Open Access

The Philadelphia chromosome in leukemogenesis

Chinese Journal of Cancer201635:48

https://doi.org/10.1186/s40880-016-0108-0

Received: 25 October 2015

Accepted: 3 May 2016

Published: 27 May 2016

Abstract

The truncated chromosome 22 that results from the reciprocal translocation t(9;22)(q34;q11) is known as the Philadelphia chromosome (Ph) and is a hallmark of chronic myeloid leukemia (CML). In leukemia cells, Ph not only impairs the physiological signaling pathways but also disrupts genomic stability. This aberrant fusion gene encodes the breakpoint cluster region-proto-oncogene tyrosine-protein kinase (BCR-ABL1) oncogenic protein with persistently enhanced tyrosine kinase activity. The kinase activity is responsible for maintaining proliferation, inhibiting differentiation, and conferring resistance to cell death. During the progression of CML from the chronic phase to the accelerated phase and then to the blast phase, the expression patterns of different BCR-ABL1 transcripts vary. Each BCR-ABL1 transcript is present in a distinct leukemia phenotype, which predicts both response to therapy and clinical outcome. Besides CML, the Ph is found in acute lymphoblastic leukemia, acute myeloid leukemia, and mixed-phenotype acute leukemia. Here, we provide an overview of the clinical presentation and cellular biology of different phenotypes of Ph-positive leukemia and highlight key findings regarding leukemogenesis.

Keywords

Chronic myeloid leukemia BCR-ABL1 Philadelphia chromosome Translocations Signaling pathway

Background

Leukemia has among the highest mortalities of any cancer [1]. Chronic myeloid leukemia (CML) accounts for 15%–20% of all adult leukemias [2]. The Philadelphia chromosome (Ph) is the truncated chromosome 22 generated by the reciprocal translocation t(9;22)(q34;q11) and was first identified in 1960 in a patient with CML [3]. Translocation of the proto-oncogene tyrosine-protein kinase (ABL1) gene located on chromosome 9 to the breakpoint cluster region (BCR) gene located on chromosome 22 results in a BCR-ABL1 fusion gene on the Ph [4, 5]. Three BCR-ABL1 fusion gene hybrids encode BCR-ABL1 protein isoforms p210, p190, and p230, which have persistently enhanced tyrosine kinase (TK) activity. These aberrantly activated kinases disturb downstream signaling pathways, causing enhanced proliferation, differentiation arrest, and resistance to cell death [6, 7]. Tyrosine kinase inhibitors (TKIs) targeting the BCR-ABL1 protein are the most successful targeted therapy for Ph-positive leukemia. However, therapeutic resistance and disease progression are the current barriers to improve the prognosis of patients with Ph-positive leukemia [810]. Leukemia stem cells and BCR-ABL kinase domain mutations may be the keys to solve these problems [11]. The Ph is not limited to CML; it is also detected in cases of acute myeloid leukemia (AML) [12, 13], acute lymphoblastic leukemia (ALL; almost all of which are B-cell ALL, rarely T-cell ALL) [14], and mixed-phenotype acute leukemia (MPAL) [1517]. The presence of the Ph results in patients with different leukemia phenotypes having substantially different prognoses. In addition, other concurrent genomic abnormalities are more common in leukemia cells with Ph than in those without. These genomic variations, in combination with BCR-ABL1 transcripts, play an important role during leukemogenesis [1820].

However, the extent of the occurrence of the Ph and the types of BCR-ABL1 transcripts found in different leukemia phenotypes, the exact role of the translocation in leukemogenesis, and the culprit of therapeutic resistance are still not fully elucidated. Here, we review the current understanding of this topic.

The Ph, BCR-ABL1 fusion gene, and BCR-ABL hybrid protein

Molecular investigation into the Ph observed in CML revealed a consistent genomic recombination between two genes—BCR on the long arm of chromosome 22 and ABL1 on the long arm of chromosome 9—resulting in their juxtaposition, which generates the BCR-ABL1 fusion gene [21]. The location of the BCR and ABL1 genomic breakpoints is highly variable [22], but the recombination usually involves fusion of intron 1, intron 13/14, or exon 19 of BCR with a 140-kb region of ABL1 between exons 1b and 2 (Fig. 1a). Referred to as p210BCR-ABL1, the fusion of BCR exon 13 and ABL1 exon 2 (e13a2) or e14a2 constitutes the major BCR-ABL1 transcript (M-BCR, originally referred to as b2a2 and b3a2). Both transcripts result in a hybrid 210-kDa protein. p210BCR-ABL1 is most commonly detected in CML and occasionally in ALL or AML. p190BCR-ABL1 (e1a2) constitutes the minor BCR-ABL1 transcript (m-BCR), which encodes a hybrid 190-kDa protein. p190BCR-ABL is commonly detected in B-cell ALL (B-ALL) and occasionally in AML but is rarely observed in CML [7]. p230BCR-ABL1 (e19a2), also known as the μ BCR-ABL1 transcript (μ-BCR), encodes a hybrid 230-kDa protein. p230BCR-ABL1 is generated by the fusion of almost the entire BCR gene with the ABL1 gene and is considered a molecular diagnostic marker for neutrophilic-chronic myeloid leukemia (CML-N) [23].
Fig. 1

The structure of the breakpoint cluster region (BCR)-proto-oncogene tyrosine-protein kinase (ABL1) gene and protein. a The BCR-ABL1 fusion gene consists of the 5′ end of the BCR gene located at 22q11 and the 3′ end of the ABL1 gene located at 9q34. The breakpoints of the translocation usually involve the intron 13 or 14 of BCR, named major breakpoint (M-BCR), intron 1 of BCR, named minor breakpoint (m-BCR), and exon 19 of BCR, named μ breakpoint (μ-BCR). For ABL1, the breakpoint always involves the region between exons 1b and 2. b The BCR-ABL1 protein contains the Ser/Thr kinase domain and the Rho/GEF domain of BCR and the src homology (SH) domains, nuclear localization signal (NLS), and actin-binding domains from ABL1. The SH1 kinase domain is the target of imatinib. The different breakpoints that generate the p230, p210, and p190 isoforms are shown

The BCR-ABL1 protein in CML contains several domains from both BCR and ABL1. The domains from BCR include an N-terminal coiled-coil domain (CC; amino acids 1–63), a Ser/Thr kinase domain containing a docking site (phosphorylated tyrosine 177, Y177) for the adaptor protein growth factor receptor-bound protein 2 (GRB2) [24, 25], and a ras homolog gene family/Guanine nucleotide exchange factors (Rho/GEF) kinase domain (amino acids 298–413) [26], whereas the domains from ABL1 include src homology (SH) domains (SH1/SH2), a proline-rich domain, and DNA- and actin-binding domains. Although different transcripts encode different proteins, a common feature of all the hybrid proteins (p210/190/230) is the constitutively active protein kinase activity compared to wild-type ABL1 (Fig. 1b).

The N-terminal CC domain and Y177 of BCR are essential for the activation of ABL1 kinase [27, 28]. Targeting the CC domain to disrupt the tetramerization of BCR-ABL1 reduces its kinase activity and increases sensitivity to the TKI imatinib mesylate (imatinib, also known by the trade names Gleevec or Glivec) [29, 30], thus indicating that inhibition of tetramerization can contribute to overcoming imatinib resistance. In CML, Y177 plays a critical role in leukemic cell progenitor expansion, proliferation, and survival. Mutation of the GRB2-binding site at Y177 in p210BCR-ABL1 fails to induce a CML-like disease [24] and enhances sensitivity to imatinib by inhibiting RAS and protein kinase B (PKB, also named AKT) activation in CML [31]. These results show that Y177 is essential for transformation of CML by BCR-ABL1, and that it has potential as a target for overcoming imatinib resistance. The Rho/GEF protein plays a major role in activating differentiation in BCR-ABL1-induced leukemogenesis [32]. Inhibition of Rho kinase suppresses DNA synthesis in BCR-ABL1-transfected cells and also inhibits the proliferation and survival of CML progenitor cells [33, 34].

ABL1 protein, one of the non-receptor TKs, is present throughout hematopoietic development, with declining levels during myeloid maturation. The autophosphorylation site in the activation loop of its SH1 domain constitutes a switch between the inactive and active kinase conformation as it conjugates adenosine triphosphate (ATP) [35]. Imatinib and other kinase inhibitors compete with ATP to bind the autophosphorylation site, blocking the downstream signaling pathway [36]. In the “closed” conformation, the SH2 domain inhibits ABL1 activity, whereas in the “open” conformation, it promotes ABL1 activation through binding to the C-terminal of the SH1 domain [37]. Importantly, docking of the SH2 domain to the C-lobe of the kinase is controlled by the myristate moiety at the N-terminal of the SH3 domain. N-terminal myristoyl modification of the SH3 domain of ABL1 binds to the SH1 domain (the kinase domain) and induces conformational changes that allow the SH2 and SH3 domains to dock onto it [38, 39]. Mutant SH3 domain of ABL1 (exon 1b) with a blocked myristate-binding site shows strongly deregulated TK activity [38]. Also, blocking the myristate-binding site completely abolished leukemogenesis in mice and increased the sensitivity of imatinib-resistant BCR-ABL1-bearing mutants to TKI inhibition [40, 41]. These findings suggest that the myristate-binding site of the SH3 domain of ABL1 is a potential novel allosteric target for pharmacologic intervention.

Ph in different phenotypes of leukemia

Cml

The BCR-ABL1 fusion gene is a hallmark of CML. Three discrete clinical stages are defined for CML: the chronic phase (CML-CP), the accelerated phase (CML-AP), and the blast crisis (CML-BC). Without therapeutic intervention, the disease follows a natural progression from relatively benign CML-CP, through CML-AP, to terminal CML-BC. The phenotype of CML-BC can be myeloid or lymphoid or, in rare cases, both. Myeloid BC is more commonly observed than lymphoid BC. In lymphoid BC, the predominant lineage is B-cell, representing about 30% of cases [42].

Most CML patients have M-BCR transcripts with b14a2 (55%) or b13a2 (40%) junctions (p210BCR-ABL1). In 5% of CML cases, both b13a2 and b14a2 transcripts are detected [43, 44]. However, the e1a2 (p190BCR-ABL1) transcript is frequently present at a low level in patients with p210BCR-ABL1-positive leukemia [45]. Approximately 52% of Ph-positive CML cases co-express p210BCR-ABL1 and p190BCR-ABL1 transcripts, with the other 48% exclusively expressing p210BCR-ABL1 [44]. All CML-BC patients co-express both transcripts [44]. Further details were provided in a study of 250 Mexican Ph-positive CML patients, which found that 90.4% of patients expressed p210BCR-ABL1, and approximately 7% of patients with p210BCR-ABL1 expressed both isoforms (b3a2/b2a2); however, co-expression of p190/p210BCR-ABL1 was seen in only 5% of patients [46]. Nevertheless, the prognosis for CML patients who co-express two or all p190/210/230BCR-ABL1 transcripts is poor [46]. Consistently, CML patients who co-express p210/p190BCR-ABL1 have considerably higher white blood cell (WBC) and blast cell counts at any time of testing, including diagnosis, than patients who express only p210BCR-ABL1 [44].

The position of the BCR breakpoint is also associated with prognosis. M-BCR rearrangement is predictive of response to therapy [47], whereas the presence of a double Ph indicates a poor prognosis [42]. However, no significant survival difference was found between patients with b13a2 and those with b14a2 mRNA junctions [48].

Acute lymphoblastic leukemia

BCR-ABL1 is not restricted to CML. It is also present in 11%–29% of ALL patients [49] but is relatively rare in childhood ALL (1%–3%) [50]. BCR-ABL1 presence in ALL patients increases with age [51] and has been reported to be as high as 50% in patients 60 years of age or older [52]. With few exceptions, Ph-positive ALL patients are diagnosed with B-ALL [5355], and most cases of Ph-positive ALL express the p190BCR-ABL1 transcript. The p210BCR-ABL1 transcript is detected in 30% of adult and 20% of childhood patients with Ph-positive ALL [43, 45, 5658]. The BCR-ABL1 variant e3a2 (exon 3 of BCR and exon 2 of ABL1) can also be detected in cases of Ph-positive ALL, which is similar to ALL with p190BCR-ABL1 transcript [59].

Prognosis of both adults and children with Ph-positive ALL treated with standard chemotherapy is very poor, with less than 5% of adults being cured [55, 60]. Fortunately, the combination of chemotherapy with the TKI imatinib has remarkable efficacy on newly diagnosed Ph-positive ALL, achieving a complete remission rate of 95% and a patient survival rate of 55% at 3 years [61].

Acute myeloid leukemia

BCR-ABL1 transcripts are rarely found in AML. Less than 1.5% of AML patients harbor the BCR-ABL1 fusion gene [6264]. Ph-positive AML is cytogenetically indistinguishable from Ph-positive CML, but molecular studies show that, in 50% of cases, the breakpoint on chromosome 22 in Ph-positive AML is different from those very consistently found in CML [65]. Furthermore, studies have confirmed that BCR-ABL1-positive AML is a unique acute leukemia with some features distinct from myeloid CML-BC. These features include less marked splenomegaly, fewer peripheral basophiles, and a lower myeloid/erythroid ratio, and bone marrow cellularity [64] compared with myeloid CML-BC. In addition, the loss within the immunoglobulin genes (deletion of 14q32) in some cases of de novo Ph-positive AML can distinguish it from myeloid CML-BC [66]. However, the median survivals of Ph-positive AML and myeloid CML-BC patients are similar (9 vs. 7 months, P = 0.54) [64].

