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
β-Thalassemia is one of the most common inherited anemias, with no effective cure for most patients. The pathophysiology reflects an imbalance between α- and β-globin chains with an excess of free α-globin chains causing ineffective erythropoiesis and hemolysis. When α-thalassemia is co-inherited with β-thalassemia, excess free α-globin chains are reduced significantly ameliorating the clinical severity. Here we demonstrate the use of CRISPR/Cas9 genome editing of primary human hematopoietic stem/progenitor (CD34+) cells to emulate a natural mutation, which deletes the MCS-R2 α-globin enhancer and causes α-thalassemia. When edited CD34+ cells are differentiated into erythroid cells, we observe the expected reduction in α-globin expression and a correction of the pathologic globin chain imbalance in cells from patients with β-thalassemia. Xenograft assays show that a proportion of the edited CD34+ cells are long-term repopulating hematopoietic stem cells, demonstrating the potential of this approach for translation into a therapy for β-thalassemia.
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