A single promoter CpG demethylation induced by eicosapentaenoic acid is essential for tumor suppressor C/EBPδ expression in U937 leukemia cells

Abstract Introduction CEBPA gene encodes CCAAT/enhancer-binding protein-alpha (C/EBPα), a crucial granulocytic differentiation factor and tumor suppressor in hematologic and non-hematologic malignancies. CEBPA gene is mutated in approximately 5–14% of acute myeloid leukemia (AML) patients and exhibited 3 different types of mutations, germ-line N-terminal mutation, N-terminal frameshift mutation and C-terminal mutation. Although murine models provide the functional consequences of CEBPA gene mutations in human hematopoiesis, the impacts of different mutations on abrogating C/EBPα functions and those of germ-line N-terminal mutations on bone marrow microenvironment have been received less attention. Methods In our previous research, we have provided the first report of multiple mutations of CEBPA contributing to the transformation of donor cells to the leukemic phenotype after allogeneic hematopoietic stem cell transplantation and identified 3 different CEBPA gene mutant forms which disrupted 3 major functional domains of C/EBPα respectively (H Xiao, Blood 2011; 117: 5257-5260). The patient and his donor-sister both harbored the N-terminal germ-line mutation (584_589dup disrupting the TAD2 domain of protein). Susceptible donor hematopoietic cells evolved to overt AML by developing two somatic CEBPA mutations, the N-terminal frameshift mutation (247dupC causing overproduction of truncated 30-KDa isoform (C/EBPα- p30) lacking the TAD1 domain) and the C-terminal mutation (914_916dup disrupting the bZIP domain), in the patient's microenvironment. We used these 3 mutant forms, as well as CEBPA gene wild type to subclone into pLenti6.3-MSC vector. Human leukemia cell lines (NB4, Kasumi-1, HL60, K562) and mouse myeloid progenitor cell line (32Dcl3) were transduced by different mutant forms to assess the impacts on blockage the major functions of C/EBPα including antileukemia effect and inducing granulocyte differentiation. To further discover previously unkown tumor suppressor genes dysregulated by C/EBPα mutant forms, the gene expression profiles of NB4 cells stably transfected with CEBPA gene different mutant forms were compared with that of CEBPA gene wild type vector by using Affymetrix PrimeView human gene expression microarray analysis. On the other hand, human normal bone marrow mesenchymal stromal cell ( MSC ) was transduced by N-terminal germ-line mutation to assess the impacts on the capacity of MSC to differentiate towards the osteogenic/adipogenic lineages, migrate and protect to leukemia cells. Results (1) The N-terminal germ-line mutation retains the functions of inducing apoptosis in leukemic cells and granulocyte differentiation of C/EBPα.The truncated C/EBPα-p30 protein mutant, produced from the N-terminal frameshift mutation, abrogates the effect of inducing apoptosis in leukemia cells. The C-terminal mutation (914_916 dup) abrogates both the effects of inducing apoptosis in leukemic cells and of promoting G-CSF-induced differentiation of 32Dcl3 cells into mature neutrophile granulocyte. (2) Gene expression microarray profiling analysis showed that compared with CEBPA gene wild type, leukemia-associated CEBPA somatic mutations, the N-terminal frameshift mutation and the C-terminal mutation, significantly inhibited the expression of ULBP2, an innate surface ligand of the natural killer (NK) cell receptor NKG2D, ultimately contributed to resistance to NK cell-mediated cytotoxicity. (3) MSCs harboring CEBPA N-terminal germ-line mutation showed impaired differentiation potential to osteogenic lineage by downregulation the expression of osteogenic genes (BSP1 and Runx2) , however similar in differentiation potential to adipogenic lineage, migration and the protection to leukemia cells, compared with MSCs with CEBPA wild type. Conclusions Our data provide clues to support that the N-terminal frameshift mutation of CEBPA works as a class I mutation, while the C-terminal mutation works as both of class I and class II mutations in inducing leukemia. Furthermore, those leukemia-associated CEBPA somatic mutations abrogate the tumor suppressor function of C/EBPα by inhibiting NKG2D-mediated NK cell cytotoxicity. The N-terminal germ-line mutation retains the major functions of C/EBPα, however impaired the osteogenic differentiation potential of bone marrow stromal cells, which is important to support hematopoiesis. Disclosures: No relevant conflicts of interest to declare.

