nctional overlap between actively transcribed genes and chromatin insulator elements.

The mammalian genome is organised into large topologically associating domains (TADs) and smaller sub-TADs or enhancer-promoter loops, which may contribute to the regulation of gene expression. These dynamic structures arise, at least partly, via cohesin-mediated loop extrusion delimited by insulator elements. By studying the structure and function of the alpha-globin locus during erythroid differentiation, we have previously shown that the juxtaposition of the enhancers and promoters during this process partly depends on cohesin-mediated loop extrusion, which appears to be delimited by 12 largely convergently orientated CTCF boundary elements. To define the downstream boundary of the sub-TAD, we removed four CTCF sites in informative combinations. This showed that rather than CTCF insulators, it is the transcriptionally active alpha-globin gene that defines the downstream boundary of the sub-TAD. Further, insertion of actively transcribed fragments of the α-globin gene between the enhancers and native genes leads to a reduction in native α-globin expression and accumulation of cohesin at the insertion site. This highlights an overlap in the functional role of the fundamental elements of the genome.