Transposon mutagenesis reveals cooperation of ETS family transcription factors with signaling pathways in erythro-megakaryocytic leukemia

Tang, Jian; Carmichael, Catherine; Shi, Wei; Metcalf, Donald; Ng, Ashley P.; Hyland, Craig D.; Jenkins, Nancy A.; Copeland, Neal G.; Howell, Viive M.; Zhao, Zhizhuang Joe; Smyth, Gordon K.; Kile, Benjamin T.; Alexander, Warren S.

doi:10.1073/pnas.1304234110

Cited by 19 publications

(16 citation statements)

References 37 publications

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“…Conversely, the numbers of GMPs and bipotential megakaryocyte-erythroid progenitor populations (BEMP, CD150 + CD9 hi , CD150 + FcγR + ) were reduced in Erg +/Mld2 mice haploinsufficient for functional Erg . Trisomic Ts65Dn/Erg +/+/+ mice were noted to have significantly fewer CFU-E, an anomaly that was not evident in Ts65Dn/Erg +/+/Mld2 mice and Erg +/Mld2 mice had an expanded population of these late erythroid progenitors, supporting previous data that suggested Erg normally restrains terminal erythroid differentiation [ 22 , 24 , 25 ]. Consistent with the immunophenotypic analyses, in clonogenic assays, Ts65Dn/Erg +/+/+ bone marrow demonstrated stimuli-specific increases in the numbers of granulocyte, macrophage and megakaryocyte colony-forming units (CFU).…”

Section: Resultssupporting

confidence: 79%

“…This finding is consistent with changes in human DS foetal livers [ 15 ] and other independent murine models of Erg overexpression [ 24 , 40 ]. Indeed, aberrant megakaryocyte-erythroid differentiation and erythroid maturation block may be a potential unifying mechanism for Erg in predisposing to acute bipotential megakaryocytic-erythroid leukemia [ 25 ]. The selective expansion of CD150 + CD9 hi cells within bipotential megakaryocyte-erythroid progenitor compartment in Ts(17 16 )65Dn mice is similar to that observed in murine models of thrombopoietin driven myeloproliferation [ 33 , 34 ], providing additional evidence that this progenitor population correlates with the degree of megakaryocytosis in disease models.…”

Section: Discussionmentioning

confidence: 99%

“…Erg has previously been shown to be essential for normal hematopoietic stem cell function [ 21 – 23 ]. Moreover, Erg deregulation can cause erythro-megakaryocytic leukemia in mice [ 24 , 25 ], and is implicated in acute myeloid and lymphoid malignancy in humans. In t(16;21) AML that carry the ERG/TLS-FUS fusion, complex karyotype AML with amplification of 21q, normal karyotype adult AML, MLL -rearranged paediatric AML and in T-ALL, high levels of ERG expression correlate with poor prognosis [ 26 – 29 ].…”

Section: Introductionmentioning

confidence: 99%

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Early Lineage Priming by Trisomy of Erg Leads to Myeloproliferation in a Down Syndrome Model

Metcalf

et al. 2015

PLoS Genet

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Down syndrome (DS), with trisomy of chromosome 21 (HSA21), is the commonest human aneuploidy. Pre-leukemic myeloproliferative changes in DS foetal livers precede the acquisition of GATA1 mutations, transient myeloproliferative disorder (DS-TMD) and acute megakaryocytic leukemia (DS-AMKL). Trisomy of the Erg gene is required for myeloproliferation in the Ts(1716)65Dn DS mouse model. We demonstrate here that genetic changes specifically attributable to trisomy of Erg lead to lineage priming of primitive and early multipotential progenitor cells in Ts(1716)65Dn mice, excess megakaryocyte-erythroid progenitors, and malignant myeloproliferation. Gene expression changes dependent on trisomy of Erg in Ts(1716)65Dn multilineage progenitor cells were correlated with those associated with trisomy of HSA21 in human DS hematopoietic stem and primitive progenitor cells. These data suggest a role for ERG as a regulator of hematopoietic lineage potential, and that trisomy of ERG in the context of DS foetal liver hemopoiesis drives the pre-leukemic changes that predispose to subsequent DS-TMD and DS-AMKL.

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Section: Resultssupporting

confidence: 79%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Early Lineage Priming by Trisomy of Erg Leads to Myeloproliferation in a Down Syndrome Model

Metcalf

et al. 2015

PLoS Genet

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“…Another 110 CCGs, including Flt3 and Runx1 , have human orthologs with mutations identified by exome or WGS 19 in at least one AML genome (P = 3.5 x 10 −7 , Bonferroni corrected). Notably, many CCGs overlapped with human AML CCGs that fall within the long-tail regions of nonsynonymous coding mutations identified by the Cancer Genome Atlas for AML 19 and with CCGs identified in two different mouse models of leukemia that also used SB mutagenesis 20,21 (Supplementary Note). We conclude from these findings that SB captures the genes mutated by the diversity of mutational processes in human AML.…”

Section: Resultsmentioning

confidence: 97%

Analyzing tumor heterogeneity and driver genes in single myeloid leukemia cells with SBCapSeq

et al. 2016

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A central challenge in oncology is how to kill tumors containing heterogeneous cell populations defined by different combinations of mutated genes. Identifying these mutated genes and understanding how they cooperate requires single-cell analysis, but current single-cell analytic methods, such as PCR-based strategies or whole-exome sequencing, are biased, lack sequencing depth or are cost prohibitive. Transposon-based mutagenesis allows the identification of early cancer drivers, but current sequencing methods have limitations that prevent single-cell analysis. We report a liquid-phase, capture-based sequencing and bioinformatics pipeline, Sleeping Beauty (SB) capture hybridization sequencing (SBCapSeq), that facilitates sequencing of transposon insertion sites from single tumor cells in a SB mouse model of myeloid leukemia (ML). SBCapSeq analysis of just 26 cells from one tumor revealed the tumor’s major clonal subpopulations, enabled detection of clonal insertion events not detected by other sequencing methods and led to the identification of dominant subclones, each containing a unique pair of interacting gene drivers along with three to six cooperating cancer genes with SB-driven expression changes.

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“…Currently the Sleeping Beauty transposon system (described below in detail) has been used to study a wide range of cancers. This included T-cell acute lymphoblastic lymphoma (T-ALL), colorectal carcinoma, malignant peripheral nerve sheath tumors, hepatocellular carcinoma (HCC), glioblastoma multiforme (GBM), pancreatic cancer, medulloblastoma, B-cell precursor acute lymphoblastic leukemia, chronic lymphocytic leukemia, and erythroleukemia [8,31,[35][36][37][38][39][40][41]. While Sleeping Beauty can be sufficient for tumor formation in some tissues of wild type mice, it is not always sufficient [28].…”

Section: Sleeping Beauty Models Of Cancermentioning

confidence: 99%

A computational approach for comparative oncogenomics using mouse models

Brett¹

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Transposon mutagenesis reveals cooperation of ETS family transcription factors with signaling pathways in erythro-megakaryocytic leukemia

Cited by 19 publications

References 37 publications

Early Lineage Priming by Trisomy of Erg Leads to Myeloproliferation in a Down Syndrome Model

Early Lineage Priming by Trisomy of Erg Leads to Myeloproliferation in a Down Syndrome Model

Analyzing tumor heterogeneity and driver genes in single myeloid leukemia cells with SBCapSeq

A computational approach for comparative oncogenomics using mouse models

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