The mechanisms by which AML1/ETO (A/E) fusion protein induces leukemogenesis in acute myeloid leukemia (AML) without mutagenic events remain elusive. Here we show that interactions between A/E and hypoxia-inducible factor 1α (HIF1α) are sufficient to prime leukemia cells for subsequent aggressive growth. In agreement with this, HIF1α is highly expressed in A/E-positive AML patients and strongly predicts inferior outcomes, regardless of gene mutations. Co-expression of A/E and HIF1α in leukemia cells causes a higher cell proliferation rate in vitro and more serious leukemic status in mice. Mechanistically, A/E and HIF1α form a positive regulatory circuit and cooperate to transactivate DNMT3a gene leading to DNA hypermethylation. Pharmacological or genetic interventions in the A/E-HIF1α loop results in DNA hypomethylation, a re-expression of hypermethylated tumor-suppressor p15(INK4b) and the blockage of leukemia growth. Thus high HIF1α expression serves as a reliable marker, which identifies patients with a poor prognosis in an otherwise prognostically favorable AML group and represents an innovative therapeutic target in high-risk A/E-driven leukemia.
Intermediate-risk acute myeloid leukemia (IR-AML), which accounts for a substantial number of AML cases, is highly heterogeneous. Although several mutations have been identified, the heterogeneity of AML is uncertain because novel mutations have yet to be discovered. Here we applied next generation sequencing (NGS) platform to screen mutational hotspots in 410 genes relevant to hematological malignancy. IR-AML samples (N=95) were sequenced by Illumina Hiseq and mutations in 101 genes were identified. Only seven genes (CEBPA, NPM1, DNMT3A, FLT3-ITD, NRAS, IDH2 and WT1) were mutated in more than 10% of patients. Genetic interaction analysis identified several cooperative and exclusive patterns of overlapping mutations. Mutational analysis indicated some correlation between genotype and phenotype. FLT3-ITD mutations were identified as independent factors of poor prognosis, while CEBPA mutations were independent favorable factors. Co-occurrence of FLT3-ITD, NPM1 and DNMT3A mutations was identified with associated with specific clinical AML features and poor outcomes. Furthermore, by integrating multiple mutations in the survival analysis, 95 IR-AML patients could be stratified into three distinct risk groups allowing reductions in IR-AML by one-third. Our study offers deep insights into the molecular pathogenesis and biology of AML and indicated that the prognosis of IR-AML could be further stratified by different mutation combinations which may direct future treatment intervention.
The t(8;21)(q22;q22) translocation, resulting in a chimeric protein AML1/ETO (A/E), is one of the most common chromosomal abnormalities in acute myeloid leukemia (AML). It has been reported that additional mutagenic “hits” are required for A/E to be a leukemic driver, but it is unclear why most A/E-positive patients don’t carry such gene mutations. We hypothesized that unconventional and more universal events might cooperate with A/E to drive leukemogenesis. Hypoxia inducible factor 1a (HIF1a) is a transcription factor mediating the cellular response to hypoxia in malignant cells. To identify the key molecule responsible for A/E-driven leukemia, we focused on HIF1a signaling, as it is selectively activated in AML stem cells in a hypoxia-independent fashion. Using qPCR analysis, we measured HIF1a mRNA levels in bone marrow mononuclear cells from 73 A/E-positive and 59 A/E-negative patients with newly diagnosed AML and 15 healthy donors. HIF1a was highly expressed in A/E-positive patients, as compared to A/E-negative patients and healthy controls. The expression of HIF1a was positively correlated with the expression of A/E, independent of KIT mutation. Patients were grouped into quartiles according to HIF1a expression levels (Q1-Q4, each quartile containing 25% of patients) and divided into high HIF1a (HIF1a high, Q4; n = 33) and low HIF1a (HIF1a low, Q1-Q3; n = 99). AE-positive patients with high HIF1a expression had a significantly shorter OS (median = 19.0 months vs. not reached, P = 0.015) and EFS (median = 9.0 months vs. 24.0 months, P = 0.001) compared to those with low HIF1a expression. Notably, HIF1a-associated inferior prognosis in A/E-positive patients was KIT mutation-independent. In patients carrying wild-type KIT [n = 53, about 73% (53/73) of the entire A/E-patients], those with high HIF1a levels had a shorter OS (median = 23.1 months vs. not reached, P = 0.008) and EFS (median = 9.4 months vs. not reached, P = 0.001) than those with low HIF1a levels. Multivariate analysis revealed that high HIF1a levels were independent prognostic indicators for both OS and EFS (P = 0.014, HR = 3.574 and P = 0.004, HR = 4.304, respectively) in AE-positive patients. Mechanistic studies revealed that A/E and HIF1a formed a positive regulatory circuit, in