ALBERT

Description: Asparaginase (ASNase) is one of the cornerstones of the multi-drug treatment protocol that is used to treat acute lymphoblastic leukemia (ALL) in pediatric and adult patients. Despite the fact that ASNase has been used in ALL treatment protocols for decades, little is known about the biodistribution and the mechanism of ASNase turnover in vivo. A large inter-individual variation in ASNase pharmacokinetics is observed in patients. While elevated ASNase levels are associated with an increase in adverse events, underexposure, frequently caused by antibody mediated clearance, seriously reduces therapeutic efficacy. To date, it is not possible to predict pharmacokinetics of ASNase in individual patients and therefore current therapeutic protocols are supported by frequent monitoring of ASNase levels and adjustments of administration schemes. We used an in vivo imaging approach to study ASNase biodistribution and pharmacodynamics in a mouse model and provide in vitro and in vivo evidence that identifies the endo-lysosomal protease Cathepsin B in macrophages as a critical component of ASNase degradation. Results/Discussion Mice were injected with 111Indium-labeled ASNase and biodistribution was monitored by quantitative microSPECT/CT scans and ex vivo analysis of organs using a gamma counter. Over time, ASNase accumulated in the liver and particularly the spleen and the bone marrow. We hypothesized that macrophages in these organs, efficiently take up the ASNase, thereby rapidly clearing the active enzyme from the blood. Immunohistochemical analysis confirmed the presence of ASNase in cells positive for the murine macrophage marker F4/80. To confirm the importance of macrophage populations in ASNase clearance, we depleted mice from phagocytic cells by injection of clodronate liposomes, and studied ASNase biodistribution and kinetics. Indeed, clodronate pretreatment significantly diminished the accumulation of ASNase in the liver, spleen and the bone marrow while doubling the circulatory half-life of serum ASNase activity. We conclude from these experiments that macrophages determine the pharmacokinetics of asparaginase, which raises the question whether rapid clearance of the drug by bone marrow resident macrophages will negatively affect the depletion of asparagine in the bone marrow niche. We previously linked a germline mutation in the gene encoding endosomal protease Cathepsin B to strongly diminished asparaginase degradation in a pediatric ALL patient. To connect the macrophage mediated clearance to the proposed role of Cathepsin B in ASNase degradation, we studied the contribution of this protease in macrophage-mediated degradation of asparaginase. We used cell lines to show that Cathepsin B expression is induced during differentiation from monocytes towards macrophages. This is consistent with our finding that macrophages, but not monocytes, are capable of degrading ASNase. Furthermore, we used both chemical inhibition and RNAi mediated knockdown of Cathepsin B to show that this protease is required for ASNase degradation in these macrophages. Finally, by comparing Cathepsin B knockout mice with wildtype littermates, we demonstrated that loss of Cathepsin B activity significantly delayed clearance of serum asparaginase, consistent with a prominent role for this lysosomal protease in ASNase turnover. In conclusion, by using in vivo imaging we showed that asparaginase is efficiently cleared from the circulation by macrophages. In particular, bone marrow resident macrophages may provide a protective environment for leukemic cells by effectively removing the therapeutic protein from the bone marrow niche. However, both the prominent role of macrophages and the importance of the lysosomal protease Cathepsin B in asparaginase clearance, may allow the rational design of a next generation asparaginase. Disclosures Metselaar: Enceladus Pharmaceuticals: Employment, Equity Ownership.

