GATA1 is a transcription factor that is required for survival and maturation of erythroid cells. In the absence of GATA1, mouse embryos die from anemia in mid-gestation. In humans, GATA1 mutations are associated with a spectrum of blood disorders, including congenital dyserythropoietic anemia and thrombocytopenia, porphyria, and Diamond-Blackfan Anemia (DBA). In the presence of trisomy 21, GATA1 mutations that delete the N- terminus lead to Down syndrome associated Acute Megakaryoblastic Leukemia (DS-AMKL). We recently demonstrated that a GATA1 mutant, which fails to bind FOG1 and is associated with rare cases of cases of dyserythropoietic anemia, fails to bind chromatin in the same manner as wild-type GATA1. This differential chromatin binding allows GATA1 to promote mast cell formation instead of red cell or megakaryocyte development. In a similar fashion, we have recently discovered that GATA1 molecules that lack the N-terminal activation domain, seen in both DBA and DS-AMKL, also fail to bind chromatin in the same way as full-length GATA1. Of interest, genes that are not properly bound or regulated by GATA1s include critical red cell genes such as Alas2, Slc4a1, and Klf1 (EKLF). In this grant, we will precisely define the requirement for the N- terminus of GATA1 in red cell development.
Our aim i s to discover how the GATA1 mutations that lead to expression of GATA1s in place of the full-length protein cause defects in the erythroid lineage and congenital anemia, including DBA. Our overarching hypothesis is that the reduced chromatin binding and aberrant gene regulation by GATA1s leads to impaired specification and terminal differentiation of red blood cells.
Our aims are to: 1 Correlate chromatin occupancy of GATA1s with gene expression defects in primary GATA1s knock-in erythroid progenitor cells to identify key direct target genes that are dysregulated; 2) Investigate the consequences of the GATA1s mutation on erythroid specification and differentiation; and 3) Determine if loss of the N-terminus reduces the interaction with essential cofactors and in turn affects their chromatin occupancy. The research described in this proposal will greatly expand our insights into how loss of the N-terminus of GATA1 alters erythropoiesis and will benefit patients with congenital anemia and DS-AMKL.
Humans with congenital GATA1 mutations suffer from various forms of anemia, including congenital dyserythropoietic anemia with thrombocytopenia and Diamond Blackfan Anemia. Here, based on our novel discovery that mutant forms of GATA1 fail to bind their targets in chromatin, we will investigate the mechanism by which these mutations cause anemia. Our research will provide important clues to assist in the development of novel approaches to normalize erythropoiesis in these patients.
Crispino, John D; Horwitz, Marshall S (2017) GATA factor mutations in hematologic disease. Blood 129:2103-2110 |
Chlon, Timothy M; McNulty, Maureen; Goldenson, Benjamin et al. (2015) Global transcriptome and chromatin occupancy analysis reveal the short isoform of GATA1 is deficient for erythroid specification and gene expression. Haematologica 100:575-84 |
Crispino, John D; Weiss, Mitchell J (2014) Erythro-megakaryocytic transcription factors associated with hereditary anemia. Blood 123:3080-8 |