which A/E bound to HIF1a gene promoter and transactivated HIF1a or vice versa. Co-expression of AE and HIF1a in leukemia cells caused a higher cell proliferation rate in vitro and more serious leukemic status in mice. To gain insight into the molecular basis of A/E-HIF1a functional cooperation in leukemogenesis, we examined the mRNA levels of DNMT1, DNMT3a and DNMT3b expression in bone marrow samples from above-mentioned AML patients and healthy donors using qPCR. The result showed that DNMT3a, but not DNMT1 and DNMT3b, was significantly overexpressed in A/E-positive patients, as compared to A/E-negative patients and healthy donors. DNMT3a levels were positively correlated with both A/E and HIF1a levels. We therefore focused on evaluating the role of DNMT3a in A/E-positive AML. We found that DNMT3a expression was positively correlated with both A/E and HIF1a levels. As an individual event, A/E or HIF1a was enriched on DNMT3a gene promoter and synergistically increased DNMT3a transcription and enhanced global DNA methylation. Pharmacological or genetic interventions in the AE-HIF1a loop resulted in DNA hypomethylation, a reexpression of hypermethylated tumor suppressor p15INK4band the blockage of leukemia growth. In summary, we showed that A/E and HIF1a form a regulatory circuit and cooperatively control aggressive leukemia growth through DNMT3a transactivation and subsequent DNA hypermethylation. Thus, the HIF1a-DNMT3a nexus serves as a reliable marker, which identifies patients with a poor prognosis in an otherwise prognostically favorable AML group, and represents an innovative therapeutic target in high-risk AE-positive leukemia. Disclosures No relevant conflicts of interest to declare.
The reason that a certain subgroup of acute myeloid leukemia (AML) patients with t(8;21) translocation (generating the AML1/ETO fusion gene) displays a poor survival remains elusive. The proto-oncogene c-kit is expressed in approximately 80% of AML cases. The kinase domain mutation of the c-kit gene, one of the most common gain-of-function mutations associated with t(8;21) AML, predicts higher relapse risk and poor prognosis. However, the role of c-kit high expression in t(8;21) AML remains poorly understood. Here we evaluated the prognostic significance of c-kit expression levels in AML patients. The mRNA expression of c-kit was determined by real-time quantitative reverse transcription PCR in 132 adult AML patients. Patients were grouped into quartiles according to c-kit expression levels (Q1–Q4, each quartile containing 25% of patients) and divided into c-kit high (Q4; n = 33) and c-kit low (Q1–Q3; n = 99). High c-kit expression was associated with AML1/ETO-positive and with c-kit mutation. Of note, 35.8% of the AML1/ETO-positive AML patients carrying wild-type c-kit expressed high levels of c-kit, suggesting that other factors are involved in c-kit overexpression. High c-kit expression was associated with inferior overall and event-free survival in AML1/ETO-positive patients and was independently predictive for overall and event-free survival in multivariate analyses in a c-kit mutation-independent manner. Thus, high c-kit expression serves as a reliable molecular marker for poor prognosis, supporting a pathogenetic role of c-kit signaling in AML1/ETO-positive AML. AML1/ETO-positive patients with high c-kit expression might benefit from early treatment modifications and molecular target therapies.
MicroRNA-9-1(miR-9-1) plays an important role in the mechanism that regulates the lineage fate of differentiating hematopoietic cells. Recent studies have shown that miR-9-1 is downregulated in t (8; 21) AML. However, the pathogenic mechanisms underlying miR-9-1 downregulation and the RUNX1-RUNX1T1 fusion protein, generated from the translocation of t (8; 21) in AML, remain unclear. RUNX1-RUNX1T1 can induce leukemogenesis through resides in and functions as a stable RUNX1-RUNX1T1-containing transcription factor complex. In this study, we demonstrate that miR-9-1 expression increases significantly after the treatment of RUNX1-RUNX1T1 (+) AML cell lines with decitabine (a DNMT inhibitor) and trichostatin A (an HDAC inhibitor). In addition, we show that RUNX1-RUNX1T1 triggers the heterochromatic silencing of miR-9-1 by binding to RUNX1-binding sites in the promoter region of miR-9-1 and recruiting chromatin-remodeling enzymes, DNMTs, and HDACs, contributing to hypermethylation of miR-9-1 in t (8; 21) AML. Furthermore, because RUNX1, RUNX1T1, and RUNX1-RUNX1T1 are all regulated by miR-9-1, the silencing of miR-9-1 enhances the oncogenic activity of these genes. Besides, overexpression of miR-9-1 induces differentiation and inhibits proliferation in t (8; 21) AML cell lines. In conclusion, our results indicate a feedback circuitry involving miR-9-1 and RUNX1-RUNX1T1, contributing to leukemogenesis in RUNX1-RUNX1T1 (+) AML cell lines.
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