Description: B cell precursor acute lymphoblastic leukemia (BCP-ALL) is one of the most common malignancies in children. In the period 1991-2013, the Dutch Childhood Oncology Group (DCOG) has completed three treatment trials for childhood ALL: ALL8, 9 and 10, each protocol with stratifications into risk-groups (details: www.skion.nl). Although the cure rates increased in these subsequent trials, relapses still occurred in a significant number of children. Since consecutive upfront treatment protocols usually change at multiple levels, genomic alterations that are associated with relapse may also be variable, which could provide insight into the biology underlying therapy failure and relapse. In this study, we characterized the genetic architecture of relapsed BCP-ALL patients within the context of these three Dutch upfront protocols. We identified 3 patient groups based on upfront treatment as follows: Group-1: patients treated upfront with high-amounts of corticosteroids (CS) and relatively mild additional chemotherapy (ALL9 NHR/HR); Group-2: patients treated with high-amounts of CS and intensive additional chemotherapy (ALL10 MR); Group-3: patients treated with low-amounts of CS and moderately-intensive additional chemotherapy (ALL8 SR/MR, ALL10 SR). The number of high-risk patients that relapsed after ALL8 HR and ALL10 HR chemotherapy courses was too low to be included for analysis. We determined, at relapse, the presence of copy number alterations and sequence mutations in 21 recurrently affected genes involved in B-cell development, cell cycle regulation and RAS signaling, in 123 patients that relapsed after treatment in group-1 (n=56), group-2 (n=20) and group-3 (n=47). The number of CREBBP mutations in patients that relapsed after treatment according to group-1 (ALL9) was significantly lower compared to the other two groups, whereas B-cell development alterations were most common in patients that relapsed after treatment according to group-1, mainly due to a higher number of IKZF1 alterations (Figure 1). The high number of relapsed patients with leukemic clones carrying IKZF1 alterations in patients treated with high-amounts of CS and relatively mild additional chemotherapy is in line with our recent finding that IKZF1 is a key determinant of GC-induced apoptosis in normal and leukemic B-cells, and that loss of IKZF1 function confers resistance to dexamethasone, the major treatment component in group-1 (Marke et al., submitted). Additionally, in the group-2 patients treated with high-amounts of CS and highly intensive additional chemotherapy, a lower percentage IKZF1-deleted clones was detected at relapse, indicating that more GC-resistant, IKZF1-deleted clones are killed by the intense chemotherapy given in addition to CS in group-2 patients. Similarly, in the group-3 patients relapsing after treatment with lower amounts of CS and moderately-intensive additional chemotherapy, the percentage of surviving IKZF1-deleted clones was lower than in patients treated with high-amounts of CS. Taken together, our data indicate that the genetic architecture of relapsed BCP-ALL patients depends on the upfront treatment and, in addition, that the poor-prognostic feature of IKZF1-deletions may be more prominent in upfront treatment with high-amounts of CS and relatively mild additional chemotherapy. Figure 1. The frequency of genetic alterations in studied genes in patients that relapsed after treatment according to group-1, 2 and 3. Genes were grouped by their corresponding pathways. Group-1: patients treated upfront with high-amounts of CS and relatively mild additional chemotherapy (ALL9 NHR/HR); Group-2: patients treated with high-amounts of CS and intensive additional chemotherapy (ALL10 MR); Group-3: patients treated with low-amounts of CS and moderately-intensive additional chemotherapy (ALL8 SR/MR, ALL10 SR). Asterisk showed significant difference between upfront treatment groups, **p

Description: Current risk assessments for treatment of children with B-cell precursor acute lymphoblastic leukemia (BCP-ALL) are based on several clinical and biological criteria, including genomic alterations. Genomic profiling of BCP-ALL in the last few years has substantially extended the number of risk factors that can be used for risk stratification, including a novel entity known as BCR-ABL1 -like or Ph-like ALL. This subgroup of BCR-ABL1-like cases is characterized by the high recurrence of a diverse repertoire of novel gene fusions and mutations which frequently result in enhanced tyrosine kinase and cytokine receptor signaling [Roberts et al., NEJM 2014;371:1005-15]. Leukemia's with these alterations could potentially be targeted with appropriate tyrosine kinase inhibitors. Clinical trials with newly-diagnosed patients carrying these alterations are therefore required, but the large genomic diversity within this group of patients currently provides a major bottleneck. Here, we describe the use of Targeted Locus Amplification (TLA), combined with deep-sequencing to detect fusion genes and sequence mutations relevant for stratification of BCP-ALL. TLA involves a strategy to selectively amplify and sequence regions 〉100 kb around a preselected primer pair by crosslinking of physically proximal genomic sequences [de Vree et al., Nat Biotechnol. 