We have used transgenic mice to study the influence of position of the human globin genes relative to the locus control region (LCR) on their expression pattern during development. The LCR, which is located 5' of the globin gene cluster, is normally required for the activation of all the genes. When the human 13-globin gene is linked as a single gene to the LCR it is activated prematurely in the embryonic yolk sac. We show that the correct timing of [] gene activation is restored when it is placed farther from the LCR than a competing human ~,-or ~-globin gene. Correct timing is not restored when 13 is the globin gene closest to the LCR. Similarly, the human ~,-globin gene is silenced earlier when present farthest from the LCR. On the basis of this result, we propose a model of developmental gene control based on stage-specific elements immediately flanking the genes and on polarity in the locus. We suggest that the difference in relative distance to the LCR, which is a consequence of the ordered arrangement of the genes, results in nonreciprocal competition between the genes for activation by the LCR.
GATA-1 is a tissue-specific transcription factor that is essential for the production of red blood cells. Here we show that overexpression of GATA-1 in erythroid cells inhibits their differentiation, leading to a lethal anaemia. Using chromosome-X-inactivation of a GATA-1 transgene and chimaeric animals, we show that this defect is intrinsic to erythroid cells, but nevertheless cell nonautonomous. Usually, cell nonautonomy is thought to reflect aberrant gene function in cells other than those that exhibit the phenotype. On the basis of our data, we propose an alternative mechanism in which a signal originating from wild-type erythroid cells restores normal differentiation to cells overexpressing GATA-1 in vivo. The existence of such a signalling mechanism indicates that previous interpretations of cell-nonautonomous defects may be erroneous in some cases and may in fact assign gene function to incorrect cell types.
The Locus Control Region (LCR) of the human beta globin gene domain is defined by four erythroid-specific DNasel hypersensitive sites (HSS) located upstream of this multigene cluster. The LCR confers copy number dependent high levels of erythroid specific expression to a linked transgene, independent of the site of integration. To assess the role of the individual hypersensitive sites of the LCR, we have localized HSS4 to a 280bp fragment that is functional both in murine erythroleukaemia (MEL) cells and in transgenic mice. This fragment coincides with the major area of hypersensitivity 'in vivo' and contains a number of DNasel footprints. Bandshift analysis shows that these footprints correspond to binding sites for the erythroid specific proteins GATA1 and NF-E2 and a number of ubiquitous proteins, including jun/fos, Sp1 and TEF2.
The GATA‐1 transcription factor has been shown to be important in the regulation of globin and non‐globin genes in erythroid, megakaryocytic and mast cell lineages. It is a member of a family of GATA proteins which both overlap in their expression patterns and bind the motif (A/T)GATA(A/G). The GATA family of proteins are also members of the superfamily of zinc finger‐like domain proteins and have two similar domains of the type Cys‐X2‐Cys‐X17‐Cys‐X2‐Cys which direct the DNA binding of the protein. A random oligonucleotide selection procedure has been employed to further elucidate the mechanism of GATA‐1‐DNA recognition. The resulting oligonucleotides were tested for binding activity to both wild‐type and mutant GATA‐1 proteins. Two classes of GATA‐1‐DNA interaction have been defined, the first requiring only the carboxy finger of GATA‐1 to bind and having the motif GAT(A/T), the second requiring both finger domains to bind and having the core motif (T/C)AAG. By using sequence comparison and depurination analysis it is concluded that the two finger‐like domains of GATA‐1 have different DNA binding recognition motifs. Binding of GATA‐1 to GAT(A/T) motifs is associated with transcriptional activation of linked genes. The only known (T/C)AAG motif is in the distal CAAT‐box promoter region of the human A gamma‐globin gene where the binding of GATA‐1 appears to regulate the correct developmental suppression of gamma‐globin expression.
GATA-1 is a tissue-specific DNA-binding protein containing two zinc-finger-like domains. It is expressed predominantly in erythrocytes. Consensus binding sites for GATA-1 have been found in the regulatory elements of all erythroid-specific genes examined. GATA-1 protein is required for erythroid differentiation beyond the proerythroblast stage. In this paper, we demonstrate that the overexpression of GATA-1 in murine erythroleukaemia (MEL) cells alleviates DMSO-induced terminal erythroid differentiation. Hence, there is no induction of globin gene transcription and the cells do not arrest in the G1 phase of the cell cycle. Furthermore, we demonstrate that expression of GATA-1 in non-transformed erythroid precursors also affects their proliferative capacity and terminal differentiation, as assayed by adult globin gene transcription. To gain insight into the mechanism of this effect, we studied the levels and activities of regulators of cell-cycle progression during DMSO-induced differentiation. A decrease in cyclin D-dependent kinase activity was observed during the induction of both control and GATA-1-overexpressing MEL cells. However, cyclin E-dependent kinase activity decreased more than 20-fold in control but less than 2-fold in GATA-1-overexpressing MEL cells upon induction. Thus GATA-1 may exert its effects by regulating cyclin E-dependent kinase activity. We also show that GATA-1 binds to the retinoblastoma protein in vitro, but not to the related protein p107, which may indicate that GATA-1 interacts directly with specific members of the cell-cycle machinery in vivo. We conclude that GATA-1 regulates cell fate, in terms of differentiation or proliferation, by affecting the cell-cycle apparatus.
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