Mixed-phenotype acute leukemia

The Ph is one of the most frequent aberrant cytogenetic findings in MPAL. The World Health Organization (WHO) defines MPAL as acute leukemia with a mixed phenotype containing two morphologically and immunophenotypically distinct populations of blasts or showing a single blast cell population expressing mixed phenotypic markers [67]. Many of these cases have a dimorphic population of blasts, with the majority being of B-lymphoid/myeloid lineage (59%–60%), followed by T-lymphoid/myeloid (32%–35%), T-/B-lymphoid (4%), and trilineage (2%–4%) [16, 68]. Ph-positive MPAL is defined as acute leukemia meeting the criteria for MPAL in which the blasts also have a detectable Ph or BCR-ABL1 fusion transcript. The frequency of Ph-positive MPAL is 17%–35% in adult MPAL patients, whereas studies of pediatric patients report a much lower rate of 3% [69, 70]. No obvious difference was found between the BCR-ABL1 transcript types expressed in adult cases [71, 72], but 30% of cases have additional chromosomal aberrations [72]. Importantly, compared with other phenotypes of leukemia, Ph-positive MPAL has a much worse outcome [16, 68]. Studies of Ph-positive MPAL are rare, and there is no consensus on the most appropriate therapy for this subtype. Although TKIs have improved the prognosis of Ph-positive MPAL, adult patients are still considered for hematopoietic stem cell (HSC) transplantation during the first remission.

What role does Ph play in leukemogenesis?

The BCR-ABL1 fusion protein was first indicated as the crucial driver of CML in mouse studies, which showed that expression of p210BCR-ABL1 in the bone marrow caused a CML-like disease. The progression of p210BCR-ABL1-associated disease in transgenic mice is consistent with the apparent indolence of human CML-CP [73, 74]. Expression of p190BCR-ABL1 at a level similar to that in the p210BCR-ABL1-transgenic model results in a clinically distinct condition. Voncken et al. [75] demonstrated the development of de novo B-cell leukemia in mice exclusively transgenic for p190BCR-ABL1, with a relatively short period of latency. Furthermore, Castellanos et al. [76] created an in-frame fusion of p190BCR-ABL1 that mimics the human chromosomal translocation by homologous recombination in embryonic stem cells. The chimeric mice generated with the mutant embryonic stem cells systematically developed B-ALL, which was detected with elevated TK activity [77]. The TKI imatinib, the first agent targeting the TK activity of BCR-ABL1 protein, has become the first-line therapy for all patients with Ph-positive CML; it is also an indispensable therapy for Ph-positive ALL. Imatinib has changed the prognosis of CML radically over the last 15 years and improved the overall survival of ALL patients.

In addition to its TK activity, the SH2 domain of BCR-ABL1 is also required for induction of CML-like disease in mice, but, interestingly, SH2 is not required for lymphoid leukemogenesis [78]. BCR-ABL1 with deleted SH2 or the R1057K mutant on SH2 of p210BCR-ABL1 retains the ability to induce a fatal myeloproliferative disorder (MPD) with an extended latency [79]. Consistently, in cells transfected with SH2-mutated BCR-ABL1 or BCR-ABL1, the B-lymphoid expansion was diminished, suggesting that the BCR-ABL1-induced MPD suppresses B-lymphoid expansion [79].

Pathways associated with BCR-ABL1

The transforming activity of BCR-ABL1 is due to its constitutive TK activity, which contributes to the maintenance of cell proliferation, inhibits differentiation, and promotes resistance to cell death. BCR-ABL1 kinase hyperactivity results in the activation of signaling pathways and deregulation of cellular processes [80]. Most of these pathways have been demonstrated in CML and ALL mouse models. The main pathways associated with BCR-ABL1 activity are presented in Fig. 2.
Fig. 2

Main pathways regulated by the BCR-ABL1 protein. The downstream pathways regulated by BCR-ABL1 protein associated with cell survival, cell proliferation, cell cycle, cell differentiation, apoptosis, and the microenvironment of leukemia stem cells. Dark violet shapes indicate the kinase; lavender pink shapes indicate the proven oncoprotein; blue shapes indicate the proven tumor suppressor protein; and other color shapes indicate the proteins existing in normal cells. Red solid lines indicate inhibiting; green solid lines indicate activating. Blue dotted lines indicate that the results need further confirmation. Black dotted lines indicate the functions associated with the signaling pathway. JAK2 janus kinase 2, STAT5 signal transducers and activators of transcription 5, BCR-XL B-cell lymphoma-extra-large, CRKL Crk-like protein, PI3 K phosphatidylinositol 3-kinase, AKT protein kinase B, MDM2 mouse double minute 2 homolog, TP53 tumor protein p53, p21WAF-1/CIP-1 cytosolic cyclin-dependent kinase inhibitor p21, SKP2I S-phase kinase-associated protein 2 inhibitor, NF-κB nuclear factor kappa-light-chain-enhancer of activated B cells, IKKβ IKβ kinase, C/EBPα CCAAT/enhancer-binding protein α, GATA2 GATA binding protein 2, GRB2 the adaptor protein growth factor receptor-bound protein 2, SOS son of sevenless, MEK mitogen-activated protein kinase kinase, ERK extracellular signal-regulated kinases, hnRNP-E2 poly(rC)-binding protein E2, FOXO3a forkhead box O3, TRAIL TNF-related apoptosis-inducing ligand

The JAK2/STAT pathway

Activation of Janus kinase (JAK)1–3 [81] and signal transducers and activators of transcription (STAT)1, 3, 5, and 6 [81, 82] has been confirmed experimentally in p190/p210BCR-ABL1-positive leukemia. JAK1–3 activation is mediated by the interaction of BCR-ABL1 with cytokine receptors [83]. BCR-ABL1 kinase directly enhances JAK2/STAT activation to promote cell growth/survival in CML models [84, 85], and it requires an intact JAK2/STAT5 pathway to enable oncogenic transformation [83]. JAK3 expression is limited to hematopoietic cells, and JAK3-knockout mice have developmental defects in lymphoid cells and expansion of the myeloid lineages [8689]. JAK2 directly phosphorylates BCR-ABL1 at Y177 and increases BCR-ABL1 protein stability, thus enhancing BCR-ABL1 signaling [24, 90]. Moreover, JAK2 induces mRNA expression of the oncogene c-MYC and protects c-MYC protein from degradation [91]. c-MYC overexpression plays a critical role in BCR-ABL1 transformation [92] and is a downstream target of activated JAK2 in BCR-ABL1-positive cells. Survivin is overexpressed in BCR-ABL1-positive cells [93], and BCR-ABL1 activates c-MYC to induce transactivation of the survivin promoter via JAK2/phosphatidylinositol 3-kinase (PI3K) signaling pathways [94]. These findings indicate that JAK2 controls BCR-ABL1 stability and oncogenic signaling in BCR-ABL1-positive cells [95]. Both JAK2 inhibition and knockdown reduce levels of phosphorylated STAT5 (p-STAT5) and inhibit the RAS-PI3K pathway. By contrast, JAK2 inhibition decreases phosphorylated Y177 (p-Y177) but does not reduce levels of BCR-ABL1, suggesting that the reduction of BCR-ABL1 by JAK2 inhibition is a separate event from phosphorylation of Y177 [90]. A recent study showed that absence of JAK2 in a CML-CP model drastically accelerated disease development with increased numbers of WBC counts and severe splenomegaly, suggesting that JAK2 inhibits the progress of CML [96].

The level of p-STAT3 is higher in CML patients who are resistant to imatinib treatment than in patients who respond [97]. BCR-ABL1 regulates transcription of STAT3 by phosphorylating JAK1/2 and mitogen-activated protein kinase kinase (MEK) [98]. Both STAT3 and STAT5a/b are essential for the induction of CML-like leukemia by BCR-ABL1 and for the maintenance of the survival and growth of CML cells [95]. STAT5- or STAT3-knockout mice with BCR-ABL1 fail to display a CML phenotype and prevent established B-ALL. Additionally, STAT5, not STAT3, is essential for cell cycle progression and survival of lymphoid leukemic cells [95]. The N-terminal of STAT5a/b plays a key role in B-lymphoid transformation [99]. Furthermore, STAT5 is not essential for normal hematopoiesis [95, 100], which makes it a good therapeutic target in Ph-positive leukemia [84, 85].

The PI3K-AKT-mTOR pathway

The PI3K-AKT-mammalian target of rapamycin (mTOR) pathway is another important downstream cascade in Ph-positive leukemia, including CML and ALL. It is able to activate c-kit-positive HSCs from the quiescent to the proliferative state in BCR-ABL1-positive CML [101]. Through a PI3K-AKT-mTOR-independent pathway, BCR-ABL1 evades cell cycle arrest by increasing cytosolic cyclin-dependent kinase inhibitor p21 (p21WAF-1/CIP-1), which has been reported to have a pro-survival role localizing in cytoplasm [102]. BCR-ABL1 also induces S-phase kinase-associated protein 2 (Skp2) expression to promote proliferation of CML cells by the PI3K-AKT-mTOR pathway [103]. Meanwhile, BCR-ABL1 increases glucose metabolism and activates mitochondrial electron transport chains specifically regulated by PI3K-AKT-mTOR in CML cells [104, 105]. Ablation of PI3 K prevents BCR-ABL1 leukemogenesis in mice, and a dual PI3 K/mTOR inhibitor PI-103 suppresses proliferation of mouse pre-B-ALL more effectively than rapamycin [106]. The dual PI3 K and mTOR small-molecule inhibitors are also effective against TKI-resistant BCR-ABL1 mutant cells in vivo and in vitro [107]. In addition, inhibition of PI3K shows synergy with TKI-enhancing cytotoxic effects in p210BCR-ABL1-transformed cells, especially apoptosis [107, 108]. Taken together, these findings suggest that the PI3K-AKT-mTOR pathway plays an important role in BCR-ABL1-mediated leukemogenesis.

Currently, several PI3K inhibitors are being investigated, and several clinical trials have been completed in pediatric ALL [109]. Interestingly, a recent study showed that PI3K inhibitors induced global transcriptional reprogramming in tumors, with (re)phosphorylation of AKT and mTOR, and increased tumor cell motility and invasion [110]. That might explain why PI3K inhibitors were not more clinically efficacious in the last 10 years. Therefore, combining PI3K inhibitors with other therapeutic approaches may be a promising future therapeutic strategy.

The MAPK/ERK (RAS/RAF/MEK/ERK) pathway

The RAS/RAF/MEK/extracellular signal-regulated kinases (ERK) pathway is a central signal transduction pathway, which transmits signals from cell surface receptors to nuclear transcription factors. In BCR-ABL1-positive leukemia cells, activation of the RAS/RAF/MEK/ERK pathway results in uncontrolled proliferation [111113]. BCR-ABL1 transduces proliferative signals partly through activation of RAS via GRB2/GRB2-associated binding protein 2 (GAB2) phosphorylation dependent on phosphorylation of Y177 of BCR [31, 114]. Disruption of RAS signaling attenuates development of BCR-ABL1-induced CML-like disease in mice, but most BCR-ABL1-positive mice with mutant RAS eventually develop pro-B-ALL. This indicates that RAS is a critical target of BCR-ABL1 in the pathogenesis of CML but not B-ALL [115].

Blockage of MEK/ERK elevates cytotoxicity of histone deacetylase inhibitors in BCR-ABL1-expressing cells resistant to the TKIs gefitinib or imatinib and leads to erythroid differentiation [116, 117]. BCR-ABL1 also activates B-RAF kinase, which is an effector molecule of the RAS-related protein RAP1 and a potent activator of the MEK/ERK/ELK-1 signaling pathway. Inhibition of RAP1 activation inhibits the BCR-ABL1-induced activation of ERK-1 [113].

Leukemic microenvironment plays a role in promoting and maintaining leukemic cell proliferation and survivability [118]. In addition to BCR-ABL1 kinase activity, CML stem cell survival depends on the continuous support of the hematopoietic niche [84]. Osteopontin (OPN), a component of the stem cell niche, is overexpressed in BCR-ABL1-expressing cells. BCR-ABL1 induces OPN overexpression by activating a signaling cascade involving RAS, RAF-1, and MAPK, indicating that BCR-ABL1 maintains the microenvironment for leukemia stem cells possibly through the RAS/RAF/MEK/ERK pathway [119].

Interestingly, oncogene addiction analysis shows that due to MEK-dependent negative feedback, JAK2 plays little or no role in signal transduction when BCR-ABL1 is active. After prolonged BCR-ABL1 inhibition (more than 8 h), negative feedback is relieved and JAK2 becomes critically important as a mediator of STAT5 phosphorylation in the downstream pathways [120]. Maintaining negative feedback with oncoprotein inhibition may, therefore, best facilitate the effects of target agents.