2014;32:1019-25]. Since TLA results in the amplification of all sequences at either end of the primer pair, TLA is highly effective in picking up structural variations including novel fusion partners. Furthermore, breakpoints can be identified from the TLA sequencing data from which targets for detection of minimal residual disease can be directly designed. A total of 31 primer sets targeting 19 recurrently affected genes were designed and multiplexed, including the 'classical' players MLL, RUNX1, TCF3, and IKZF1, the tyrosine kinase genes ABL1, ABL2, PDGFRB, CSF1R, JAK1, JAK2, JAK3, FLT3, and TYK2, and the cytokine signaling genes CRLF2, EPOR, IL7R, TSLP, SH2B3, and IL2RB. Primer sets were chosen such that the most relevant regions were sufficiently covered. As a pilot, viable cells from 46 selected BCP-ALL samples were analysed, including 26 cases with a BCR-ABL1 -like expression profile [Den Boer et al., Lancet Oncol. 2009;10:125-34], of which 6 had a known kinase fusion. 7 Gb of aligned sequence data was obtained for each patient sample. All 21 rearrangements known to be present in these samples were detected by TLA, including rearrangements in ETV6-RUNX1 (n=5), MLL (n=4), TCF3-PBX1 (n=3), CRLF2 (n=4), EBF1-PDGFRB (n=2), BCR-ABL1 (n=1), RCSD1-ABL2 (n=1), and SSBP2 -CSF1R (n=1). For 10 of the fusions sequencing depth was sufficient to extract breakpoint-spanning sequences directly. For two cases with known JAK2 fusions with an unknown partner, the fusion gene was identified (TERF2 and BCR), as was the case for an unknown ABL1 fusion (FOXP1). New fusions were identified in 9 cases, including previously described IGH@-EPOR and TCF3-ZNF384 fusions, and novel kinase activating fusions of MAP3K19-TSLP and HDAC9-FLT3. In addition we identified deletion breakpoint fusions in IKZF1, and sequence mutations in JAK1, JAK3,and IL7R. In total, we detected gene fusions or sequence mutations affecting tyrosine kinase or cytokine receptor signaling in 16 of the 26 cases with a BCR-ABL1 -like expression profile. We conclude that TLA is an effective method for the reliable detection of sequence mutations and structural variations that are relevant for disease prognosis and/or could be targeted by approved kinase inhibiton. Disclosures Simonis: Cergentis BV: Employment. Klous:Cergentis BV: Employment. Yilmaz:Cergentis BV: Employment. Splinter:Cergentis BV: Employment.

Description: Deletions and mutations affecting transcription factor IKZF1 are associated with increased relapse risk and poor outcome in B cell precursor acute lymphoblastic leukemia (BCP-ALL). However, additional genetic events may either enhance or negate the effects of IKZF1 on prognosis. We observed that deletions of the gene encoding the transcriptional coregulator BTG1 frequently co-occured with loss of IKZF1 function, suggesting a synergistic role for these events during leukemia development or progression. Targeted deletion of Btg1 predisposed both Btg1+/- and Btg1-/- mice to T cell malignancies, similar to what has been observed in Ikzf1 heterozygous knockout animals. Hence, while somatic single single-copy losses of either BTG1 and IKZF1 in the patient are predominantly found in BCP-ALL, targeted deletion of these genes in the mouse gives rise to T cell malignancies. To establish whether loss of BTG1 function affected the tumor suppressive role of IKZF1, the Btg1 knockout allele was crossed onto mice heterozygous for a loss-of-function Ikzf1 allele. Leukemia penetrance in these compound mice increased in a Btg1 dose-dependent manner. These leukemias were characterized by clonal TCRb rearrangement and aggressive infiltration into secondary organs, indicating synergistic roles for these tumor suppressors during mouse leukemia development. To investigate the effects of combined IKZF1/BTG1 loss in human BCP-ALL, we examined a large pediatric cohort of BCP-ALL cases, and found that the combined presence of BTG1 and IKZF1 deletions was associated with a markedly higher incidence of relapse, relative to IKZF1-deleted cases without BTG1 aberrations. Similar to BTG1 copy number losses, deletions in EBF1, PAX5, RB1 and CDKN2A/B appeared to be selectively enriched in IKZF1 deleted ALL. However, in contrast to BTG1, none of these other copy number alterations affected relapse incidence or outcome in this patient group. In conclusion, our data demonstrate synergy between the tumor suppressors BTG1 and IKZF1 during mouse leukemia development while the combined (single copy) loss of these two tumor suppressors identifies a patient group with an extremely poor outcome. Event free survival in a cohort of 514 children newly diagnosed with BCP-ALL, divided into four categories based on IKZF1 and BTG1 deletion status. Figure 1. Combined loss of IKZF1 and BTG1 predicts poor outcome in BCP-ALL Figure 1. Combined loss of IKZF1 and BTG1 predicts poor outcome in BCP-ALL Disclosures Pieters: Eusa Pharma: Consultancy, Honoraria, Membership on an entity's Board of Directors or advisory committees.

