Project description:Congenital dyserythropoietic anemia type I (CDA-I) is an autosomal recessive disorder marked by ineffective erythropoiesis, abnormal morphology of bone marrow erythroblasts, and iron overload. Most cases of CDA-I are caused by mutations in the CDAN1 gene, which encodes for a ubiquitous protein of unknown function, codanin-1. To study the function of codanin-1 in CDA-I erythroid pathophysiology several erythroid models were developed. Here we show that codanin-1 expression is required for erythroid progenitor development and normal erythroid cell differentiation. Erythroid cells lacking codanin-1 demonstrated morphologic changes similar to that observed in CDA-I. Global gene expression changes after codanin-1 knockdown revealed alterations in a set of key erythroid genes. In particular, the AHSP gene, which showed decreased mRNA expression after codanin-1 knockdown in CD34+ cells, also demonstrated increased codanin-1 occupancy at its gene regulatory region by chromatin immunoprecipitation coupled to high-throughput sequencing. Using cell models recapitulating many features of CDA-I, we have confirmed the importance of codanin-1 during erythroid differentiation and provide mechanistic insight into how loss of codanin-1 expression results in CDA-I.

Project description:Congenital Dyserythropoietic Anaemia type 1 (CDA-I) is an inherited anaemia arising primarily from mutations in C15orf41 and CDAN1, however the molecular mechanisms that cause the disease remain to be fully elucidated. We use an in vitro culture system to study multiple stages of erythropoiesis from CD34+ progenitors of patients with CDA-I. Applying a number of techniques, including ATAC-seq, we show that differentiation of CDA-I patient erythroblasts closely matches that of healthy donors during the early and intermediate stages of erythroid differentiation and maturation. However, a defect in terminal erythropoiesis can be observed in the CDA-I patient derived erythroblasts, resulting in a reduction in the number of enucleated erythroid cells.

Project description:Congenital dyserythropoietic anemia Type 1 (CDA1) is a rare macrocytic anemia caused by loss-of-function mutation of CDAN1. To investigate the functional role of CDAN1, we performed RNA-sequencing on human erythroleukemic K562 cells with CDAN1 shRNA knockdown using a doxycycline inducible system

Project description:Analysis of erythroblastic cells differentiated from induced pluripotent stem cells (iPSCs) generated from peripheral blood T lymphocytes of CDA type IV patient. Type IV congenital dyserythropoietic anemia (CDA) is due to a monoallelic mutation at the second zinc finger of KLF1 (c.973G>A). Results provide insight into molecular mechanisms underlying CDA pathogenesis.

Project description:Red blood cell disorders can result in severe anemia. One such disease, congenital dyserythropoietic anemia IV (CDA IV) is caused by heterozygous mutation E325K in the transcription factor KLF1. However, studying the molecular basis of CDA IV is severely impeded by paucity of suitable and adequate quantities of material from anaemic patients and rarity of the disease. We therefore took a novel approach, creating a human cellular disease model system for CDA IV, which accurately recapitulates the disease phenotype. Next, using comparative proteomics we reveal extensive distortion of the proteome and a wide range of disordered biological processes in CDA IV erythroid cells. These include down-regulated pathways governing cell cycle, chromatin separation, DNA repair, cytokinesis, membrane trafficking and global transcription, and upregulated networks governing mitochondria biogenesis. The diversity of such pathways elucidates the spectrum of phenotypic abnormalities that occur with CDA IV and impairment to erythroid cell development and survival, collectively explaining the CDA IV disease phenotype. The data also reveal far more extensive involvement of KLF1 in previously assigned biological processes, along with novel roles in the regulation of intracellular processes not previously attributed to this transcription factor. Overall, the data demonstrate the power of such a model cellular system to unravel the molecular basis of disease and how studying effects of a rare mutation can reveal fundamental biology.

Project description:CDAN1, and residue R1042, have a function in DNA replication and organization in terminal erythroid maturation.

Project description:Congenital dyserythropoietic anaemia (CDA) type IV has been associated with an amino acid substitution, Glu325Lys (E325K), in the transcription factor KLF1. Patients with CDA type IV present with a range of symptoms, including the persistence of nucleated red blood cells (RBCs) in the peripheral blood which reflects the known role for KLF1 within the erythroid cell lineage. The final stages of RBCs maturation and enucleation take place within the erythroblastic island (EBI) niche in close association with EBI macrophages. It is not known whether the detrimental effects of the E325K mutation in KLF1 are restricted to the erythroid lineage or whether deficiencies in macrophages associated with their niche also contribute to the disease pathology. To address this question, we generated iPSC lines genetically modified to express a KLF1-E325K-ERT2 protein that could be activated with 4OH-tamoxifen. We performed bulk RNA-sequencing on macrophages generated from these iPSCs, macrophages generated from one KLF1-E325K-ERT2 iPSC line (iCDA4.1) was compared to macrophages generated from one inducible KLF1-WT-ERT2 (K2) iPSC line which was derived from the same parental iPSCs (SFCi55) as the KLF1-E325K-ERT2 line.

Project description:Nuclear receptor binding SET domain protein 1 (NSD1) is recurrently mutated in human cancers including acute leukemia. We found that NSD1 knockdown altered erythroid clonogenic growth of human CD34+ hematopoietic cells. Ablation of Nsd1 in the hematopoietic system induced a transplantable erythroleukemia in mice. Despite abundant expression of the transcriptional master regulator GATA1, in vitro differentiation of Nsd1-/- erythroblasts was majorly impaired associated with reduced activation of GATA1-induced targets, while GATA1-repressed target genes were less affected. Retroviral expression of wildtype Nsd1, but not a catalytically-inactive Nsd1N1918Q SET-domain mutant induced terminal maturation of Nsd1-/- erythroblasts. Despite similar GATA1 levels, exogenous Nsd1 but not Nsd1N1918Q significantly increased GATA1 chromatin occupancy and target gene activation. Notably, Nsd1 expression reduced the association of GATA1 with the co-repressor SKI, and knockdown of SKI induced differentiation of Nsd1-/- erythroblasts. Collectively, we identified the NSD1 methyltransferase as a novel regulator of GATA1-controlled erythroid differentiation and leukemogenesis.

Project description:Congenital dyserythropoietic anemia (CDA) type IV is caused by a heterozygous mutation, Glu325Lys (E325K), in the KLF1 transcription factor. A molecular understanding of this disease is absent, partly due to its rarity. We expanded erythroid cells from a patient’s peripheral blood and analyzed its global expression pattern. We find that a large number of erythroid pathways are disrupted, particularly those related to membrane transport, globin regulation, and iron utilization. The altered genetics lead to significant deficits in differentiation. Glu325 is within the KLF1 zinc finger domain at an amino acid critical for site specific DNA binding. The change to Lys is predicted to significantly alter the target site recognition sequence, both by subverting normal recognition and by enabling interaction with novel sites. Consistent with this, we find high level ectopic expression of genes not normally present in the red cell. These altered properties explain the patients’ clinical and phenotypic features and elucidate the dominant character of the mutation.

Project description:We find that the myeloid master regulatory transcription factor, PU.1, binds to >16,000 sites in both normal and leukemic erythroid cells. Of these bound sites, ~7,000 lie within 2kb of TSS of a gene, suggesting PU.1 may regulate a large number of genes in erythroid cells. Coupling this data with gene expression analysis, we show PU.1 directly regulates several critical signaling pathways in erythroid cells.