ATRX is a member of the SNF2 family of helicase͞ATPases that is thought to regulate gene expression via an effect on chromatin structure and͞or function. Mutations in the hATRX gene cause severe syndromal mental retardation associated with ␣-thalassemia. Using indirect immunofluorescence and confocal microscopy we have shown that ATRX protein is associated with pericentromeric heterochromatin during interphase and mitosis. By coimmunofluorescence, ATRX localizes with a mouse homologue of the Drosophila heterochromatic protein HP1 in vivo, consistent with a previous two-hybrid screen identifying this interaction. From the analysis of a trap assay for nuclear proteins, we have shown that the localization of ATRX to heterochromatin is encoded by its N-terminal region, which contains a conserved plant homeodomainlike finger and a coiled-coil domain. In addition to its association with heterochromatin, at metaphase ATRX clearly binds to the short arms of human acrocentric chromosomes, where the arrays of ribosomal DNA are located. The unexpected association of a putative transcriptional regulator with highly repetitive DNA provides a potential explanation for the variability in phenotype of patients with identical mutations in the ATRX gene.
Complex gene regulation is one of the key requirements for the evolution of higher eukaryotes. 1 In these organisms, many genes are regulated by enhancers that are 10 4 -10 6 base pairs (bp) distant from the promoter. Enhancer sequences usually contain multiple small transcription factor binding sites (typically ~10bp), and physical contact between the promoter and enhancer is thought to be required to modulate gene expression. 2 Current methods have extensively defined chromatin architecture at scales above 1 kb but until now it has not been possible to define physical contacts at the scale of the key proteins determining gene expression. Here we define the interactions between different classes of regulatory elements (enhancers, promoters and boundary elements) in unprecedented detail, using a novel chromosome conformation capture method (Micro Capture-C (MCC)), which allows physical contacts to be determined at base-pair resolution. We find that highly punctate contacts occur between enhancers, promoters and CCCTC-binding factor (CTCF) sites and we show, using base pair resolution plots of ligation junctions, that transcription factors generate a key component of the contacts between enhancers and promoters. Our data show that contacts from CTCF sites highly correlate with cooccupancy of cohesin and that interactions between CTCF sites are increased when active promoters and enhancers are located within the intervening chromatin. We also find that promoters make the strongest contacts with both enhancers and CTCF sites and that while CTCF sites contact promoters strongly they only make weak contacts with enhancers. The highly punctate nature of the contacts is an unexpected finding because the current view is that physical contacts are constrained by much larger domains such as topological associated domains (TADs). 3 Our results support a model in which chromatin loop extrusion 4-6 is dependent on cohesin loading at active promoters and enhancers, explaining the formation of tissue-specific chromatin domains without changes in CTCF binding. The data suggest that a separate mechanism to loop extrusion underlies enhancer-/promoter contacts, which likely involves DNA binding proteins at enhancers and promoters. The unprecedented
Hemoglobin switching is a complex process by which distinct globin chains are produced during stages of development. In an effort to characterize the process of hemoglobin switching in the zebrafish model system, we have isolated and characterized several embryonic globin genes. The embryonic and adult globin genes are found in clusters in a head-to-head configuration. One cluster of embryonic and adult genes is localized to linkage group 3, whereas another embryonic cluster is localized on linkage group 12. Several embryonic globin genes demonstrate an erythroid-specific pattern of expression early during embryogenesis and later are downregulated as definitive hematopoiesis occurs. We utilized electrospray mass spectroscopy to correlate globin genes and protein expression in developing embryonic red cells. The mutation, zinfandel, has a hypochromic microcytic anemia as an embryo, but later recovers in adulthood. The zinfandel gene maps to linkage group 3 near the major globin gene locus, strongly suggesting that zinfandel represents an embryonic globin defect. Our studies are the first to systematically evaluate the embryonic globins in the zebrafish and will ultimately be useful in evaluating zebrafish mutants with defects in hemoglobin production and switching.
The major positive regulatory activity of the human a-globin gene complex has been localized to an element associated with a strong erythroid-specific DNase I hypersensitive site (HS -40) located 40 kb upstream of the ,2-globin mRNA cap site. Footprint and gel shift analyses of the element have demonstrated the presence of four binding sites for the nuclear factor GATA-1 and two sites corresponding to the AP-1 consensus binding sequence. This region resembles one of the major elements of the j8-globin locus control region in its constitution and characteristics; this together with evidence from expression studies suggests that HS -40 is a primary element controiling a-globin gene expression.
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