Description: Despite the high cure rate of pediatric acute lymphoblastic leukemia (ALL), relapse and associated therapy resistance remains a significant problem. Recent studies have identified genomic lesions that predict poor outcome (for example: loss of IKZF1 or P53). Because the effects on cell biology of most of these alterations are unknown, rational design of alternative therapy protocols is difficult. We used a CRISPR/Cas9 based knockout screen in the (cytogenetically normal) B cell progenitor-ALL cell line Nalm6 to identify novel genes involved in resistance towards asparaginase, a key component of current ALL treatment protocols. As a proof-of-principle experiment, we introduced loss-of-function mutations by transiently expressing the Cas9 nuclease in Nalm6 cells transduced with a guideRNA (gRNA) library that targets 507 of the human kinases, each with 10 unique gRNAs (Wang et al. Science 2014;343 (6166):80-4). We treated these cells in the absence or presence of an IC50 dose of asparaginase for two weeks. Subsequently, genomic DNA from treated and untreated control cells was isolated and subjected to the Illumina HiSeq platform for paired-end sequencing. We retrieved 84% of all gRNA sequences with a median of 997 reads per gRNA in the sample before treatment. Furthermore, 454 out of the 507 genes were targeted by 6 or more gRNAs. This indicates that the library complexity was sufficiently maintained during the transduction and culture procedure to study dynamics during treatment. The frequency of each gRNA before and after treatment was compared to determine the effect of loss of function of individual kinases on sensitivity towards asparaginase treatment. The MAGeCK algorithm (Li et al. Genome Biology 2014, 15:554) was used to the prioritize genes of which the gRNAs were selectively enriched or depleted during treatment. This algorithm ranks genes by comparing the performance of each gRNA that targets a specific gene. This analysis yielded 18 genes that were found to be associated with resistance (figure 1), as illustrated by the enrichment of multiple gRNAs targeting these genes. To the converse, 31 (out of 454 evaluable) genes were selectively depleted during treatment (figure 2), suggesting that loss of these genes enhances sensitivity to asparaginase treatment. These gRNAs frequently target pro-survival kinases, including components of B cell receptor signaling (BTK, MAPK, AKT3, and Yes1), suggesting that inhibiting these kinases may be used to enhance treatment response. The apoptosis inducing effects of Asparaginase treatment impinge on changes in cell metabolism as a result of amino acid starvation. In line with this, our dataset revealed enrichment of gRNAs targeting genes either directly involved in the amino acid response route (TRIB3) or other metabolic pathways (BCKDK). For an initial validation step, we used RNAi to suppress expression of one of these genes, Tribbles homologue 3 (TRIB3), a pseudokinase acting as a pro-apoptotic protein in the amino acid response pathway. Indeed, shRNA mediated knockdown of TRIB3 was sufficient to render these cells refractory to the apoptosis inducing effects of asparaginase. We conclude from these results that our CRISPR/Cas9 based screens can be used to (i) delineate pathways that contribute therapy resistance and (ii) identify protein (kinase) targets that can be selectively inhibited to improve therapy response. Disclosures No relevant conflicts of interest to declare.

Description: Relapse represents the most common cause of therapy failure in B-cell precursor ALL acute lymphoblastic leukemia (BCP-ALL), and is caused by selective outgrowth of therapy-resistant leukemic cells. Two-third of BCP-ALL relapses present after treatment, i.e. after two years. These relapses may originate from leukemic (sub)clones that remained in a quiescent state during treatment or that could not be reached by the chemotherapeutics. Relapses that occur during treatment are different in that they display clonal outgrowth in the presence of chemotherapeutics, and these patients have poorer outcomes. The aim of this study is to explore the genomic abnormalities in leukemia with early relapse, and investigate the clonal dynamics of relapses that arise during treatment. We included 17 BCP-ALL cases which relapse during treatment (