TRAIL-induced apoptosis

Tumor necrosis factor (TNF)-related apoptosis-inducing ligand-TNFSF10 (TRAIL), a death receptor ligand, is down-regulated in BCR-ABL1-positive leukemia [121123]. In BCR-ABL1-positive cell lines and primary ALL cells, TRAIL induces death-inducing receptor (DR4 and DR5)-dependent apoptotic cell death [124]. Treatment with imatinib enhances TRAIL-induced apoptosis [125, 126]. Inducing TRAIL-mediated cell death also inhibits cancer cell proliferation and suppresses growth of CML xenografts [127].

These results suggest the potential use of recombinant TRAIL as a novel therapeutic agent; they also suggest the possible contribution of endogenously expressed TRAIL in immunotherapy against BCR-ABL1-positive leukemia.

C/EBPα-mediated differentiation

CCAAT/enhancer-binding proteins (C/EBPs) are transcription factors that regulate normal myelopoiesis as well as myeloid disorders. BCR-ABL1 suppresses C/EBPα mRNA levels via the induction of the mitogen-activated protein kinases-poly(rC)-binding protein E2 (MAPK-hnRNP-E2) pathway [128130]. Disruption of C/EBPα blocks the transition from common myeloid to granulocyte-monocyte progenitor cells [131]. The failure of myeloid precursors to differentiate into mature granulocytes is a unique characteristic of clinical progression from CML-CP to CML-BC. C/EBPα expression is reduced in BCR-ABL1-expressing cell lines and CML-BC cells. Loss of miR-328 in CML-BC also reduces expression of C/EPBα [132]. Meanwhile, phosphorylation at serine 21 of the C/EBPα protein is associated with differentiation effects in K562 cells [133]. Furthermore, C/EBPα deregulation and neutrophilic differentiation by BCR-ABL1 are reversed by imatinib [134]. The gene profile shows that activation of C/EBPα induces the expression of cell cycle- and apoptosis-related genes and enhances imatinib-induced apoptosis of K562 cells [135]. Restoration of C/EBPα expression induces terminal granulocytic differentiation and inhibits proliferation of leukemia cells in vitro and in vivo [136138]. Moreover, the effects of C/EBPα in p210BCR-ABL1-expressing cells depend partly on transcriptional repression of c-MYC and GATA-2 [139]. However, absence of C/EBPα results in loss of myeloid identity in transgenic mice with BCR-ABL1-induced CML-like disease and, interestingly, causes erythroleukemia instead, suggesting that CEBPα is essential for BCR-ABL1-positive CML [140].

Ectopic expression of C/EBPα in primary human BCR-ABL1-positive B-ALL cells induces macrophage-like cells, which are unable to establish disease in xenograft hosts [141]. Epigenetic studies show that aberrant methylation in the CpG island of the promoter region of C/EBPα is a common event in CML, suggesting that regulating methylation of C/EBPα could be a new therapeutic direction for treating Ph-positive leukemia [142].

Autophagy

Autophagy can be manipulated for a better therapy on AML by inducing cooperation with apoptosis and differentiation [143]. Also, autophagy presents a potential target in BCR-ABL1-positive leukemia, particularly in TKI-resistant types [144146]. Disruption of autophagy is a new strategy to treat imatinib-resistant CML patients. Pharmacologic or genetic inhibition of the Hedgehog pathway can markedly induce autophagy in BCR-ABL1-positive CML cells. Inhibition of both Hedgehog pathway and autophagy may be a potent new strategy to overcome drug resistance in CML [147]. Importantly, BCR-ABL1 suppresses apoptosis as well as autophagy, resulting in low basal levels of autophagy in BCR-ABL1-transformed cells. Treatment of BCR-ABL1-positive cells in vitro with chemical inhibitors of autophagy or by deletion of the autophagy-related 3 (Atg3) gene induces cell death. In a cell transfer model in vivo, Atg3 deletion also prevented BCR-ABL1-mediated leukemogenesis [148]. Moreover, the therapeutic drug arsenic trioxide (As2O3) targeted BCR-ABL1 for autophagy degradation via a p62/the gene encoding p62 (SQSTM1)-dependent mechanism, which is mediated localization of the oncoprotein to the autolysosomes [149].

In conclusion, BCR-ABL1-positive cells particularly depend on autophagy for leukemogenesis, and regulation of autophagy may be a therapeutic approach for BCR-ABL1-positive leukemia.

Genomic instability

Genomic instability is an essential factor of tumorigenesis for both leukemias and solid tumors. Chromosomal translocations generate the aberrant fusion TKs, such as BCR-ABL1, Ets variant gene 6-ABL1 [TEL(ETV6)/ABL1], TEL(ETV6)/JAK2, and TEL-platelet-derived growth factor beta receptor [TEL(ETV6)/PDGFβR], which induce hematologic malignancies [150]. BCR-ABL1-positive cells contain elevated numbers of DNA double-strand breaks (DSBs) and show stimulation of the single-strand annealing (SSA) repair process [151153]. The WRN gene (mutated in Werner syndrome) encodes a helicase required for processing DSB ends during the repair. BCR-ABL1 enhances the expression and increases the nuclear localization of WRN to promote survival and genomic instability [154].

Prolonged expression of the p210BCR-ABL1 transcript was associated with development of aneuploidy and complex chromosomal translocations in the mouse model [155]. Transgenic mice expressing p190BCR-ABL1 developed karyotypic abnormalities, most commonly trisomies involving chromosomes 12, 14, or 17, alone or in combination [18].

A recent study using a whole transcriptome array showed that genes such as dipeptidyl peptidase-4 (DPP4), interleukin-2 receptor alpha (IL2RA), protein tyrosine phosphatase, receptor type D (PTPRD), calcium channel, voltage-dependent, L type, alpha 1D subunit (CACNA1D), interleukin 1 receptor accessory protein (IL1RAP), solute carrier family 4 (SLC4A4), and potassium channel, subfamily K, member 5 (KCNK5) were up-regulated in BCR-ABL1-positive CML. This study found that these genes play key roles in proliferation, differentiation, and molecular pathways in HSCs [156]. Accumulation of additional cytogenetic and molecular abnormalities also contributes to blast transformation and progression [157159]. BCR-ABL1 and genomic instability are currently considered to be a complex partnership in leukemogenesis, suggesting that BCR-ABL1 itself leads to genomic instability independent of its leukemogenic effect [20].

The Ph rarely appears with other genetic abnormalities in CML-CP. However, in Ph-positive B-ALL, AML, MPAL, and CML-AP and CML-BP, deletions involving immunoglobulin heavy chain (IGH), T-cell receptor (TCR), encoding the transcription factor IKAROS family zinc finger protein 1 (IKZF1), and cyclin-dependent kinase inhibitor 2 (CDKN2A/B) are common [66]. A recent study showed that the BCR-ABL1 fusion gene could be a prenatal and possibly initiating genetic event in Ph-positive childhood ALL and that variation in other genes is a secondary and probably postnatal event in these cases [160]. Common gene abnormalities found in Ph-positive leukemia are discussed in Table 1.
Table 1

Recurrent genomic abnormalities in Philadelphia chromosome (Ph)-positive leukemia

Genomic abnormality

Location

Status

Ph-positive leukemia

Frequency

Reference(s)

IKZF1

7q12.2

Deletion

ALL

50%–83%

[162, 164]

Deletion

Lymphoid CML-BC

73%–75%

[163, 180]

PAX5

9p13

Deletion

ALL

33%–51%

[171, 172, 180]

Deletion

Lymphoid CML-BC

58.3%

[180]

EBF1

5q34

Deletion

ALL

14%

[198]

CDKN2A/B

9p13-p23.1

Deletion

AML

50%

[66]

Deletion

MPAL

33.3%

[66]

Deletion

ALL

53.5%

[163, 164]

Deletion

Lymphoid CML-BC

58.3%–69%

[180]

IG

14q32.33

IGHV/IGHG2 M deletion

Lymphoid CML-BC

66%–100%

[66, 163, 180]

22q11.2

IGLL1 deletion

AML

66.7%

[66]

TCR

14q11.2/7p14.1

TCRA/B/D deletion

AML/MPAL

66.7%

[66]

14q11.2

TCRA deletion

Lymphoid CML-BC

74%

[66, 180]

BTG1

12q21.33

Deletion

BCP-ALL

11%–31.3%

[176]

 

Deletion

MPAL

33.3%

[176]

 

Deletion

CML-BC (B-lineage)

33.3%

[176]

IKZF1 transcription factor IKAROS family zinc finger protein 1, PAX5 paired box 5, EBF1 early B-cell factor 1, CDKN2A/B cyclin-dependent kinase inhibitor 2, IG immunoglobulin, TCR T-cell receptor, BTG1 B-cell translocation gene 1, IGHV immunoglobulin heavy chain variable region, IGHG2M immunoglobulin heavy constant gamma 2, IGLL1 immunoglobulin lambda-like polypeptide 1, TCRA T-cell receptor alpha locus, ALL acute lymphoblastic leukemia, CML-BC chronic myeloid leukemia blast crisis, AML acute myeloid leukemia, MPAL mixed-phenotype acute leukemia, BCP-ALL B-cell precursor ALL

IKZF1 mutation

IKZF1, located on chromosome 7p12, is a regulator of lymphocyte differentiation. Wild-type IKAROS prevents stemness properties and has tumor suppressor activity in BCR-ABL1-initiated leukemia [161]. BCR-ABL1 and IKZF1 mutations are strongly linked: somatic mutations in IKZF1 are present in 70%–83% of Ph-positive ALL cases; approximately 90% are deletions, and 10% are point mutations [162]. Deletion of IKZF1 has also been identified as an acquired lesion at transformation from CML-CP to lymphoid CML-BC but never in myeloid CML-BC or AML with Ph [163]. In addition, loss of IKZF1 predicts a poor prognosis in patients with Ph-positive leukemia [164]. Disruption of IKAROS activity in primitive CML-CP cells can mimic myeloid disease progression (CML-AP), revealing that loss of IKAROS is a frequent step and potential predictor of BCR-ABL1-positive CML-AP/BC [162]. The IKAROS-6 (IK6) is produced by an in-frame deletion of exons 4–7 of IKZF1, which deletes the DNA-binding domain and leads to cytosolic accumulation of the mutant protein. The mutations associated with a more profound reduction in IKAROS function (bi-allelic deletion and IK6) are particularly common in Ph-positive ALL [165].

In addition, loss of IKZF1 is recurrent in pediatric AML and may be a determinant of oncogenesis in AML with monosomy 7 [166]. Sequencing of IKZF1 deletion breakpoints suggests that aberrant recombination activating gene (RAG)-mediated V(D)J recombination is responsible for the deletions [167].

PAX5 and EBF1 mutation

The paired box 5 (PAX5) and early B-cell factor 1 (EBF1) are transcription factors that are expressed specifically during B-cell development and control lineage identity and commitment [168170]. Recurrent deletions of PAX5 and EBF1 occur in approximately 50% and 14% of Ph-positive ALL cases, respectively [163, 168, 171]. In contrast to BCR-ABL1-negative ALL, no point mutations of PAX5 have been found, suggesting that deletions are the main mechanism of inactivation of PAX5 in BCR-ABL1-positive ALL [172]. EBF1 co-regulates target genes with PAX5. In mouse models, loss of PAX5 or EBF1 leads to a differentiation block at the pro- to pre-B-cell stage, resulting in B-cell precursor leukemia (BCP-ALL) [170, 173]. Complete loss of PAX5 and EBF1 is apparently a secondary event and is significantly associated with BCR-ABL1 [171].

BTG1 deletion

The B-cell translocation gene 1 (BTG1) on chromosome 12q21.33 is highly conserved and belongs to an antiproliferative gene family that regulates cell growth, differentiation, and angiogenesis [174, 175]. BTG1 deletion occurs in 11%–31.3% of BCP-ALL cases, in 33.3% of MPAL cases, and in 33.3% of CML-BC (B-lineage) cases [176]. Eight distinct deletions of different sizes within the second exon of BTG1 have been identified in BCP-ALL, resulting in the expression of truncated BTG1 transcripts [177]. Loss of BTG1 expression also causes glucocorticoid (GC) resistance both by reducing glucocorticoid receptor (GR) expression and by controlling GR-mediated transcription in ALL [178]. It suggests that BTG1 deletions may act as “drivers” of leukemogenesis in BCP-ALL, MPAL, and lymphoid CML-BC (B-lineage) with Ph. BTG1 overexpression inhibits proliferation and invasion and induces G2/M arrest, differentiation, senescence, and apoptosis in xenograft models of gastric cancer. Restoring BTG1 might reverse phenotypes and be a potential target for gene therapy of Ph-positive leukemia [179].

IGH and TCR deletion

The deletions of 4 chromosomal regions, 7p12–14, 9p21–24, 14q11.2, and 14q32.33, are found recurrently in Ph-positive leukemia. The deletions of immunoglobulin heavy chain (IgH) genes and TCRα/β/γ genes are restricted to the four chromosomal regions. Most common deletions include immunoglobulin heavy chain variable region (IGHV), immunoglobulin heavy constant gamma 2 (IGHG2 M), and T-cell receptor alpha locus (TCRA). Deletion within both IGH and TCR genes is a characteristic of lymphoid CML-BC with Ph; none of these genome losses is detected in CML-CP or myeloid CML-BC samples [180]. Deletions within chromosomes 7 and 9, including IKZF1 and CDKN2a/b genes, are also frequently accompanied by IGH and TCR gene deletion in Ph-positive BP-ALL [66], indicating that deletion of the IGH and/or TCR gene region is obligatory for the development of a malignant clone with a lymphoid phenotype. Interestingly, Ph-positive AML also possesses deletions of immunoglobulin (IG) and TCR genes but involving immunoglobulin lambda-like polypeptide 1 (IGLL1, 22q11.2) and TCRA/B/D (14q11.2 and 7p14.1), respectively. The above studies suggested that different parts of the deletion with IG and TCR genes might result in different phenotypes of leukemia [19, 66, 163].

