EVI1-Positive AML Cells Show Distinct Features and High Dependency on ETS Transcription Factor ERG

Inappropriate expression of Ecotropic viral integration site 1 (EVI1) has been associated with dismal clinical outcomes in acute myeloid leukemia (AML), while EVI1 is indispensable for normal hematopoiesis. We have previously reported that EVI1 expression is restricted to hematopoietic stem cell fraction and EVI1-expressing cells show robust long-term reconstitution capacity using Evi1-IRES-GFP knock-in (EVI1-GFP) mice, which enable us to track Evi1 expression on a single cell basis. In this study, we tried to elucidate the functional implication of EVI1 expression in AML using these mice. We generated murine EVI1-GFP AML model by retrovirally transducing MLL-AF9 or -ENL fusion gene into Lineage- Sca-1+ c-kit+ (LSK) cells from EVI1-GFP mice followed by transplantation into lethally irradiated syngeneic mice. Clonogenic and leukemogenic potentials of AML cells, especially leukemic cells with a granulocyte-macrophage progenitor phenotype (L-GMPs) from these mice, were compared according to GFP expression. Remarkably, GFP-positive L-GMPs tended to show lower colony-forming activity in semi-solid media and lower leukemia-initiating potential than GFP-negative L-GMPs. GFP-positive L-GMPs, however, induced a more aggressive form of AML, characterized by shorter survival in the secondary transplantation model. When EVI1-GFP AML mice underwent cytotoxic chemotherapy with cytarabine, the GFP-positive fraction was enriched during myelosuppression, indicating the survival advantage of EVI1-positive cells. To investigate the downstream target of EVI1, we employed murine EVI1-AML model, where murine hematopoietic cells exogenously expressing 3×FLAG-tagged EVI1 were transplanted into syngeneic mice. Using EVI1-AML cells, we performed chromatin-immunoprecipitation coupled to next-generation sequencing (ChIP-seq) by anti-FLAG tag antibody. To identify leukemia-specific targets of EVI1, the result was compared with the result of ChIP-seq obtained from 32D-cl3 murine hematopoietic progenitor cells with 3×FLAG tag inserted into 3'-end of the coding region of the EVI1 gene. Gene ontology analysis revealed that genes involved in immune processes are explicitly enriched in the leukemia samples. Among the list of EVI1-bound genes, we tried to refine functional downstream targets of EVI1, which are upregulated in murine EVI1-AML cells and of which expressions are positively correlated with EVI1. By combining the ChIP-seq data with murine transcriptome data that compare hematopoietic progenitor cells expressing empty-vector and EVI1+ AML cells, and public gene expression datasets of human AML (Valk et al. NEJM 2004), we picked out 18 genes as candidate EVI1 downstream genes. Functional screening using EVI1-AML cells and shRNAs against these genes revealed that silencing of ETS transcription factor ERG (ETS-related gene) markedly suppressed proliferation and colony-forming activity of EVI1-AML cells, as well as rendered them vulnerable to cytotoxic agents. Normal c-kit+ hematopoietic progenitor cells were less affected by shRNAs against ERG. By comparing MLL-ENL immortalized murine hematopoietic cells with high and low EVI1 expression, EVI1-high MLL-ENL cells showed higher ERG dependency than EVI1-low MLL-ENL cells. Pharmacological inhibition of ERG also led to marked inhibition of EVI1-AML cells and EVI1-high MLL-ENL cells. Finally, knockdown of ERG remarkably delayed AML development in bone marrow transplantation model of EVI1-AML and EVI1-expressing MLL-ENL AML. Our data suggest that EVI1-positive AML cells are characterized by an aggressive nature and resistance to cytotoxic agents, as well as low leukemia stem cell capacity. ERG would be a novel downstream target of EVI1, on which survival of EVI1-expressing AML cells depends. Disclosures Masamoto: Kyowa Hakko Kirin Co., Ltd.: Speakers Bureau; Chugai Pharmaceutical Company: Speakers Bureau; Bristol Myers Squibb: Speakers Bureau; Janssen Pharmaceutical K.K.: Speakers Bureau; Eisai Co., Ltd.: Speakers Bureau; ONO PHARMACEUTICAL CO., LTD.: Speakers Bureau; MSD K.K.: Speakers Bureau; Otsuka Pharmaceutical Co., Ltd.: Speakers Bureau; Takeda Pharmaceutical Company Limited.: Speakers Bureau; Nippon Shinyaku Co., Ltd.: Speakers Bureau; AbbVie GK: Speakers Bureau; SymBio Pharmaceuticals: Speakers Bureau. Kurokawa: Daiichi Sankyo Company.: Research Funding, Speakers Bureau; Eisai Co., Ltd.: Research Funding, Speakers Bureau; MSD K.K.: Research Funding, Speakers Bureau; Astellas Pharma Inc.: Research Funding, Speakers Bureau; Teijin Limited: Research Funding, Speakers Bureau; Nippon Shinyaku Co., Ltd.: Research Funding, Speakers Bureau; ONO PHARMACEUTICAL CO., LTD.: Research Funding, Speakers Bureau; Kyowa Hakko Kirin Co., Ltd.: Research Funding, Speakers Bureau; AbbVie GK: Research Funding, Speakers Bureau; Pfizer Japan Inc.: Research Funding, Speakers Bureau; Chugai Pharmaceutical Company: Research Funding, Speakers Bureau; Otsuka Pharmaceutical Co., Ltd.: Research Funding, Speakers Bureau; Takeda Pharmaceutical Company Limited.: Research Funding, Speakers Bureau; Sumitomo Dainippon Pharma Co., Ltd.: Research Funding, Speakers Bureau.

