Project description:Mutations in GATA1 that result in skipping of exon 2, which encodes the N-terminus, are associated with the myeloid leukemia of Down syndrome and Diamond-Blackfan anemia (DBA). To elucidate the molecular functions of the N-terminus, we employed single-cell RNA sequencing (scRNA-seq) of fetal liver cells derived from Gata1 mutant embryos that express the GATA1 short (GATA1s) isoform in place of full-length GATA1 (GATA1FL). scRNA-seq highlighted defects in erythropoiesis and revealed that the absence of the N-terminus resulted in elevated expression of genes involved in glycolysis, such as the rate-limiting pyruvate kinase PKM. To elucidate the regulation of the PKM gene, we performed precision nuclear run-on sequencing and cleavage under targets and release using nuclease on erythroid cells following acute deletion of GATA1 and determined that PKM is a direct target of GATA1. Mechanistically, we found that substitution of GATA1FL with GATA1s led to increased glycolysis in erythroid progenitor cells but did not affect oxidative phosphorylation. We further discovered that the expression of PKM is significantly elevated in DBA patients with RPS19 mutations, consistent with a role for GATA1 regulation of glycolysis in erythropoiesis. Together, these findings reveal that GATA1 controls not just heme metabolism, but also glycolysis.

Project description:Mutations in GATA1 that result in skipping of exon 2, which encodes the N-terminus, are associated with the myeloid leukemia of Down syndrome and Diamond-Blackfan anemia (DBA). To elucidate the molecular functions of the N-terminus, we employed single-cell RNA sequencing (scRNA-seq) of fetal liver cells derived from Gata1 mutant embryos that express the GATA1 short (GATA1s) isoform in place of full-length GATA1 (GATA1FL). scRNA-seq highlighted defects in erythropoiesis and revealed that the absence of the N-terminus resulted in elevated expression of genes involved in glycolysis, such as the rate-limiting pyruvate kinase PKM. To elucidate the regulation of the PKM gene, we performed precision nuclear run-on sequencing and cleavage under targets and release using nuclease on erythroid cells following acute deletion of GATA1 and determined that PKM is a direct target of GATA1. Mechanistically, we found that substitution of GATA1FL with GATA1s led to increased glycolysis in erythroid progenitor cells but did not affect oxidative phosphorylation. We further discovered that the expression of PKM is significantly elevated in DBA patients with RPS19 mutations, consistent with a role for GATA1 regulation of glycolysis in erythropoiesis. Together, these findings reveal that GATA1 controls not just heme metabolism, but also glycolysis.

Project description:Mutations in GATA1 that result in skipping of exon 2, which encodes the N-terminus, are associated with the myeloid leukemia of Down syndrome and Diamond-Blackfan anemia (DBA). To elucidate the molecular functions of the N-terminus, we employed single-cell RNA sequencing (scRNA-seq) of fetal liver cells derived from Gata1 mutant embryos that express the GATA1 short (GATA1s) isoform in place of full-length GATA1 (GATA1FL). scRNA-seq highlighted defects in erythropoiesis and revealed that the absence of the N-terminus resulted in elevated expression of genes involved in glycolysis, such as the rate-limiting pyruvate kinase PKM. To elucidate the regulation of the PKM gene, we performed precision nuclear run-on sequencing and cleavage under targets and release using nuclease on erythroid cells following acute deletion of GATA1 and determined that PKM is a direct target of GATA1. Mechanistically, we found that substitution of GATA1FL with GATA1s led to increased glycolysis in erythroid progenitor cells but did not affect oxidative phosphorylation. We further discovered that the expression of PKM is significantly elevated in DBA patients with RPS19 mutations, consistent with a role for GATA1 regulation of glycolysis in erythropoiesis. Together, these findings reveal that GATA1 controls not just heme metabolism, but also glycolysis.

Project description:Mutations in GATA1 that result in skipping of exon 2, which encodes the N-terminus, are associated with the myeloid leukemia of Down syndrome and Diamond-Blackfan anemia (DBA). To elucidate the molecular functions of the N-terminus, we employed single-cell RNA sequencing (scRNA-seq) of fetal liver cells derived from Gata1 mutant embryos that express the GATA1 short (GATA1s) isoform in place of full-length GATA1 (GATA1FL). scRNA-seq highlighted defects in erythropoiesis and revealed that the absence of the N-terminus resulted in elevated expression of genes involved in glycolysis, such as the rate-limiting pyruvate kinase PKM. To elucidate the regulation of the PKM gene, we performed precision nuclear run-on sequencing and cleavage under targets and release using nuclease on erythroid cells following acute deletion of GATA1 and determined that PKM is a direct target of GATA1. Mechanistically, we found that substitution of GATA1FL with GATA1s led to increased glycolysis in erythroid progenitor cells but did not affect oxidative phosphorylation. We further discovered that the expression of PKM is significantly elevated in DBA patients with RPS19 mutations, consistent with a role for GATA1 regulation of glycolysis in erythropoiesis. Together, these findings reveal that GATA1 controls not just heme metabolism, but also glycolysis.