Therapeutic resistance and disease progression in Ph-positive leukemia patients

Compared with CML-CP patients, imatinib responses are much less durable in patients with CML-AP/BC or ALL [810]. Compelling research suggests that a population of cancer stem cells (CSCs) is responsible for therapeutic resistance and disease progression. BCR-ABL1-positive stem cells persist in CML patients despite prolonged treatment with imatinib [181, 182]. Primitive, quiescent, Ph-positive stem cells (CD34+CD38) from patients with CML are insensitive to imatinib in vitro [183]. Consistently, the BCR-ABL1 expression in persistent leukemic stem cells could explain innate resistance to imatinib and to other TKIs [184].

In CML patients with TKI resistance, relapse or evolving to blast crisis, BCR-ABL1 kinase mutations (M237I, L248V, Q252E, Y253H, D276G, G321E, V304A, M351T, T315 I, E352G, Y353G, E373G, and T389A) can be detected in stem cells [185, 186]. Mutations were found in 27% of CML-CP patients, 52% of CML-AP patients, 75% of myeloid blast crisis patients, and 83% of lymphoid blast crisis/Ph-positive ALL patients [187]. Thirty percent of patients with primary resistance and 57% of patients with acquired resistance were associated with these mutations [187]. Studies have confirmed that the mutations were the potential source of resistance and relapse [185]. The following mutations are involved in theraputic resistence and disease progression [188]: (1) contact residues (such as T315) by impeding inhibitor access or eliminating critical hydrogen bonds; (2) the ATP-binding loop (such as L248V) by preventing Abl from adopting the specific conformation required for high-affinity imatinib binding; and (3) regulatory motifs (such as the activation loop) by stabilizing an active conformation that is inaccessible to imatinib.

Recent studies showed that inhibition of heat shock protein 90 (Hsp90) decreased the number of leukemia stem cells, caused BCR-ABL protein degradation by the ubiquitin-proteasome pathway, and prolonged survival of mice with CML induced by BCR-ABL-T315I [189, 190]. Many novel Hsp90 inhibitors have entered into clinical trials, the results of which are encouraging [190]. This anti-Hsp90 strategy in treating CML patients, especially with TKI resistance, has a good application prospect. Another study showed that some alkyne-containing pyrazolopyrimidines can inhibit not only Abl(T315I) in vitro but also Bcr-Abl(T315I) in cells, suggesting that these pyrazolopyrimidines can serve as lead compounds for targeted therapy to overcome drug resistance of CML [191]. Also, one third-generation TKI, ponatinib, has been proven against the drug resistance including the T315I mutation. X-ray crystallographic analysis revealed that ponatinib inactivated T315I Bcr-Abl mutated kinase by conformational alteration [192].

In brief, a quiescent population of leukemia stem cells with or without BCR-ABL1 kinase domain mutations is responsible for drug resistance [11].

Conclusion leukemogenesis is an outcome of the Ph combined with other genetic variations

Expression of BCR-ABL1 (p210 transcript) has been detected at very low levels in the peripheral blood cells of some healthy individuals but not in umbilical cord blood cells [193]. In addition, BCR-ABL1-specific T cells are detected in healthy donors and in CML patients after allogeneic stem cell transplantation [194]. These results indicate that normal cells evolve progressively to a neoplastic state, and they may acquire a succession of genetic abnormalities and gain the ability to maintain proliferation, inhibit differentiation, and resist cell death [195].

The Ph bearing the BCR-ABL1 fusion gene is the key initiator of different phenotypes of leukemia with diverse prognoses. The translocation leads to persistent TK activation and genomic instability during leukemogenesis. Disorders in multiple signaling pathways and genetic abnormalities combined with the Ph are essential for the evolution of different types of leukemia; however, why cells possessing the Ph should evolve specifically into CML, AML, ALL, or MPAL is currently unclear and under investigation. Evidence shows that there are characteristics exclusive to specific leukemias, including deletion of BTG1 in B-cell leukemia, loss of IKZF1 with monosomy 7 in AML, and deletions involving IGH, TCR, IKZF1, and CDKN2A/B in CML-AP/CP. Greater understanding of leukemogenesis and the effect of treatment on clonal evolution will provide novel insights into the design of future therapeutic strategies for Ph-positive leukemia [196, 197].

Abbreviations

Ph: 

Philadelphia chromosome

CML: 

chronic myeloid leukemia

ALL: 

acute lymphoblastic leukemia

AML: 

acute myeloid leukemia

MPAL: 

mixed-phenotype acute leukemia

TK: 

tyrosine kinase

TKIs: 

tyrosine kinase inhibitors

CML-N: 

neutrophilic-chronic myeloid leukemia

Y177: 

phosphorylated tyrosine 177

CML-CP: 

chronic phase of CML

CML-AP: 

accelerated phase of CML

CML-BC: 

blast crisis of CML

myeloid CML-BC: 

myeloid-BC of CML

HSC: 

hematopoietic stem cell

MPD: 

myeloproliferative disorder

OPN: 

osteopontin

TRAIL: 

tumor necrosis factor-related apoptosis-inducing ligand-TNFSF10

C/EBPs: 

CCAAT/enhancer-binding proteins

SSA: 

single-strand annealing

IKZF1: 

encoding the transcription factor IKAROS

BTG1: 

B cell translocation gene 1

IGH: 

immunoglobulin heavy chain

EBF1: 

early B-cell factor 1

PAX5: 

paired box 5

CDKN2A/B: 

cyclin-dependent kinase inhibitor 2

TCR: 

T-cell receptor

IGHV: 

immunoglobulin heavy chain variable region

IGHG2M: 

immunoglobulin heavy constant gamma 2

TCRA: 

T-cell receptor alpha locus

IGLL1: 

immunoglobulin lambda-like polypeptide 1

Declarations

Authors’ contributions

QL, JSY, and ZJK conceived of the study. ZJK, LZX, ZJL, and DH participated in its design and coordination. ZJK drafted the manuscript. YY, YFL, BL, and JXF reviewed and edited the manuscript. ZJK and YJP performed the diagrammatic drawing. All authors read and approved the final manuscript.

Acknowledgements

We thank Professor Han Liu for revising the manuscript. This study was supported by the China Central Budget Recruitment Program of High-Level Overseas Talent (GDW 201221022066 to Q. Liu), the National Basic Research Program of China (973 Program: No. 2012CB967000 to Q. Liu), the National Natural Science Foundation of China (NNSF No. 81130040 to Q. Liu and No. 81201686 to J. Xu), the Program for Changjiang Scholars and Innovative Research Team in Universities (ITR 13049 to Q. Liu), and the Liaoning (NSF 2014029102 to Q. Liu).

Competing interests

The authors declare that they have no competing interests.

Open AccessThis article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

Authors’ Affiliations

(1)
Department of Hematology, The Second Affiliated Hospital, Institute of Cancer Stem Cell, Dalian Medical University
(2)
State Key Laboratory of Oncology in South China, Sun Yat-sen University Cancer Center
(3)
Department of Oncology, The Second Affiliated Hospital, Dalian Medical University
(4)
Department of Hematology, The Third Affiliated Hospital, Sun Yat-sen University