The Ets protein Pointed P1 represses Asense expression in type II neuroblasts by activating Tailless

Intermediate neural progenitors (INPs) boost the number and diversity of neurons generated from neural stem cells (NSCs) by undergoing transient proliferation. In the developing Drosophila brains, INPs are generated from type II neuroblasts (NBs). In order to maintain type II NB identity and their capability to produce INPs, the proneural protein Asense (Ase) needs to be silenced by the Ets transcription factor pointed P1 (PntP1), a master regulator of type II NB development. However, the molecular mechanisms underlying the PntP1-mediated suppression of Ase is still unclear. In this study, we utilized genetic and molecular approaches to determine the transcriptional property of PntP1 and identify the direct downstream effector of PntP1 and the cis- DNA elements that mediate the suppression of ase. Our results demonstrate that PntP1 directly activates the expression of the transcriptional repressor, Tailless (Tll), by binding to seven Ets-binding sites, and Tll in turn suppresses the expression of Ase in type II NBs by binding to two hexameric core half-site motifs. We further show that Tll provides positive feedback to maintain the expression of PntP1 and the identity of type II NBs. Thus, our study identifies a novel direct target of PntP1 and reveals mechanistic details of the specification and maintenance of the type II NB identity by PntP1.

ELK4-mediated lncRNA SNHG22 promotes gastric cancer progression through interacting with EZH2 and regulating miR-200c-3p/Notch1 axis

Long non-coding RNAs (lncRNAs) play important regulatory roles in the initiation and progression of various cancers. However, the biological roles and the potential mechanisms of lncRNAs in gastric cancers remain unclear. Here, we report that the expression of lncRNA SNHG22 (small nucleolar RNA host gene 22) was significantly increased in GC (Gastric Cancer) tissues and cells, which confers poor prognosis of patients. Knockdown of SNHG22 inhibited the proliferation and invasion ability of GC cells. Moreover, we identified that the transcriptional factor, ELK4 (ETS transcription factor ELK4), could promote SNHG22 expression in GC cells. In addition, using RNA pull-down followed MS assay, we found that SNHG22 directly bound to EZH2 (enhancer of zeste 2 polycomb repressive complex 2 subunit) to suppress the expression of tumor suppressor genes. At the same time, SNHG22 sponged miR-200c-3p to increase Notch1 (notch receptor 1) expression. Taken together, our findings demonstrated the role of SNHG22 on promoting proliferation and invasion of GC cells. And we revealed a new regulatory mechanism of SNHG22 in GC cells. SNHG22 is a promising lncRNA biomarker for diagnosis and prognosis and a potential target for GC treatment.

SPDEF expression associates with survival in triple negative breast cancer.

