A Novel Complex, RUNX1-MYEF2, Represses Hematopoietic Genes in Erythroid Cells

Riel, Boet van; Pakozdi, Tibor; Brouwer, Rutger W. W.; Monteiro, Rui; Tuladhar, Kapil; Franke, Vedran; Bryne, Jan Christian; Jorna, Ruud; Rijkers, Erik Jan; IJcken, Wilfred F. J. van; Andrieu-Soler, Charlotte; Demmers, Jeroen; Patient, Roger; Soler, Éric; Lenhard, Boris; Grosveld, Frank

doi:10.1128/mcb.05938-11

Cited by 33 publications

(28 citation statements)

References 56 publications

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Section: Gr1 Double-positive Cells (mentioning

confidence: 90%

“…4 of these genes (CD53, 20 Cpa3, 20 ItgaL,21,22 Mpo 23,24 ) are targets of RUNX1 and many of these genes are deregulated in other models of impaired RUNX1 activity. 4,25,26 These findings imply that at least some of the gene expression changes induced by CBF␤-SMMHC⌬C95 are because of altered RUNX1 activity.The data presented here demonstrate that the C-terminal 95 amino acids are critical for CBF␤-SMMHC's activities, particularly leukemogenesis. Blocking the function of this region in the fusion protein may be a potential therapeutic strategy in the future for the treatment of Inv16 AML.…”

mentioning

confidence: 90%

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The C-terminus of CBFβ-SMMHC is required to induce embryonic hematopoietic defects and leukemogenesis

Kamikubo¹,

Hyde²,

Zhao³

et al. 2013

Blood

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• Heterozygous CBF␤-SMMHC⌬C95 knock-in mice have normal hematopoiesis.• Heterozygous CBF␤-SMMHC⌬C95 knock-in mice do not develop leukemia.The C-terminus of CBF␤-SMMHC, the fusion protein produced by a chromosome 16 inversion in acute myeloid leukemia subtype M4Eo, contains domains for selfmultimerization and transcriptional repression, both of which have been proposed to be important for leukemogenesis by CBF␤-SMMHC. To test the role of the fusion protein's C-terminus in vivo, we generated knock-in mice expressing a C-terminally truncated CBF␤-SMMHC (CBF␤-SMMHC⌬C95). Embryos with a single copy of CBF␤-SMMHC⌬C95 were viable and showed no defects in hematopoiesis, whereas embryos homozygous for the CBF␤-SMMHC⌬C95 allele had hematopoietic defects and died in mid-gestation, similar to embryos with a single-copy of the full-length CBF␤-SMMHC. Importantly, unlike mice expressing full-length CBF␤-SMMHC, none of the mice expressing CBF␤-SMMHC⌬C95 developed leukemia, even after treatment with a mutagen, although some of the older mice developed a nontransplantable myeloproliferative disease. Our data indicate that the CBF␤-SMMHC's C-terminus is essential to induce embryonic hematopoietic defects and leukemogenesis. (Blood. 2013;121(4):638-642) IntroductionInversion 16 (Inv16) results in the fusion of the transcription factor gene, CBFB, and MYH11, which encodes smooth muscle myosin heavy chain (SMMHC). 1 Expression of CBF␤-SMMHC is probably the initiating event in Inv16 AML 2 ; however, its mechanism is not well understood.Previously, we generated knock-in mice expressing Cbfb-MYH11 3 to address the role of the fusion gene in vivo. Mice expressing a single allele of the fusion gene (Cbfb ϩ/MYH11 ) showed defective primitive hematopoiesis, blocked definitive hematopoiesis, and embryonic lethality. 3,4 Interestingly, except for the primitive hematopoietic defect, this phenotype is indistinguishable from mice lacking functional Cbfb 5-7 or its dimerization partner Runx1, 8,9 implying that Cbfb-MYH11 has dominant negative activities. Importantly, nearly 100% of the Cbfb-MYH11 mice develop AML within 6 months after treatment with a mutagen. 2,10 This demonstrates that expression of Cbfb-MYH11 is necessary, but not sufficient for AML.The C-terminus of CBF␤-SMMHC consists of repeated ␣-helical rod domains that facilitate self-dimerization and multimerization. [11][12][13] Work in myeloid cells indicates CBF␤-SMMHC's ability to form multimers correlates with its ability to repress proliferation and transcription. 12,13 In addition, CBF␤-SMMHC C-terminus can interact with transcriptional corepressors, 14,15 providing a possible mechanism for its dominant negative effects on transcriptional regulation by CBF␤/RUNX1. CBF␤-SMMHC multimerization and transcriptional repression are potential mechanisms for leukemogenesis, implying that the C-terminal region is critically important. To test the requirement of this region in vivo, we generated knock-in mice expressing a truncated Cbfb-MYH11 that encodes a CBF␤-SMMHC fusion protein missin...

