expected, loss of Nr3c1 abrogated responses to GCs. Interestingly, loss of Txnip also largely rescued GC-induced cell death in pre-B ALL cells. On this basis, we tested drug interactions between GCs and TXNIP agonists, 3-O-methylglucose (3-OMG) and D-allose. Treating patient-derived GC-refractory pre-B ALL cells with 3-OMG or D-allose strongly synergized with GC-treatment. Collectively, our findings provide a mechanistic explanation for the empiric finding that GCs are effective in the treatment of B-cell but not myeloid malignancies, and identify TXNIP as a novel therapeutic target in pre-B ALL. Note: This abstract was not presented at the meeting. Citation Format: Lai N. Chan, Zhengshan Chen, Gang Xiao, Jae Woong Lee, Kadriye Nehir Cosgun, Huimin Geng, Valeria Cazzaniga, Hilde Schjerven, Ross A. Dickins, Markus Muschen. Transcriptional control of glucocorticoid responses in leukemia [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 93. doi:10.1158/1538-7445.AM2017-93

Abstract 1124: Transcriptional control of B cell identity restricts metabolic fitness in human leukemia

Oncogenic lesions in multi-potent progenitor cells often give rise to either B-cell or myeloid lineage leukemia. While transformed by the same oncogenes (e.g. BCR-ABL1, RAS), B-lineage and myeloid leukemias are distinct diseases. Given that oncogenic tyrosine kinase signaling (e.g. BCR-ABL1) imposes significant metabolic requirements on energy supply, biogenesis and metabolic fitness, we studied whether the divergent characteristics of myeloid and B-lineage leukemias have a metabolic basis. Metabolic analyses revealed that B-lineage acute lymphoblastic leukemia (Ph+ ALL) cells proliferate at maximum capacity of their glycolytic machinery. In contrast to myeloid leukemia (CML), B-lineage ALL cells lack metabolic adaptive fitness in response to metabolic fluctuations. C/EBPα-mediated reprogramming of B-lineage cells into the myeloid lineage induced glycolytic gene expression (Insr, Slc2a1, G6pdx, G6pd2, and Hk3). Frequent genetic lesions of transcription factors that determine B cell identity (IKZF1, PAX5, EBF1) partially mitigate B cell-instrinsic metabolic liability. Reconstitution of PAX5 expression in patient-derived B-lineage ALL cells reduced metabolic fitness by impacting glucose metabolism. Using genetic and metabolic experiments, we identified the metabolic liability observed in B-lineage ALL is in part dependent on the serine/threonine kinase LKB1. In agreement with previous studies, Cre-mediated deletion of Lkb1 induced proliferation in myeloid leukemia. Surprisingly, Lkb1 deletion led to apoptosis and decreased leukemogenic capacity in B-lineage leukemia. Consistent with the above observations, Arf, p53 and p27 levels were reduced in Lkb1-deficient myeloid leukemia cells, while Lkb1 deletion in B-lineage ALL cells up-regulated Arf, p53 and p27 levels. Enhanced glucose consumption and lactate production were observed in Lkb1-deficient myeloid leukemia cells. In contrast, loss of Lkb1 led to defective glycolytic and mitochondrial activity in B-lineage ALL. Lkb1 deletion in B-lineage ALL caused global accumulation of metabolites, suggesting that LKB1 is required for maintaining metabolic homeostasis. Moreover, loss of Lkb1 decreased protein levels of mitochondrial, anti-apoptotic BCL-2 family proteins, BCL-xL and MCL1, in B-lineage ALL. Reverse Phase Protein Array analyses revealed that LKB1 levels positively correlated with BCL-xL and MCL1 in patient-derived Ph+ ALL samples (n = 51) as well as other subtypes of B-lineage ALL (n = 183; MDACC, 1983-2007). Importantly, C/EBPα-mediated reprogramming of B-lineage ALL cells to the myeloid linage relieved dependency on LKB1. Taken together, we showed that transcriptional control of B cell identity causes unique metabolic liability. B-lineage ALL cells exhibit unique reliance on LKB1 for metabolic homeostasis and survival. Our findings revealed LKB1 as a potential therapeutic target in B-lineage ALL. Note: This abstract was not presented at the meeting. Citation Format: Lai N. Chan, Daniel Braas, Christian Hurtz, Seyedmehdi Shojaee, Huimin Geng, Valeria Cazzaniga, Carina Ng, Behzad Kharabi Masouleh, Yi Hua Qiu, Nianxiang Zhang, Kevin R. Coombes, Thomas Ernst, Giovanni Cazzaniga, Andreas Hochhaus, Steven Kornblau, Thomas Graeber. Transcriptional control of B cell identity restricts metabolic fitness in human leukemia. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 1124. doi:10.1158/1538-7445.AM2015-1124