We mined published microarray data (1) to understand the most significant gene expression differences in the tumors of triple negative breast cancer patients based on survival at time of analysis: dead or alive. We observed significant transcriptome-wide differential expression of SAM pointed domain-containing ets transcription factor, encoded by SPDEF when comparing the primary tumors of triple negative breast cancer patients dead or alive. Importantly, SPDEF expression was significantly correlated with distant metastasis-free survival in basal subtype breast cancer, a molecular subtype sharing significant overlap with triple negative breast cancer. SPDEF may be of relevance as a biomarker or as a molecule of interest in understanding the etiology or progression of triple negative breast cancer.

Banana Lectin from Musa paradisiaca Is Mitogenic for Cow and Pig PBMC via IL-2 Pathway and ELF1

The aim of the study was to gain deeper insights in the potential of polyclonal stimulation of PBMC with banana lectin (BanLec) from Musa paradisiaca. BanLec induced a marked proliferative response in cow and pig PBMC, but was strongest in pigs, where it induced an even higher proliferation rate than Concanavalin A. Molecular processes associated with respective responses in porcine PBMC were examined with differential proteome analyses. Discovery proteomic experiments was applied to BanLec stimulated PBMC and cellular and secretome responses were analyzed with label free LC-MS/MS. In PBMC, 3955 proteins were identified. After polyclonal stimulation with BanLec, 459 proteins showed significantly changed abundance in PBMC. In respective PBMC secretomes, 2867 proteins were identified with 231 differentially expressed candidates as reaction to BanLec stimulation. The transcription factor “E74 like ETS transcription factor 1 (ELF1)” was solely enriched in BanLec stimulated PBMC. BanLec induced secretion of several immune regulators, amongst them positive regulators of activated T cell proliferation and Jak-STAT signaling pathway. Top changed immune proteins were CD226, CD27, IFNG, IL18, IL2, CXCL10, LAT, ICOS, IL2RA, LAG3, and CD300C. BanLec stimulates PBMC of cows and pigs polyclonally and induces IL2 pathway and further proinflammatory cytokines. Proteomics data are available via ProteomeXchange with identifier PXD027505.

Hyper-SUMOylation of ERG Is Essential for the Progression of Acute Myeloid Leukemia

Leukemia is a malignant disease of hematopoietic tissue characterized by the differentiation arrest and malignant proliferation of immature hematopoietic precursor cells in bone marrow. ERG (ETS-related gene) is an important member of the E26 transformation-specific (ETS) transcription factor family that plays a crucial role in physiological and pathological processes. However, the role of ERG and its modification in leukemia remains underexplored. In the present study, we stably knocked down or overexpressed ERG in leukemia cells and observed that ERG significantly promotes the proliferation and inhibits the differentiation of AML (acute myeloid leukemia) cells. Further experiments showed that ERG was primarily modified by SUMO2, which was deconjugated by SENP2. PML promotes the SUMOylation of ERG, enhancing its stability. Arsenic trioxide decreased the expression level of ERG, further promoting cell differentiation. Furthermore, the mutation of SUMO sites in ERG inhibited its ability to promote the proliferation and inhibit the differentiation of leukemia cells. Our results demonstrated the crucial role of ERG SUMOylation in the development of AML, providing powerful targeted therapeutic strategies for the clinical treatment of AML.

Acetylation of ELF5 suppresses breast cancer progression by promoting its degradation and targeting CCND1

E74-like ETS transcription factor 5 (ELF5) is involved in a wide spectrum of biological processes, e.g., mammogenesis and tumor progression. We have identified a list of p300-interacting proteins in human breast cancer cells. Among these, ELF5 was found to interact with p300 via acetylation, and the potential acetylation sites were identified as K130, K134, K143, K197, K228, and K245. Furthermore, an ELF5-specific deacetylase, SIRT6, was also identified. Acetylation of ELF5 promoted its ubiquitination and degradation, but was also essential for its antiproliferative effect against breast cancer, as overexpression of wild-type ELF5 and sustained acetylation-mimicking ELF5 mutant could inhibit the expression of its target gene CCND1. Taken together, the results demonstrated a novel regulation of ELF5 as well as shedding light on its important role in modulation of breast cancer progression.