References

  1. Chen W, Zheng R, Zeng H, Zhang S. The updated incidences and mortalities of major cancers in China, 2011. Chin J Cancer. 2015;34(3):53.PubMed CentralView ArticleGoogle Scholar
  2. Siegel RL, Miller KD, Jemal A. Cancer statistics, 2015. CA Cancer J Clin. 2015;65(1):5–29.PubMedView ArticleGoogle Scholar
  3. Nowell PC. A minute chromosome in human chronic granulocytic leukemia. Science. 1960;132:497–501.Google Scholar
  4. Rowley JD. New consistent chromosomal abnormality in chronic myelogenous leukaemia identified by quinacrine fluorescence and Giemsa staining. Nature. 1973;243:290–3.PubMedView ArticleGoogle Scholar
  5. Collins SJ, Groudine MT. Rearrangement and amplification of c-abl sequences in the human chronic myelogenous leukemia cell line K-562. Proc Natl Acad Sci USA. 1983;80(15):4813–7.PubMedPubMed CentralView ArticleGoogle Scholar
  6. Kurzrock R, Gutterman JU, Talpaz M. The molecular genetics of Philadelphia chromosome-positive leukemias. N Engl J Med. 1988;319(15):990–8.PubMedView ArticleGoogle Scholar
  7. Li S, Ilaria RL Jr, Million RP, Daley GQ, Van Etten RA. The P190, P210, and P230 forms of the BCR/ABL oncogene induce a similar chronic myeloid leukemia-like syndrome in mice but have different lymphoid leukemogenic activity. J Exp Med. 1999;189(9):1399–412.PubMedPubMed CentralView ArticleGoogle Scholar
  8. Ottmann OG, Druker BJ, Sawyers CL, Goldman JM, Reiffers J, Silver RT, et al. A phase 2 study of imatinib in patients with relapsed or refractory Philadelphia chromosome-positive acute lymphoid leukemias. Blood. 2002;100(6):1965–71.PubMedView ArticleGoogle Scholar
  9. Sawyers CL, Hochhaus A, Feldman E, Goldman JM, Miller CB, Ottmann OG, et al. Imatinib induces hematologic and cytogenetic responses in patients with chronic myelogenous leukemia in myeloid blast crisis: results of a phase II study. Blood. 2002;99(10):3530–9.PubMedView ArticleGoogle Scholar
  10. Tojo A, Usuki K, Urabe A, Maeda Y, Kobayashi Y, Jinnai I, et al. A Phase I/II study of nilotinib in Japanese patients with imatinib-resistant or -intolerant Ph + CML or relapsed/refractory Ph + ALL. Int J Hematol. 2009;89(5):679–88.PubMedView ArticleGoogle Scholar
  11. Corbin AS, Agarwal A, Loriaux M, Cortes J, Deininger MW, Druker BJ. Human chronic myeloid leukemia stem cells are insensitive to imatinib despite inhibition of BCR-ABL activity. J Clin Invest. 2011;121(1):396–409.PubMedPubMed CentralView ArticleGoogle Scholar
  12. Rafiei A, Mian AA, Doring C, Metodieva A, Oancea C, Thalheimer FB, et al. The functional interplay between the t(9;22)-associated fusion proteins BCR/ABL and ABL/BCR in Philadelphia chromosome-positive acute lymphatic leukemia. PLoS Genet. 2015;11(4):e1005144.PubMedPubMed CentralView ArticleGoogle Scholar
  13. Zhang LJ, Gan YM, Yu L. Occurrence of BCR/ABL fusion gene in a patient with acute promyelocytic leukemia. Med Oncol. 2015;32(1):382.PubMedView ArticleGoogle Scholar
  14. Verrma SP, Dutta TK, Vinod KV, Dubashi B, Ariga KK. Philadelphia chromosome positive pre-T cell acute lymphoblastic leukemia: a rare case report and short review. Indian J Hematol Blood Transfus. 2014;30(Suppl 1):177–9.PubMedPubMed CentralView ArticleGoogle Scholar
  15. Choi W, Kim M, Lim J, Han K, Lee S, Lee JW, et al. Four cases of chronic myelogenous leukemia in mixed phenotype blast phase at initial presentation mimicking mixed phenotype acute leukemia with t(9;22). Ann Lab Med. 2014;34(1):60–3.PubMedPubMed CentralView ArticleGoogle Scholar
  16. Matutes E, Pickl WF, Van’t Veer M, Morilla R, Swansbury J, Strobl H, et al. Mixed-phenotype acute leukemia: clinical and laboratory features and outcome in 100 patients defined according to the WHO 2008 classification. Blood. 2011;117(11):3163–71.PubMedView ArticleGoogle Scholar
  17. Sabattini E, Bacci F, Sagramoso C, Pileri SA. WHO classification of tumours of haematopoietic and lymphoid tissues in 2008: an overview. Pathologica. 2010;102(3):83–7.PubMedGoogle Scholar
  18. Voncken JW, Morris C, Pattengale P, Dennert G, Kikly C, Groffen J, et al. Clonal development and karyotype evolution during leukemogenesis of BCR/ABL transgenic mice. Blood. 1992;79(4):1029–36.PubMedGoogle Scholar
  19. Sill H, Goldman JM, Cross NC. Homozygous deletions of the p16 tumor-suppressor gene are associated with lymphoid transformation of chronic myeloid leukemia. Blood. 1995;85(8):2013–6.PubMedGoogle Scholar
  20. Ilaria R Jr. Bcr/Abl, leukemogenesis, and genomic instability: a complex partnership. Leuk Res. 2002;26(11):971–3.PubMedView ArticleGoogle Scholar
  21. Hagemeijer A. Chromosome abnormalities in CML. Baillieres Clin Haematol. 1987;1(4):963–81.PubMedView ArticleGoogle Scholar
  22. Score J, Calasanz MJ, Ottman O, Pane F, Yeh RF, Sobrinho-Simoes MA, et al. Analysis of genomic breakpoints in p190 and p210 BCR-ABL indicate distinct mechanisms of formation. Leukemia. 2010;24(10):1742–50.PubMedView ArticleGoogle Scholar
  23. Pane F, Frigeri F, Sindona M, Luciano L, Ferrara F, Cimino R, et al. Neutrophilic-chronic myeloid leukemia: a distinct disease with a specific molecular marker (BCR/ABL with C3/A2 junction). Blood. 1996;88(7):2410–4.PubMedGoogle Scholar
  24. He Y, Wertheim JA, Xu L, Miller JP, Karnell FG, Choi JK, et al. The coiled-coil domain and Tyr177 of bcr are required to induce a murine chronic myelogenous leukemia-like disease by bcr/abl. Blood. 2002;99(8):2957–68.PubMedView ArticleGoogle Scholar
  25. Million RP, Van Etten RA. The Grb2 binding site is required for the induction of chronic myeloid leukemia-like disease in mice by the Bcr/Abl tyrosine kinase. Blood. 2000;96(2):664–70.PubMedGoogle Scholar
  26. Maru Y, Witte ON. The BCR gene encodes a novel serine/threonine kinase activity within a single exon. Cell. 1991;67(3):459–68.PubMedView ArticleGoogle Scholar
  27. Pendergast AM, Gishizky ML, Havlik MH, Witte ON. SH1 domain autophosphorylation of P210 BCR/ABL is required for transformation but not growth factor independence. Mol Cell Biol. 1993;13(3):1728–36.PubMedPubMed CentralView ArticleGoogle Scholar
  28. Zhang X, Subrahmanyam R, Wong R, Gross AW, Ren R. The NH(2)-terminal coiled-coil domain and tyrosine 177 play important roles in induction of a myeloproliferative disease in mice by Bcr-Abl. Mol Cell Biol. 2001;21(3):840–53.PubMedPubMed CentralView ArticleGoogle Scholar
  29. Beissert T, Hundertmark A, Kaburova V, Travaglini L, Mian AA, Nervi C, et al. Targeting of the N-terminal coiled coil oligomerization interface by a helix-2 peptide inhibits unmutated and imatinib-resistant BCR/ABL. Int J Cancer. 2008;122(12):2744–52.PubMedView ArticleGoogle Scholar
  30. Preyer M, Vigneri P, Wang JY. Interplay between kinase domain autophosphorylation and F-actin binding domain in regulating imatinib sensitivity and nuclear import of BCR-ABL. PLoS ONE. 2011;6(2):e17020.PubMedPubMed CentralView ArticleGoogle Scholar
  31. Chu S, Li L, Singh H, Bhatia R. BCR-tyrosine 177 plays an essential role in Ras and Akt activation and in human hematopoietic progenitor transformation in chronic myelogenous leukemia. Cancer Res. 2007;67(14):7045–53.PubMedView ArticleGoogle Scholar
  32. Harnois T, Constantin B, Rioux A, Grenioux E, Kitzis A, Bourmeyster N. Differential interaction and activation of Rho family GTPases by p210bcr-abl and p190bcr-abl. Oncogene. 2003;22(41):6445–54.PubMedView ArticleGoogle Scholar
  33. Unwin RD, Sternberg DW, Lu Y, Pierce A, Gilliland DG, Whetton AD. Global effects of BCR/ABL and TEL/PDGFRbeta expression on the proteome and phosphoproteome: identification of the Rho pathway as a target of BCR/ABL. J Biol Chem. 2005;280(8):6316–26.PubMedView ArticleGoogle Scholar
  34. Burthem J, Rees-Unwin K, Mottram R, Adams J, Lucas GS, Spooncer E, et al. The rho-kinase inhibitors Y-27632 and fasudil act synergistically with imatinib to inhibit the expansion of ex vivo CD34(+) CML progenitor cells. Leukemia. 2007;21(8):1708–14.PubMedView ArticleGoogle Scholar
  35. Dorey K, Engen JR, Kretzschmar J, Wilm M, Neubauer G, Schindler T, et al. Phosphorylation and structure-based functional studies reveal a positive and a negative role for the activation loop of the c-Abl tyrosine kinase. Oncogene. 2001;20(56):8075–84.PubMedView ArticleGoogle Scholar
  36. Schindler T, Bornmann W, Pellicena P, Miller WT, Clarkson B, Kuriyan J. Structural mechanism for STI-571 inhibition of abelson tyrosine kinase. Science. 2000;289(5486):1938–42.PubMedView ArticleGoogle Scholar
  37. Xu W, Harrison SC, Eck MJ. Three-dimensional structure of the tyrosine kinase c-Src. Nature. 1997;385(6617):595–602.PubMedView ArticleGoogle Scholar
  38. Barila D, Superti-Furga G. An intramolecular SH3-domain interaction regulates c-Abl activity. Nat Genet. 1998;18(3):280–2.PubMedView ArticleGoogle Scholar
  39. Nagar B, Hantschel O, Young MA, Scheffzek K, Veach D, Bornmann W, et al. Structural basis for the autoinhibition of c-Abl tyrosine kinase. Cell. 2003;112(6):859–71.PubMedView ArticleGoogle Scholar
  40. Grebien F, Hantschel O, Wojcik J, Kaupe I, Kovacic B, Wyrzucki AM, et al. Targeting the SH2-Kinase interface in Bcr-Abl inhibits leukemogenesis. Cell. 2011;147(2):306–19.PubMedPubMed CentralView ArticleGoogle Scholar
  41. Zhang J, Adrian FJ, Jahnke W, Cowan-Jacob SW, Li AG, Iacob RE, et al. Targeting Bcr-Abl by combining allosteric with ATP-binding-site inhibitors. Nature. 2010;463(7280):501–6.PubMedPubMed CentralView ArticleGoogle Scholar
  42. Kantarjian HM, Keating MJ, Talpaz M, Walters RS, Smith TL, Cork A, et al. Chronic myelogenous leukemia in blast crisis. Analysis of 242 patients. Am J Med. 1987;83(3):445–54.PubMedView ArticleGoogle Scholar
  43. Okamoto K, Karasawa M, Sakai H, Ogura H, Morita K, Naruse T. A novel acute lymphoid leukaemia type BCR/ABL transcript in chronic myelogenous leukaemia. Br J Haematol. 1997;96(3):611–3.PubMedView ArticleGoogle Scholar
  44. Lichty BD, Keating A, Callum J, Yee K, Croxford R, Corpus G, et al. Expression of p210 and p190 BCR-ABL due to alternative splicing in chronic myelogenous leukaemia. Br J Haematol. 1998;103(3):711–5.PubMedView ArticleGoogle Scholar
  45. van Rhee F, Hochhaus A, Lin F, Melo JV, Goldman JM, Cross NC. p190 BCR-ABL mRNA is expressed at low levels in p210-positive chronic myeloid and acute lymphoblastic leukemias. Blood. 1996;87(12):5213–7.PubMedGoogle Scholar
  46. Arana-Trejo RM, Ruiz Sanchez E, Ignacio-Ibarra G, Baez de la Fuente E, Garces O, Gomez Morales E, et al. BCR/ABL p210, p190 and p230 fusion genes in 250 Mexican patients with chronic myeloid leukaemia (CML). Clin Lab Haematol. 2002;24(3):145–50.PubMedView ArticleGoogle Scholar
  47. Elliott SL, Taylor KM, Taylor DL, Rodwell RL, Williams BF, Shuttlewood MM, et al. Cytogenetic response to alpha-interferon is predicted in early chronic phase chronic myeloid leukemia by M-bcr breakpoint location. Leukemia. 1995;9(6):946–50.PubMedGoogle Scholar
  48. Rozman C, Urbano-Ispizua A, Cervantes F, Rozman M, Colomer D, Feliz P, et al. Analysis of the clinical relevance of the breakpoint location within M-BCR and the type of chimeric mRNA in chronic myelogenous leukemia. Leukemia. 1995;9(6):1104–7.PubMedGoogle Scholar
  49. Pullarkat V, Slovak ML, Kopecky KJ, Forman SJ, Appelbaum FR. Impact of cytogenetics on the outcome of adult acute lymphoblastic leukemia: results of Southwest Oncology Group 9400 study. Blood. 2008;111(5):2563–72.PubMedPubMed CentralView ArticleGoogle Scholar
  50. Schultz KR, Pullen DJ, Sather HN, Shuster JJ, Devidas M, Borowitz MJ, et al. Risk- and response-based classification of childhood B-precursor acute lymphoblastic leukemia: a combined analysis of prognostic markers from the Pediatric Oncology Group (POG) and Children’s Cancer Group (CCG). Blood. 2007;109(3):926–35.PubMedPubMed CentralView ArticleGoogle Scholar
  51. Mrozek K, Harper DP, Aplan PD. Cytogenetics and molecular genetics of acute lymphoblastic leukemia. Hematol Oncol Clin North Am. 2009;23(5):991–1010.PubMedPubMed CentralView ArticleGoogle Scholar
