Abstract
Specification and differentiation of the megakaryocyte and erythroid lineages from a common bipotential progenitor provides a well studied model to dissect binary cell fate decisions. To understand how the distinct megakaryocyte- and erythroid-specific gene programs arise, we have examined the transcriptional regulation of the megakaryocyte erythroid transcription factor GATA1. Hemopoietic-specific mouse (m)GATA1 expression requires the mGata1 enhancer mHS-3.5. Within mHS-3.5, the 3' 179 bp of mHS-3.5 are required for megakaryocyte but not red cell expression. Here, we show mHS-3.5 binds key hemopoietic transcription factors in vivo and is required to maintain histone acetylation at the mGata1 locus in primary megakaryocytes. Analysis of GATA1-LacZ reporter gene expression in transgenic mice shows that a 25-bp element within the 3'-179 bp in mHS-3.5 is critical for megakaryocyte expression. In vitro three DNA binding activities A, B, and C bind to the core of the 25-bp element, and these binding sites are conserved through evolution. Activity A is the zinc finger transcription factor ZBP89 that also binds to other cis elements in the mGata1 locus. Activity B is of particular interest as it is present in primary megakaryocytes but not red cells. Furthermore, mutation analysis in transgenic mice reveals activity B is required for megakaryocyte-specific enhancer function. Bioinformatic analysis shows sequence corresponding to the binding site for activity B is a previously unrecognized motif, present in the cis elements of the Fli1 gene, another important megakaryocyte-specific transcription factor. In summary, we have identified a motif and a DNA binding activity likely to be important in directing a megakaryocyte gene expression program that is distinct from that in red cells.
Highlights
Though lineage specification is regulated by external cues that are modulated by intracellular signaling pathways, it culminates in activation of uni-lineage programs of gene expression and repression of genes associated with alternative cell fate
MHS-3.5 Is Required for Hyperacetylation of Histone H3 within the mGata1 Locus in Primary Megakaryocytes but Not Red Cells—To establish when during megakaryocytic differentiation mHS-3.5 is required for GATA1 expression, we isolated fetal primary common myeloid progenitors (CMP), megakaryocyte erythroid progenitors (MEP), megakaryocyte progenitors (MkP), and primary megakaryo
GATA1 levels were similar in wild-type and ⌬neo⌬HS CMP and MEP but decreased in ⌬neo⌬HS MkP and megakaryocytes to 5% of wild-type levels
Summary
Though lineage specification is regulated by external cues that are modulated by intracellular signaling pathways, it culminates in activation of uni-lineage programs of gene expression and repression of genes associated with alternative cell fate. The hemopoietic promoter (mIE), an upstream enhancer 3.5 kilobases from the GATA1 hemopoietic transcription start site, HS1/ G1HE/mHS-3.5 (hereafter referred to as mHS-3.5), and an element in the first mGata intron (HS 4/5 or mHSϩ3.5) (see Fig. 1A) are required to direct reporter gene expression to both erythroid cells and megakaryocytes in transgenic mice [8–10] Deletion of mHS-3.5 from the reporter construct extinguishes reporter gene expression in both red cells and megakaryocytes, highlighting a non-redundant enhancer function for mHS-3.5 in this assay [11, 12]. Whereas the whole 312 bp of mHS-3.5 is required for megakaryocyte reporter gene expression, only the 5Ј 133 bp is necessary for red cell reporter gene expression [11] These data suggest that the 3Ј 179 bp of mHS-3.5 binds trans-acting factors that cooperate with proteins that bind the GATA site, to direct megakaryocyte-specific enhancer activity. As a prelude to identifying trans-acting factors required for megakaryocyte-specific GATA1 expression, and megakaryocyte-specific gene activation in general, we set out to pinpoint the cis-acting sequences within mHS-3.5 mediating megakaryocyte-specific enhancer activity
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