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Section: Gr1 Double-positive Cells (mentioning

confidence: 90%

mentioning

confidence: 90%

The C-terminus of CBFβ-SMMHC is required to induce embryonic hematopoietic defects and leukemogenesis

Kamikubo¹,

Hyde²,

Zhao³

et al. 2013

Blood

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“…Our results show for the first time that GATA2 is required for HSC generation in the AGM and continues to be required for HSC survival. GATA2 is thought to act in combination with other transcription factors, such as RUNX1, to promote/ enhance transcription of genes relevant to hematopoietic cell development and growth (Wilson et al, 2010;van Riel et al, 2012). Because we used the Vec-Cre and Vav-Cre cKO approach used previously for Runx1 deletion (Chen et al, 2009), the requirements for these two transcription factors can be directly compared.…”

Section: Methodsmentioning

confidence: 99%

“…Yet, it is unknown whether GATA2 is required in the endothelial compartment for the formation of intra-arterial clusters and AGM HSCs, and what the function of GATA2 is thereafter. Furthermore, GATA factors are described to act through combinatory interactions with other key regulators, including RUNX1 (Wilson et al, 2010;van Riel et al, 2012). Previously, RUNX1 was shown to be required for the generation of HSCs during the endothelial-to-hematopoietic transition (EHT).…”

Section: Brief Definitive Reportmentioning

confidence: 99%

GATA2 is required for HSC generation and survival

Pater

Kaimakis

Vink

et al. 2013

Experimental Hematology

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“…For example, several essential myeloid lineage growth factor receptor genes, such as those encoding the M-CSFR and GM-GSFRα, are regulated by a PU.1 collaboration with C/EBPα (Hohaus et al, 1995;Li et al, 2005). Runx1 is a critical factor for the development of the definitive HSC pool and also has a role in the specification of some hematopoietic lineages (Wang et al, 1996;van Riel et al, 2012). Similar to the PU.1-C/EBPα complex, PU.1 also collaborates with Runx1 to activate transcription of the Csf1r gene encoding the M-CSF receptor (Li et al, 2005).…”

Section: Pu1 Cross-talk With Other Lineagespecific Transcription Facmentioning

confidence: 99%

Epigenetic control of hematopoiesis: the PU.1 chromatin connection

Riel

Rosenbauer

2014

Biological Chemistry

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Purine-rich box1 (PU.1) is a transcription factor that not only has a key role in the development of most hematopoietic cell lineages but also in the suppression of leukemia. To exert these functions, PU.1 can cross-talk with multiple different proteins by forming complexes in order to activate or repress transcription. Among its protein partners are chromatin remodelers, DNA methyltransferases, and a number of other transcription factors with important roles in hematopoiesis. While a great deal of knowledge has been acquired about PU.1 function over the years, it was the development of novel genome-wide technologies, which boosted our understanding of how PU.1 acts on the chromatin to drive its repertoire of target genes. This review summarizes current knowledge and ideas of molecular mechanisms by which PU.1 controls hematopoiesis and suppresses leukemia.

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A Novel Complex, RUNX1-MYEF2, Represses Hematopoietic Genes in Erythroid Cells

Cited by 33 publications

References 56 publications

The C-terminus of CBFβ-SMMHC is required to induce embryonic hematopoietic defects and leukemogenesis

The C-terminus of CBFβ-SMMHC is required to induce embryonic hematopoietic defects and leukemogenesis

GATA2 is required for HSC generation and survival

Epigenetic control of hematopoiesis: the PU.1 chromatin connection

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