  52. Larson RA. Management of acute lymphoblastic leukemia in older patients. Semin Hematol. 2006;43(2):126–33.PubMedView ArticleGoogle Scholar
  53. Mancini M, Scappaticci D, Cimino G, Nanni M, Derme V, Elia L, et al. A comprehensive genetic classification of adult acute lymphoblastic leukemia (ALL): analysis of the GIMEMA 0496 protocol. Blood. 2005;105(9):3434–41.PubMedView ArticleGoogle Scholar
  54. Moorman AV, Harrison CJ, Buck GA, Richards SM, Secker-Walker LM, Martineau M, et al. Karyotype is an independent prognostic factor in adult acute lymphoblastic leukemia (ALL): analysis of cytogenetic data from patients treated on the Medical Research Council (MRC) UKALLXII/Eastern Cooperative Oncology Group (ECOG) 2993 trial. Blood. 2007;109(8):3189–97.PubMedView ArticleGoogle Scholar
  55. Stock W. Advances in the treatment of Philadelphia chromosome-positive acute lymphoblastic leukemia. Clin Adv Hematol Oncol. 2008;6(7):487–8.PubMedGoogle Scholar
  56. Melo JV. The diversity of BCR-ABL fusion proteins and their relationship to leukemia phenotype. Blood. 1996;88(7):2375–84.PubMedGoogle Scholar
  57. Emilia G, Luppi M, Marasca R, Torelli G. Relationship between BCR/ABL fusion proteins and leukemia phenotype. Blood. 1997;89(10):3889.PubMedGoogle Scholar
  58. Roman J, Parziale A, Gottardi E, De Micheli D, Cilloni D, Tiribelli M, et al. Novel type of BCR-ABL transcript in a chronic myelogenous leukaemia patient relapsed after bone marrow transplantation. Br J Haematol. 2000;111(2):644–6.PubMedView ArticleGoogle Scholar
  59. Soekarman D, van Denderen J, Hoefsloot L, Moret M, Meeuwsen T, van Baal J, et al. A novel variant of the bcr-abl fusion product in Philadelphia chromosome-positive acute lymphoblastic leukemia. Leukemia. 1990;4(6):397–403.PubMedGoogle Scholar
  60. Arico M, Schrappe M, Hunger SP, Carroll WL, Conter V, Galimberti S, et al. Clinical outcome of children with newly diagnosed Philadelphia chromosome-positive acute lymphoblastic leukemia treated between 1995 and 2005. J Clin Oncol. 2010;28(31):4755–61.PubMedPubMed CentralView ArticleGoogle Scholar
  61. Yanada M, Ohno R, Naoe T. Recent advances in the treatment of Philadelphia chromosome-positive acute lymphoblastic leukemia. Int J Hematol. 2009;89(1):3–13.PubMedView ArticleGoogle Scholar
  62. Kihara R, Nagata Y, Kiyoi H, Kato T, Yamamoto E, Suzuki K, et al. Comprehensive analysis of genetic alterations and their prognostic impacts in adult acute myeloid leukemia patients. Leukemia. 2014;28(8):1586–95.PubMedView ArticleGoogle Scholar
  63. Ley TJ, Miller C, Ding L, Raphael BJ, Mungall AJ, Robertson AG, et al. Genomic and epigenomic landscapes of adult de novo acute myeloid leukemia. New Engl J Med. 2013;368(22):2059–74.View ArticleGoogle Scholar
  64. Soupir CP, Vergilio JA, Dal Cin P, Muzikansky A, Kantarjian H, Jones D, et al. Philadelphia chromosome-positive acute myeloid leukemia: a rare aggressive leukemia with clinicopathologic features distinct from chronic myeloid leukemia in myeloid blast crisis. Am J Clin Pathol. 2007;127(4):642–50.PubMedView ArticleGoogle Scholar
  65. Johansson B, Fioretos T, Mitelman F. Cytogenetic and molecular genetic evolution of chronic myeloid leukemia. Acta Haematol. 2002;107(2):76–94.PubMedView ArticleGoogle Scholar
  66. Nacheva EP, Grace CD, Brazma D, Gancheva K, Howard-Reeves J, Rai L, et al. Does BCR/ABL1 positive Acute Myeloid Leukaemia Exist? Brit J Haematol. 2013;161(4):541–50.View ArticleGoogle Scholar
  67. Vardiman JW, Thiele J, Arber DA, Brunning RD, Borowitz MJ, Porwit A, et al. The 2008 revision of the World Health Organization (WHO) classification of myeloid neoplasms and acute leukemia: rationale and important changes. Blood. 2009;114(5):937–51.PubMedView ArticleGoogle Scholar
  68. Killick S, Matutes E, Powles RL, Hamblin M, Swansbury J, Treleaven JG, et al. Outcome of biphenotypic acute leukemia. Haematologica. 1999;84(8):699–706.PubMedGoogle Scholar
  69. Owaidah TM, Al Beihany A, Iqbal MA, Elkum N, Roberts GT. ACytogenetics, molecular and ultrastructural characteristics of biphenotypic acute leukemia identified by the EGIL scoring system. Leukemia. 2006;20(4):620–6.PubMedView ArticleGoogle Scholar
  70. Al-Seraihy AS, Owaidah TM, Ayas M, El-Solh H, Al-Mahr M, Al-Ahmari A, et al. Clinical characteristics and outcome of children with biphenotypic acute leukemia. Haematologica. 2009;94(12):1682–90.PubMedPubMed CentralView ArticleGoogle Scholar
  71. Bhatia P, Binota J, Varma N, Bansal D, Trehan A, Marwaha RK, et al. A Study on the expression of BCR-ABL transcript in mixed phenotype acute leukemia (MPAL) cases using the reverse transcriptase polymerase reaction assay (RT-PCR) and its correlation with hematological remission status post initial induction therapy. Mediterr J Hematol Infect Dis. 2012;4(1):e2012024.PubMedPubMed CentralView ArticleGoogle Scholar
  72. Wang Y, Gu M, Mi Y, Qiu L, Bian S, Wang J. Clinical characteristics and outcomes of mixed phenotype acute leukemia with Philadelphia chromosome positive and/or bcr-abl positive in adult. Int J Hematol. 2011;94(6):552–5.PubMedView ArticleGoogle Scholar
  73. Daley GQ, Van Etten RA, Baltimore D. Induction of chronic myelogenous leukemia in mice by the P210bcr/abl gene of the Philadelphia chromosome. Science. 1990;247(4944):824–30.PubMedView ArticleGoogle Scholar
  74. Heisterkamp N, Jenster G, ten Hoeve J, Zovich D, Pattengale PK, Groffen J. Acute leukaemia in bcr/abl transgenic mice. Nature. 1990;344(6263):251–3.PubMedView ArticleGoogle Scholar
  75. Voncken JW, Kaartinen V, Pattengale PK, Germeraad WT, Groffen J, Heisterkamp N. BCR/ABL P210 and P190 cause distinct leukemia in transgenic mice. Blood. 1995;86(12):4603–11.PubMedGoogle Scholar
  76. Castellanos A, Pintado B, Weruaga E, Arevalo R, Lopez A, Orfao A, et al. A BCR-ABL(p190) fusion gene made by homologous recombination causes B-cell acute lymphoblastic leukemias in chimeric mice with independence of the endogenous bcr product. Blood. 1997;90(6):2168–74.PubMedGoogle Scholar
  77. Lugo TG, Pendergast AM, Muller AJ, Witte ON. Tyrosine kinase activity and transformation potency of bcr-abl oncogene products. Science. 1990;247(4946):1079–82.PubMedView ArticleGoogle Scholar
  78. Roumiantsev S, de Aos IE, Varticovski L, Ilaria RL, Van Etten RA. The src homology 2 domain of Bcr/Abl is required for efficient induction of chronic myeloid leukemia-like disease in mice but not for lymphoid leukemogenesis or activation of phosphatidylinositol 3-kinase. Blood. 2001;97(1):4–13.PubMedView ArticleGoogle Scholar
  79. Zhang X, Wong R, Hao SX, Pear WS, Ren R. The SH2 domain of bcr-Abl is not required to induce a murine myeloproliferative disease; however, SH2 signaling influences disease latency and phenotype. Blood. 2001;97(1):277–87.PubMedView ArticleGoogle Scholar
  80. Sattler M, Griffin JD. Molecular mechanisms of transformation by the BCR-ABL oncogene. Semin Hematol. 2003;40(Suppl 2):4–10.PubMedView ArticleGoogle Scholar
  81. Ilaria RL Jr, Van Etten RA. P210 and P190(BCR/ABL) induce the tyrosine phosphorylation and DNA binding activity of multiple specific STAT family members. J Biol Chem. 1996;271(49):31704–10.PubMedView ArticleGoogle Scholar
  82. Frank DA, Varticovski L. BCR/abl leads to the constitutive activation of Stat proteins, and shares an epitope with tyrosine phosphorylated Stats. Leukemia. 1996;10(11):1724–30.PubMedGoogle Scholar
  83. Tao WJ, Lin H, Sun T, Samanta AK, Arlinghaus R. BCR-ABL oncogenic transformation of NIH 3T3 fibroblasts requires the IL-3 receptor. Oncogene. 2008;27(22):3194–200.PubMedPubMed CentralView ArticleGoogle Scholar
  84. Warsch W, Walz C, Sexl V. JAK of all trades: JAK2-STAT5 as novel therapeutic targets in BCR-ABL1 + chronic myeloid leukemia. Blood. 2013;122(13):2167–75.PubMedView ArticleGoogle Scholar
  85. Valent P. Targeting the JAK2-STAT5 pathway in CML. Blood. 2014;124(9):1386–8.PubMedPubMed CentralView ArticleGoogle Scholar
  86. Baird AM, Lucas JA, Berg LJ. A profound deficiency in thymic progenitor cells in mice lacking Jak3. J Immunol. 2000;165(7):3680–8.PubMedView ArticleGoogle Scholar
  87. Grossman WJ, Verbsky JW, Yang L, Berg LJ, Fields LE, Chaplin DD, et al. Dysregulated myelopoiesis in mice lacking Jak3. Blood. 1999;94(3):932–9.PubMedGoogle Scholar
  88. Thomis DC, Gurniak CB, Tivol E, Sharpe AH, Berg LJ. Defects in B lymphocyte maturation and T lymphocyte activation in mice lacking Jak3. Science. 1995;270(5237):794–7.PubMedView ArticleGoogle Scholar
  89. Nosaka T, van Deursen JM, Tripp RA, Thierfelder WE, Witthuhn BA, McMickle AP, et al. Defective lymphoid development in mice lacking Jak3. Science. 1995;270(5237):800–2.PubMedView ArticleGoogle Scholar
  90. Samanta A, Perazzona B, Chakraborty S, Sun X, Modi H, Bhatia R, et al. Janus kinase 2 regulates Bcr-Abl signaling in chronic myeloid leukemia. Leukemia. 2011;25(3):463–72.PubMedPubMed CentralView ArticleGoogle Scholar
  91. Xie S, Lin H, Sun T, Arlinghaus RB. Jak2 is involved in c-Myc induction by Bcr-Abl. Oncogene. 2002;21(47):7137–46.PubMedView ArticleGoogle Scholar
  92. Sawyers CL. The role of myc in transformation by BCR-ABL. Leuk Lymphoma. 1993;11(Suppl 1):45–6.PubMedView ArticleGoogle Scholar
  93. Stella S, Tirro E, Conte E, Stagno F, Di Raimondo F, Manzella L, et al. Suppression of survivin induced by a BCR-ABL/JAK2/STAT3 pathway sensitizes imatinib-resistant CML cells to different cytotoxic drugs. Mol Cancer Ther. 2013;12(6):1085–98.PubMedView ArticleGoogle Scholar
  94. Fang ZH, Dong CL, Chen Z, Zhou B, Liu N, Lan HF, et al. Transcriptional regulation of survivin by c-Myc in BCR/ABL-transformed cells: implications in anti-leukaemic strategy. J Cell Mol Med. 2009;13(8B):2039–52.PubMedView ArticleGoogle Scholar
  95. Hoelbl A, Schuster C, Kovacic B, Zhu B, Wickre M, Hoelzl MA, et al. Stat5 is indispensable for the maintenance of bcr/abl-positive leukaemia. EMBO Mol Med. 2010;2(3):98–110.PubMedPubMed CentralView ArticleGoogle Scholar
  96. Grundschober E, Hoelbl-Kovacic A, Bhagwat N, Kovacic B, Scheicher R, Eckelhart E, et al. Acceleration of Bcr-Abl + leukemia induced by deletion of JAK2. Leukemia. 2014;28(9):1918–22.PubMedPubMed CentralView ArticleGoogle Scholar
  97. Sayed D, Badrawy H, Gaber N, Khalaf MR. p-Stat3 and bcr/abl gene expression in chronic myeloid leukemia and their relation to imatinib therapy. Leuk Res. 2014;38(2):243–50.PubMedView ArticleGoogle Scholar
  98. Coppo P, Flamant S, De Mas V, Jarrier P, Guillier M, Bonnet ML, et al. BCR-ABL activates STAT3 via JAK and MEK pathways in human cells. Br J Haematol. 2006;134(2):171–9.PubMedView ArticleGoogle Scholar
  99. Hoelbl A, Kovacic B, Kerenyi MA, Simma O, Warsch W, Cui Y, et al. Clarifying the role of Stat5 in lymphoid development and Abelson-induced transformation. Blood. 2006;107(12):4898–906.PubMedPubMed CentralView ArticleGoogle Scholar
  100. Walz C, Ahmed W, Lazarides K, Betancur M, Patel N, Hennighausen L, et al. Essential role for Stat5a/b in myeloproliferative neoplasms induced by BCR-ABL1 and JAK2(V617F) in mice. Blood. 2012;119(15):3550–60.PubMedPubMed CentralView ArticleGoogle Scholar
  101. Li Q, Wu Y, Fang S, Wang L, Qi H, Zhang Y, et al. BCR/ABL oncogene-induced PI3 K signaling pathway leads to chronic myeloid leukemia pathogenesis by impairing immuno-modulatory function of hemangioblasts. Cancer Gene Ther. 2015;22(5):227–37.PubMedView ArticleGoogle Scholar
  102. Keeshan K, Cotter TG, McKenna SL. Bcr-Abl upregulates cytosolic p21WAF-1/CIP-1 by a phosphoinositide-3-kinase (PI3 K)-independent pathway. Br J Haematol. 2003;123(1):34–44.PubMedView ArticleGoogle Scholar
  103. Andreu EJ, Lledo E, Poch E, Ivorra C, Albero MP, Martinez-Climent JA, et al. BCR-ABL induces the expression of Skp2 through the PI3 K pathway to promote p27Kip1 degradation and proliferation of chronic myelogenous leukemia cells. Cancer Res. 2005;65(8):3264–72.PubMedGoogle Scholar