Project description:Mutations in GATA1 that result in skipping of exon 2, which encodes the N-terminus, are associated with the myeloid leukemia of Down syndrome and Diamond-Blackfan anemia (DBA). To elucidate the molecular functions of the N-terminus, we employed single-cell RNA sequencing (scRNA-seq) of fetal liver cells derived from Gata1 mutant embryos that express the GATA1 short (GATA1s) isoform in place of full-length GATA1 (GATA1FL). scRNA-seq highlighted defects in erythropoiesis and revealed that the absence of the N-terminus resulted in elevated expression of genes involved in glycolysis, such as the rate-limiting pyruvate kinase PKM. To elucidate the regulation of the PKM gene, we performed precision nuclear run-on sequencing and cleavage under targets and release using nuclease on erythroid cells following acute deletion of GATA1 and determined that PKM is a direct target of GATA1. Mechanistically, we found that substitution of GATA1FL with GATA1s led to increased glycolysis in erythroid progenitor cells but did not affect oxidative phosphorylation. We further discovered that the expression of PKM is significantly elevated in DBA patients with RPS19 mutations, consistent with a role for GATA1 regulation of glycolysis in erythropoiesis. Together, these findings reveal that GATA1 controls not just heme metabolism, but also glycolysis.

Project description:Mutations in GATA1, which lead to expression of the GATA1s isoform that lacks the GATA1 N-terminus, are seen in patients with Diamond-Blackfan Anemia (DBA). In our efforts to better understand the connection between GATA1s and DBA, we comprehensively studied erythropoiesis in Gata1s mice. Defects in yolks sac and fetal liver hematopoiesis included impaired terminal maturation and reduced numbers of erythroid progenitors. RNA-sequencing revealed that both erythroid and megakaryocytic genes were altered by the loss of the N-terminus, including aberrant up-regulation of Gata2 and Runx1. Mass spectrometry studies demonstrated there was a global increase in H3K27 methylation in the erythroid progenitors. By contrast, chromatin biding assays revealed that, despite similar occupancy of GATA1 and GATA1s, there was a striking reduction of H3K27me3 at regulatory elements of the Gata2 and Runx1 genes. Consistent with the observation that overexpression of GATA2 has been reported to impair erythropoiesis, we found that haploinsufficiency of Gata2 rescued the erythroid defects of Gata1s fetuses. Together, our integrated genomic analysis of transcriptomic and epigenetic signatures reveals that, although Gata1s mice do not precisely model DBA, they provide novel insights into the role of the N-terminus of GATA1 in transcriptional regulation and red blood cell maturation.

Project description:We transduced mouse Gata1- megakaryocyte-erythroid progenitors with MIGRI-GFP vector expressing GATA1fl or GATA1s cDNAs. GFP-positive cells expressing one of the two isoforms of GATA1 were isolated by FACS 42 hours following transduction and used for microarray transcriptome analysis. At this time point, there was no apparent difference in the cell surface phenotypes between GATA1fl and GATA1s-expressing cells. Transcriptome data for G1ME/GATA1fl at 42h were deposited previously under GSE14980 (GSM374049, GSM374050, GSM374051), whereas G1ME/GATA1s at 42h are deposited here.

Project description:We used chromatin immunoprecipitation sequencing (ChIP-seq) to compare genome-wide binding profiles of GATA1fl and GATA1s in G1ME cells, which are immortalized, developmentally arrested megakaryocyte-erythroid progenitors (MEPs) derived from in vitro differentiation of murine Gata1- ES cells. Although the truncation in GATA1s leaves the DNA binding domain intact, GATA1s fails to broadly occupy erythroid specific regulatory regions. These observations point to lineage specific co-factor associations essential for normal chromatin occupancy and provide mechanistic insights into how GATA1s mutations cause human disease. We performed ChIP-seq on G1ME cells 42 hours after retroviral transfer of HA-tagged full-length GATA1 (GATA1fl) or GATA1s cDNAs (2 replicates each). At this time point, there was no apparent difference in the cell surface phenotypes between GATA1fl and GATA1s-expressing cells. For each ChIP-seq replicate we obtained a matching input sample (non-ChIP DNA) as a control.

Project description:We transduced mouse Gata1- megakaryocyte-erythroid progenitors with MIGRI-GFP vector expressing GATA1fl or GATA1s cDNAs. GFP-positive cells expressing one of the two isoforms of GATA1 were isolated by FACS 42 hours following transduction and used for microarray transcriptome analysis. At this time point, there was no apparent difference in the cell surface phenotypes between GATA1fl and GATA1s-expressing cells. Transcriptome data for G1ME/GATA1fl at 42h were deposited previously under GSE14980 (GSM374049, GSM374050, GSM374051), whereas G1ME/GATA1s at 42h are deposited here. We performed differential expression analysis comparing mean expression levels of genes in G1ME cells at 42 hours after transduction with GATA1fl (3 replicates deposited previously under GSE14980: GSM374049, GSM374050, GSM374051) or GATA1s (3 replicates deposited here). All 6 samples were prepared the same way and analyzed on the same platform, Affymetrix Mouse Genome 420 2.0.

Project description:We used chromatin immunoprecipitation sequencing (ChIP-seq) to compare genome-wide binding profiles of GATA1fl and GATA1s in G1ME cells, which are immortalized, developmentally arrested megakaryocyte-erythroid progenitors (MEPs) derived from in vitro differentiation of murine Gata1- ES cells. Although the truncation in GATA1s leaves the DNA binding domain intact, GATA1s fails to broadly occupy erythroid specific regulatory regions. These observations point to lineage specific co-factor associations essential for normal chromatin occupancy and provide mechanistic insights into how GATA1s mutations cause human disease.