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RASSF2 Functions As a Tumor Suppressor in t(8;21) AML Via Promotion of Apoptosis

Blood ◽

10.1182/blood.v124.21.3590.3590 ◽

2014 ◽

Vol 124 (21) ◽

pp. 3590-3590

Author(s):

Samuel A Stoner ◽

Russell Dekelver ◽

Miao-Chia Lo ◽

Dong-Er Zhang

Keyword(s):

Gene Expression ◽

Tumor Suppressor ◽

Cell Lines ◽

Hematopoietic Cells ◽

Leukemia Cell ◽

Leukemia Cells ◽

Mrna Levels ◽

Human Cd34 ◽

Leukemia Cell Lines ◽

Cd34 Cells

Abstract The t(8;21) chromosomal translocation is one of the most common chromosomal translocations associated with acute myeloid leukemia (AML), found in approximately 12% of de novo AML cases. The majority of these cases are classified as FAB-subtype M2 AML. The t(8;21) results in the stable fusion of the AML1 (RUNX1) and ETO (RUNX1T1) genes. The AML1-ETO fusion protein is composed of the N-terminal portion of AML1, which includes the DNA-binding Runt-homology domain, and nearly the full-length ETO protein. The primary accepted mechanism by which AML1-ETO promotes leukemia development is through the aberrant recruitment of transcriptional repression/activation complexes to normal AML1 target genes. Therefore, the identification of individual genes or biological pathways that are specifically disrupted in the presence of AML1-ETO will provide further molecular insight into the pathogenesis of t(8;21) AML and lead to the possibility for improved treatment for these patients. We identified RASSF2 as a gene that is specifically downregulated in (2-4 fold) in total bone marrow of t(8;21) patients compared to non-t(8;21) FAB-subtype M2 AML patients by analyzing publicly available gene expression datasets. Similarly, using a mouse model of t(8;21) AML we found Rassf2 mRNA levels to be nearly 30-fold lower in t(8;21) leukemia cells compared to wild-type Lin-Sca-cKit+ (LK) myeloid progenitors. Gene expression analysis by RT-qPCR in leukemia cell lines confirmed that RASSF2 mRNA levels are significantly downregulated (8-10-fold) in both Kasumi-1 and SKNO-1 t(8;21) cell lines as compared to a similar non-t(8;21) HL-60 cell line and to primary human CD34+ control cells. In addition, expression of AML1-ETO in HL-60 or CD34+ cells results in a decrease in RASSF2 mRNA expression, which further suggests that RASSF2 is a target for regulation by AML1-ETO. Assessment of published ChIP-seq data shows that AML1-ETO binds the RASSF2 gene locus at two distinct regions in both primary t(8;21) AML patient samples and in the Kasumi-1 and SKNO-1 cell lines. These regions are similarly bound by several important hematopoietic transcription factors in primary human CD34+ cells, including AML1, ERG, FLI1, and TCF7L2, implicating these two regions as important for the regulation of RASSF2 expression during blood cell differentiation. Overexpression of RASSF2 in human leukemia cell lines using an MSCV-IRES-GFP (MIG) construct revealed that RASSF2 has a strong negative effect on leukemia cell proliferation and viability. The overall percentage of GFP-positive cells in MIG-RASSF2 transduced cells markedly decreased compared to MIG-control transduced cells over a period of 14 days. This effect was primarily due to significantly increased apoptosis in the RASSF2 expressing cell populations. Similarly, we found that expression of RASSF2 significantly inhibits the long-term self-renewal capability of hematopoietic cells transduced with AML1-ETO in a serial replating/colony formation assay. AML1-ETO transduced hematopoietic cells were normally capable of serial replating for more than 6 weeks. However, AML1-ETO transduced cells co-expressing RASSF2 consistently had reduced colony number and lost their ability to replate after 3-4 weeks. This was due to a dramatically increased rate of apoptosis in RASSF2 expressing cells. RASSF2 is reported to be a tumor suppressor that is frequently downregulated at the transcriptional level by hypermethylation in primary tumor samples, but not healthy controls. Here we have identified RASSF2 as a target for repression, and demonstrated its tumor suppressive function in t(8;21) leukemia cells. Further insights into the molecular mechanisms of RASSF2 function in AML will continue to be explored. Disclosures No relevant conflicts of interest to declare.

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