  104. Kim JH, Chu SC, Gramlich JL, Pride YB, Babendreier E, Chauhan D, et al. Activation of the PI3 K/mTOR pathway by BCR-ABL contributes to increased production of reactive oxygen species. Blood. 2005;105(4):1717–23.PubMedView ArticleGoogle Scholar
  105. Naughton R, Quiney C, Turner SD, Cotter TG. Bcr-Abl-mediated redox regulation of the PI3 K/AKT pathway. Leukemia. 2009;23(8):1432–40.PubMedView ArticleGoogle Scholar
  106. Kharas MG, Janes MR, Scarfone VM, Lilly MB, Knight ZA, Shokat KM, et al. Ablation of PI3 K blocks BCR-ABL leukemogenesis in mice, and a dual PI3 K/mTOR inhibitor prevents expansion of human BCR-ABL + leukemia cells. J Clin Invest. 2008;118(9):3038–50.PubMedPubMed CentralView ArticleGoogle Scholar
  107. Okabe S, Tauchi T, Tanaka Y, Kitahara T, Kimura S, Maekawa T, et al. Efficacy of the dual PI3 K and mTOR inhibitor NVP-BEZ235 in combination with nilotinib against BCR-ABL-positive leukemia cells involves the ABL kinase domain mutation. Cancer Biol Ther. 2014;15(2):207–15.PubMedPubMed CentralView ArticleGoogle Scholar
  108. Rioux-Bilan A, Daubon T, Morel F, Kitzis A, Bourmeyster N. Inhibition of PI3 K synergistically enhances the apoptotic effect of STI-571 on p210(bcr-abl)-transformed cells in a Rac1-dependent manner. Leuk Res. 2008;32(3):517–9.PubMedView ArticleGoogle Scholar
  109. Barrett D, Brown VI, Grupp SA, Teachey DT. Targeting the PI3 K/AKT/mTOR signaling axis in children with hematologic malignancies. Paediatr Drugs. 2012;14(5):299–316.PubMedPubMed CentralGoogle Scholar
  110. Caino MC, Ghosh JC, Chae YC, Vaira V, Rivadeneira DB, Faversani A, et al. PI3 K therapy reprograms mitochondrial trafficking to fuel tumor cell invasion. Proc Natl Acad Sci USA. 2015;112(28):8638–43.PubMedPubMed CentralView ArticleGoogle Scholar
  111. Steelman LS, Pohnert SC, Shelton JG, Franklin RA, Bertrand FE, McCubrey JA. JAK/STAT, Raf/MEK/ERK, PI3 K/Akt and BCR-ABL in cell cycle progression and leukemogenesis. Leukemia. 2004;18(2):189–218.PubMedView ArticleGoogle Scholar
  112. Jin A, Kurosu T, Tsuji K, Mizuchi D, Arai A, Fujita H, et al. BCR/ABL and IL-3 activate Rap1 to stimulate the B-Raf/MEK/Erk and Akt signaling pathways and to regulate proliferation, apoptosis, and adhesion. Oncogene. 2006;25(31):4332–40.PubMedView ArticleGoogle Scholar
  113. Mizuchi D, Kurosu T, Kida A, Jin ZH, Jin A, Arai A, et al. BCR/ABL activates Rap1 and B-Raf to stimulate the MEK/Erk signaling pathway in hematopoietic cells. Biochem Biophys Res Commun. 2005;326(3):645–51.PubMedView ArticleGoogle Scholar
  114. Mandanas RA, Leibowitz DS, Gharehbaghi K, Tauchi T, Burgess GS, Miyazawa K, et al. Role of p21 RAS in p210 bcr-abl transformation of murine myeloid cells. Blood. 1993;82(6):1838–47.PubMedGoogle Scholar
  115. Baum KJ, Ren R. Effect of Ras inhibition in hematopoiesis and BCR/ABL leukemogenesis. J Hematol Oncol. 2008;1:5.PubMedPubMed CentralView ArticleGoogle Scholar
  116. Brozik A, Casey NP, Hegedus C, Bors A, Kozma A, Andrikovics H, et al. Reduction of Bcr-Abl function leads to erythroid differentiation of K562 cells via downregulation of ERK. Ann N Y Acad Sci. 2006;1090:344–54.PubMedView ArticleGoogle Scholar
  117. Ozaki K, Kosugi M, Baba N, Fujio K, Sakamoto T, Kimura S, et al. Blockade of the ERK or PI3 K-Akt signaling pathway enhances the cytotoxicity of histone deacetylase inhibitors in tumor cells resistant to gefitinib or imatinib. Biochem Biophys Res Commun. 2010;391(4):1610–5.PubMedView ArticleGoogle Scholar
  118. Basak P, Chatterjee S, Das P, Das M, Pereira JA, Dutta RK, et al. Leukemic stromal hematopoietic microenvironment negatively regulates the normal hematopoiesis in mouse model of leukemia. Chin J Cancer. 2010;29(12):969–79.PubMedView ArticleGoogle Scholar
  119. Hickey FB, England K, Cotter TG. Bcr-Abl regulates osteopontin transcription via Ras, PI-3 K, aPKC, Raf-1, and MEK. J Leukoc Biol. 2005;78(1):289–300.PubMedView ArticleGoogle Scholar
  120. Asmussen J, Lasater EA, Tajon C, Oses-Prieto J, Jun YW, Taylor BS, et al. MEK-dependent negative feedback underlies BCR-ABL-mediated oncogene addiction. Cancer Discov. 2014;4(2):200–15.PubMedPubMed CentralView ArticleGoogle Scholar
  121. Kuroda I, Inukai T, Zhang X, Kikuchi J, Furukawa Y, Nemoto A, et al. BCR-ABL regulates death receptor expression for TNF-related apoptosis-inducing ligand (TRAIL) in Philadelphia chromosome-positive leukemia. Oncogene. 2013;32(13):1670–81.PubMedView ArticleGoogle Scholar
  122. Zhao S, Asgary Z, Wang Y, Goodwin R, Andreeff M, Younes A. Functional expression of TRAIL by lymphoid and myeloid tumour cells. Br J Haematol. 1999;106(3):827–32.PubMedView ArticleGoogle Scholar
  123. De Carvalho DD, Binato R, Pereira WO, Leroy JM, Colassanti MD, Proto-Siqueira R, et al. BCR-ABL-mediated upregulation of PRAME is responsible for knocking down TRAIL in CML patients. Oncogene. 2011;30(2):223–33.PubMedView ArticleGoogle Scholar
  124. Uno K, Inukai T, Kayagaki N, Goi K, Sato H, Nemoto A, et al. TNF-related apoptosis-inducing ligand (TRAIL) frequently induces apoptosis in Philadelphia chromosome-positive leukemia cells. Blood. 2003;101(9):3658–67.PubMedView ArticleGoogle Scholar
  125. Nimmanapalli R, Porosnicu M, Nguyen D, Worthington E, O’Bryan E, Perkins C, et al. Cotreatment with STI-571 enhances tumor necrosis factor alpha-related apoptosis-inducing ligand (TRAIL or apo-2L)-induced apoptosis of Bcr-Abl-positive human acute leukemia cells. Clin Cancer Res. 2001;7(2):350–7.PubMedGoogle Scholar
  126. Park SJ, Kim MJ, Kim HB, Kang CD, Kim SH. Sensitization of imatinib-resistant CML cells to TRAIL-induced apoptosis is mediated through down-regulation of Bcr-Abl as well as c-FLIP. Biochem J. 2009;420(1):73–81.PubMedView ArticleGoogle Scholar
  127. Raimondo S, Naselli F, Fontana S, Monteleone F, Lo Dico A, Saieva L, et al. Citrus limon-derived nanovesicles inhibit cancer cell proliferation and suppress CML xenograft growth by inducing TRAIL-mediated cell death. Oncotarget. 2015;6:1951.View ArticleGoogle Scholar
  128. Perrotti D, Cesi V, Trotta R, Guerzoni C, Santilli G, Campbell K, et al. BCR-ABL suppresses C/EBPalpha expression through inhibitory action of hnRNP E2. Nat Genet. 2002;30(1):48–58.PubMedView ArticleGoogle Scholar
  129. Chen XM, Feng WL, Zhao SQ, Zeng JM, Bai WJ, Wang XZ, et al. Effect and possible mechanism of HnRNP E2 decoy RNA on proliferation of K562 leukemia cells. Ai Zheng. 2006;25(7):793–7.PubMedGoogle Scholar
  130. Chang JS, Santhanam R, Trotta R, Neviani P, Eiring AM, Briercheck E, et al. High levels of the BCR/ABL oncoprotein are required for the MAPK-hnRNP-E2 dependent suppression of C/EBPalpha-driven myeloid differentiation. Blood. 2007;110(3):994–1003.PubMedPubMed CentralView ArticleGoogle Scholar
  131. Zhang P, Iwasaki-Arai J, Iwasaki H, Fenyus ML, Dayaram T, Owens BM, et al. Enhancement of hematopoietic stem cell repopulating capacity and self-renewal in the absence of the transcription factor C/EBP alpha. Immunity. 2004;21(6):853–63.PubMedView ArticleGoogle Scholar
  132. Eiring AM, Harb JG, Neviani P, Garton C, Oaks JJ, Spizzo R, et al. miR-328 functions as an RNA decoy to modulate hnRNP E2 regulation of mRNA translation in leukemic blasts. Cell. 2010;140(5):652–65.PubMedPubMed CentralView ArticleGoogle Scholar
  133. Fragliasso V, Chiodo Y, Ferrari-Amorotti G, Soliera AR, Manzotti G, Cattelani S, et al. Phosphorylation of serine 21 modulates the proliferation inhibitory more than the differentiation inducing effects of C/EBPalpha in K562 cells. J Cell Biochem. 2012;113(5):1704–13.PubMedPubMed CentralGoogle Scholar
  134. Schuster C, Forster K, Dierks H, Elsasser A, Behre G, Simon N, et al. The effects of Bcr-Abl on C/EBP transcription-factor regulation and neutrophilic differentiation are reversed by the Abl kinase inhibitor imatinib mesylate. Blood. 2003;101(2):655–63.PubMedView ArticleGoogle Scholar
  135. Ferrari-Amorotti G, Mariani SA, Novi C, Cattelani S, Pecorari L, Corradini F, et al. The biological effects of C/EBPalpha in K562 cells depend on the potency of the N-terminal regulatory region, not on specificity of the DNA binding domain. J Biol Chem. 2010;285(40):30837–50.PubMedPubMed CentralView ArticleGoogle Scholar
  136. Tavor S, Park DJ, Gery S, Vuong PT, Gombart AF, Koeffler HP. Restoration of C/EBPalpha expression in a BCR-ABL + cell line induces terminal granulocytic differentiation. J Biol Chem. 2003;278(52):52651–9.PubMedView ArticleGoogle Scholar
  137. Ferrari-Amorotti G, Keeshan K, Zattoni M, Guerzoni C, Iotti G, Cattelani S, et al. Leukemogenesis induced by wild-type and STI571-resistant BCR/ABL is potently suppressed by C/EBPalpha. Blood. 2006;108(4):1353–62.PubMedPubMed CentralView ArticleGoogle Scholar
  138. Guerzoni C, Bardini M, Mariani SA, Ferrari-Amorotti G, Neviani P, Panno ML, et al. Inducible activation of CEBPB, a gene negatively regulated by BCR/ABL, inhibits proliferation and promotes differentiation of BCR/ABL-expressing cells. Blood. 2006;107(10):4080–9.PubMedPubMed CentralView ArticleGoogle Scholar
  139. Soliera AR, Lidonnici MR, Ferrari-Amorotti G, Prisco M, Zhang Y, Martinez RV, et al. Transcriptional repression of c-Myb and GATA-2 is involved in the biologic effects of C/EBPalpha in p210BCR/ABL-expressing cells. Blood. 2008;112(5):1942–50.PubMedPubMed CentralView ArticleGoogle Scholar
  140. Wagner K, Zhang P, Rosenbauer F, Drescher B, Kobayashi S, Radomska HS, et al. Absence of the transcription factor CCAAT enhancer binding protein alpha results in loss of myeloid identity in bcr/abl-induced malignancy. Proc Natl Acad Sci USA. 2006;103(16):6338–43.PubMedPubMed CentralView ArticleGoogle Scholar
  141. McClellan JS, Dove C, Gentles AJ, Ryan CE, Majeti R. Reprogramming of primary human Philadelphia chromosome-positive B cell acute lymphoblastic leukemia cells into nonleukemic macrophages. Proc Natl Acad Sci USA. 2015;112(13):4074–9.PubMedPubMed CentralView ArticleGoogle Scholar
  142. Annamaneni S, Kagita S, Gorre M, Digumarti RR, Satti V, Battini MR. Methylation status of CEBPA gene promoter in chronic myeloid leukemia. Hematology. 2014;19(1):42–4.PubMedView ArticleGoogle Scholar
  143. Zhang SP, Niu YN, Yuan N, Zhang AH, Chao D, Xu QP, et al. Role of autophagy in acute myeloid leukemia therapy. Chin J Cancer. 2013;32(3):130–5.PubMedPubMed CentralView ArticleGoogle Scholar
  144. Kamitsuji Y, Kuroda J, Kimura S, Toyokuni S, Watanabe K, Ashihara E, et al. The Bcr-Abl kinase inhibitor INNO-406 induces autophagy and different modes of cell death execution in Bcr-Abl-positive leukemias. Cell Death Differ. 2008;15(11):1712–22.PubMedView ArticleGoogle Scholar
  145. Carew JS, Nawrocki ST, Kahue CN, Zhang H, Yang C, Chung L, et al. Targeting autophagy augments the anticancer activity of the histone deacetylase inhibitor SAHA to overcome Bcr-Abl-mediated drug resistance. Blood. 2007;110(1):313–22.PubMedPubMed CentralView ArticleGoogle Scholar
  146. Calabretta B, Salomoni P. Suppression of autophagy by BCR/ABL. Front Biosci (Schol Ed). 2012;4:453–60.View ArticleGoogle Scholar
  147. Zeng X, Zhao H, Li Y, Fan J, Sun Y, Wang S, et al. Targeting Hedgehog signaling pathway and autophagy overcomes drug resistance of BCR-ABL-positive chronic myeloid leukemia. Autophagy. 2015;11(2):355–72.PubMedPubMed CentralView ArticleGoogle Scholar
  148. Altman BJ, Jacobs SR, Mason EF, Michalek RD, MacIntyre AN, Coloff JL, et al. Autophagy is essential to suppress cell stress and to allow BCR-Abl-mediated leukemogenesis. Oncogene. 2011;30(16):1855–67.PubMedPubMed CentralView ArticleGoogle Scholar
  149. Gounaris E, Wu EJ, Vakana E, Sharma B, Bogyo M, Altman JK, et al. Autophagic degradation of the BCR-ABL oncoprotein and generation of antileukemic responses by arsenic trioxide. Blood. 2012;120(17):3555–62.PubMedPubMed CentralView ArticleGoogle Scholar
  150. Turner SD, Alexander DR. Fusion tyrosine kinase mediated signalling pathways in the transformation of haematopoietic cells. Leukemia. 2006;20(4):572–82.PubMedView ArticleGoogle Scholar
  151. Fernandes MS, Reddy MM, Gonneville JR, DeRoo SC, Podar K, Griffin JD, et al. BCR-ABL promotes the frequency of mutagenic single-strand annealing DNA repair. Blood. 2009;114(9):1813–9.PubMedPubMed CentralView ArticleGoogle Scholar
  152. Nowicki MO, Falinski R, Koptyra M, Slupianek A, Stoklosa T, Gloc E, et al. BCR/ABL oncogenic kinase promotes unfaithful repair of the reactive oxygen species-dependent DNA double-strand breaks. Blood. 2004;104(12):3746–53.PubMedView ArticleGoogle Scholar
  153. Cramer K, Nieborowska-Skorska M, Koptyra M, Slupianek A, Penserga ET, Eaves CJ, et al. BCR/ABL and other kinases from chronic myeloproliferative disorders stimulate single-strand annealing, an unfaithful DNA double-strand break repair. Cancer Res. 2008;68(17):6884–8.PubMedPubMed CentralView ArticleGoogle Scholar
  154. Slupianek A, Poplawski T, Jozwiakowski SK, Cramer K, Pytel D, Stoczynska E, et al. BCR/ABL stimulates WRN to promote survival and genomic instability. Cancer Res. 2011;71(3):842–51.PubMedPubMed CentralView ArticleGoogle Scholar
  155. Laneuville P, Sun G, Timm M, Vekemans M. Clonal evolution in a myeloid cell line transformed to interleukin-3 independent growth by retroviral transduction and expression of p210bcr/abl. Blood. 1992;80(7):1788–97.PubMedGoogle Scholar
  156. Gerber JM, Gucwa JL, Esopi D, Gurel M, Haffner MC, Vala M, et al. Genome-wide comparison of the transcriptomes of highly enriched normal and chronic myeloid leukemia stem and progenitor cell populations. Oncotarget. 2013;4(5):715–28.PubMedPubMed CentralView ArticleGoogle Scholar
  157. Ilaria RL, Jr. Pathobiology of lymphoid and myeloid blast crisis and management issues. Hematology Am Soc Hematol Educ Program. 2005:188-94.Google Scholar
  158. Perrotti D, Jamieson C, Goldman J, Skorski T. Chronic myeloid leukemia: mechanisms of blastic transformation. J Clin Invest. 2010;120(7):2254–64.PubMedPubMed CentralView ArticleGoogle Scholar
  159. Skorski T. Genetic mechanisms of chronic myeloid leukemia blastic transformation. Curr Hematol Malig Rep. 2012;7(2):87–93.PubMedView ArticleGoogle Scholar
  160. Cazzaniga G, van Delft FW, Lo Nigro L, Ford AM, Score J, Iacobucci I, et al. Developmental origins and impact of BCR-ABL1 fusion and IKZF1 deletions in monozygotic twins with Ph + acute lymphoblastic leukemia. Blood. 2011;118(20):5559–64.PubMedPubMed CentralView ArticleGoogle Scholar
  161. Theocharides AP, Dobson SM, Laurenti E, Notta F, Voisin V, Cheng PY, et al. Dominant-negative Ikaros cooperates with BCR-ABL1 to induce human acute myeloid leukemia in xenografts. Leukemia. 2015;29(1):177–87.PubMedView ArticleGoogle Scholar
  162. Beer PA, Knapp DJ, Miller PH, Kannan N, Sloma I, Heel K, et al. Disruption of IKAROS activity in primitive chronic-phase CML cells mimics myeloid disease progression. Blood. 2015;125(3):504–15.PubMedPubMed CentralView ArticleGoogle Scholar
  163. Mullighan CG, Miller CB, Radtke I, Phillips LA, Dalton J, Ma J, et al. BCR-ABL1 lymphoblastic leukaemia is characterized by the deletion of Ikaros. Nature. 2008;453(7191):110.PubMedView ArticleGoogle Scholar
  164. Mullighan CG, Su X, Zhang J, Radtke I, Phillips LA, Miller CB, et al. Deletion of IKZF1 and prognosis in acute lymphoblastic leukemia. N Engl J Med. 2009;360(5):470–80.PubMedPubMed CentralView ArticleGoogle Scholar
  165. Dupuis A, Gaub MP, Legrain M, Drenou B, Mauvieux L, Lutz P, et al. Biclonal and biallelic deletions occur in 20% of B-ALL cases with IKZF1 mutations. Leukemia. 2013;27(2):503–7.PubMedView ArticleGoogle Scholar
  166. de Rooij JD, Beuling E, van den Heuvel-Eibrink MM, Obulkasim A, Baruchel A, Trka J, et al. Recurrent deletions of IKZF1 in pediatric acute myeloid leukemia. Haematologica. 2015;100:1151.PubMedPubMed CentralView ArticleGoogle Scholar
  167. Iacobucci I, Storlazzi CT, Cilloni D, Lonetti A, Ottaviani E, Soverini S, et al. Identification and molecular characterization of recurrent genomic deletions on 7p12 in the IKZF1 gene in a large cohort of BCR-ABL1-positive acute lymphoblastic leukemia patients: on behalf of Gruppo Italiano Malattie Ematologiche dell’Adulto Acute Leukemia Working Party (GIMEMA AL WP). Blood. 2009;114(10):2159–67.PubMedView ArticleGoogle Scholar
  168. Lin H, Grosschedl R. Failure of B-cell differentiation in mice lacking the transcription factor EBF. Nature. 1995;376(6537):263–7.PubMedView ArticleGoogle Scholar
  169. Ramirez J, Lukin K, Hagman J. From hematopoietic progenitors to B cells: mechanisms of lineage restriction and commitment. Curr Opin Immunol. 2010;22(2):177–84.PubMedPubMed CentralView ArticleGoogle Scholar
  170. Cobaleda C, Schebesta A, Delogu A, Busslinger M. Pax5: the guardian of B cell identity and function. Nat Immunol. 2007;8(5):463–70.PubMedView ArticleGoogle Scholar
  171. Familiades J, Bousquet M, Lafage-Pochitaloff M, Bene MC, Beldjord K, De Vos J, et al. PAX5 mutations occur frequently in adult B-cell progenitor acute lymphoblastic leukemia and PAX5 haploinsufficiency is associated with BCR-ABL1 and TCF3-PBX1 fusion genes: a GRAALL study. Leukemia. 2009;23(11):1989–98.PubMedView ArticleGoogle Scholar
  172. Iacobucci I, Lonetti A, Paoloni F, Papayannidis C, Ferrari A, Storlazzi CT, et al. The PAX5 gene is frequently rearranged in BCR-ABL1-positive acute lymphoblastic leukemia but is not associated with outcome. A report on behalf of the GIMEMA acute leukemia working party. Haematologica. 2010;95(10):1683–90.PubMedPubMed CentralView ArticleGoogle Scholar
  173. Goga A, McLaughlin J, Afar DE, Saffran DC, Witte ON. Alternative signals to RAS for hematopoietic transformation by the BCR-ABL oncogene. Cell. 1995;82(6):981–8.PubMedView ArticleGoogle Scholar
  174. Rouault JP, Samarut C, Duret L, Tessa C, Samarut J, Magaud JP. Sequence analysis reveals that the BTG1 anti-proliferative gene is conserved throughout evolution in its coding and 3′ non-coding regions. Gene. 1993;129(2):303–6.PubMedView ArticleGoogle Scholar
  175. Iwai K, Hirata K, Ishida T, Takeuchi S, Hirase T, Rikitake Y, et al. An anti-proliferative gene BTG1 regulates angiogenesis in vitro. Biochem Biophys Res Commun. 2004;316(3):628–35.PubMedView ArticleGoogle Scholar
  176. Xie J, Wang Q, Wang Q, Yao H, Wen L, Ma L, et al. High frequency of BTG1 deletions in patients with BCR-ABL1-positive acute leukemia. Cancer Genet. 2014;207(5):226–30.PubMedView ArticleGoogle Scholar
  177. Waanders E, Scheijen B, van der Meer LT, van Reijmersdal SV, van Emst L, Kroeze Y, et al. The origin and nature of tightly clustered BTG1 deletions in precursor B-cell acute lymphoblastic leukemia support a model of multiclonal evolution. PLoS Genet. 2012;8(2):e1002533.PubMedPubMed CentralView ArticleGoogle Scholar
  178. van Galen JC, Kuiper RP, van Emst L, Levers M, Tijchon E, Scheijen B, et al. BTG1 regulates glucocorticoid receptor autoinduction in acute lymphoblastic leukemia. Blood. 2010;115(23):4810–9.PubMedView ArticleGoogle Scholar
  179. Zheng HC, Li J, Shen DF, Yang XF, Zhao S, Wu YZ, et al. BTG1 expression correlates with pathogenesis, aggressive behaviors and prognosis of gastric cancer: a potential target for gene therapy. Oncotarget. 2015;6:19685.PubMedPubMed CentralView ArticleGoogle Scholar
  180. Nacheva EP, Brazma D, Virgili A, Howard-Reeves J, Chanalaris A, Gancheva K, et al. Deletions of immunoglobulin heavy chain and T cell receptor gene regions are uniquely associated with lymphoid blast transformation of chronic myeloid leukemia. BMC Genom. 2010;11:41.View ArticleGoogle Scholar
  181. Chomel JC, Bonnet ML, Sorel N, Bertrand A, Meunier MC, Fichelson S, et al. Leukemic stem cell persistence in chronic myeloid leukemia patients with sustained undetectable molecular residual disease. Blood. 2011;118(13):3657–60.PubMedView ArticleGoogle Scholar
  182. Chu S, McDonald T, Lin A, Chakraborty S, Huang Q, Snyder DS, et al. Persistence of leukemia stem cells in chronic myelogenous leukemia patients in prolonged remission with imatinib treatment. Blood. 2011;118(20):5565–72.PubMedPubMed CentralView ArticleGoogle Scholar
  183. Graham SM, Jorgensen HG, Allan E, Pearson C, Alcorn MJ, Richmond L, et al. Primitive, quiescent, Philadelphia-positive stem cells from patients with chronic myeloid leukemia are insensitive to STI571 in vitro. Blood. 2002;99(1):319–25.PubMedView ArticleGoogle Scholar
  184. Chomel JC, Sorel N, Guilhot J, Guilhot F, Turhan AG. BCR-ABL expression in leukemic progenitors and primitive stem cells of patients with chronic myeloid leukemia. Blood. 2012;119(12):2964–5.PubMedView ArticleGoogle Scholar
  185. Chu S, Xu H, Shah NP, Snyder DS, Forman SJ, Sawyers CL, et al. Detection of BCR-ABL kinase mutations in CD34 + cells from chronic myelogenous leukemia patients in complete cytogenetic remission on imatinib mesylate treatment. Blood. 2005;105(5):2093–8.PubMedView ArticleGoogle Scholar
  186. Sorel N, Bonnet ML, Guillier M, Guilhot F, Brizard A, Turhan AG. Evidence of ABL-kinase domain mutations in highly purified primitive stem cell populations of patients with chronic myelogenous leukemia. Biochem Biophys Res Commun. 2004;323(3):728–30.PubMedView ArticleGoogle Scholar
  187. Soverini S, Colarossi S, Gnani A, Rosti G, Castagnetti F, Poerio A, et al. Contribution of ABL kinase domain mutations to imatinib resistance in different subsets of Philadelphia-positive patients: by the GIMEMA Working Party on Chronic Myeloid Leukemia. Clin Cancer Res. 2006;12(24):7374–9.PubMedView ArticleGoogle Scholar
  188. O’Hare T, Eide CA, Deininger MW. Bcr-Abl kinase domain mutations, drug resistance, and the road to a cure for chronic myeloid leukemia. Blood. 2007;110(7):2242–9.PubMedView ArticleGoogle Scholar
  189. Peng C, Li D, Li S. Heat shock protein 90: a potential therapeutic target in leukemic progenitor and stem cells harboring mutant BCR-ABL resistant to kinase inhibitors. Cell Cycle. 2007;6(18):2227–31.PubMedView ArticleGoogle Scholar
  190. Khajapeer KV, Baskaran R. Hsp90 inhibitors for the treatment of chronic myeloid leukemia. Leuk Res Treat. 2015;2015:757694.Google Scholar
  191. Liu X, Kung A, Malinoski B, Prakash GK, Zhang C. Development of alkyne-containing pyrazolopyrimidines to overcome drug resistance of Bcr-Abl kinase. J Med Chem. 2015;58(23):9228–37.PubMedView ArticleGoogle Scholar
  192. Jabbour E, Kantarjian H. Chronic myeloid leukemia: 2016 update on diagnosis, therapy, and monitoring. Am J Hematol. 2016;91(2):252–65.PubMedView ArticleGoogle Scholar
  193. Biernaux C, Loos M, Sels A, Huez G, Stryckmans P. Detection of major bcr-abl gene expression at a very low level in blood cells of some healthy individuals. Blood. 1995;86(8):3118–22.PubMedGoogle Scholar
  194. Butt NM, Wang L, Abu-Eisha HM, Christmas SE, Clark RE. BCR-ABL-specific T cells can be detected in healthy donors and in chronic myeloid leukemia patients following allogeneic stem cell transplantation. Blood. 2004;103(8):3245.PubMedView ArticleGoogle Scholar
  195. Hanahan D, Weinberg RA. Hallmarks of cancer: the next generation. Cell. 2011;144(5):646–74.PubMedView ArticleGoogle Scholar
  196. Landau DA, Carter SL, Getz G, Wu CJ. Clonal evolution in hematological malignancies and therapeutic implications. Leukemia. 2014;28(1):34–43.PubMedPubMed CentralView ArticleGoogle Scholar
  197. Hainaut P, Plymoth A. Targeting the hallmarks of cancer: towards a rational approach to next-generation cancer therapy. Curr Opin Oncol. 2013;25(1):50–1.PubMedView ArticleGoogle Scholar
  198. Mullighan CG, Goorha S, Radtke I, Miller CB, Coustan-Smith E, Dalton JD, et al. Genome-wide analysis of genetic alterations in acute lymphoblastic leukaemia. Nature. 2007;446(7137):758–64.PubMedView ArticleGoogle Scholar

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