PT  - JOURNAL ARTICLE
AU  - Caroline L Harrold
AU  - Matthew E Gosden
AU  - Lars L P Hanssen
AU  - Rosa J Stolper
AU  - Damien J Downes
AU  - Jelena M. Telenius
AU  - Daniel Biggs
AU  - Chris Preece
AU  - Samy Alghadban
AU  - Jacqueline A Sharpe
AU  - Benjamin Davies
AU  - Jacqueline A. Sloane-Stanley
AU  - Mira T Kassouf
AU  - Jim R Hughes
AU  - Douglas R Higgs
TI  - A functional overlap between actively transcribed genes and chromatin boundary elements
AID  - 10.1101/2020.07.01.182089
DP  - 2020 Jan 01
TA  - bioRxiv
PG  - 2020.07.01.182089
4099  - http://biorxiv.org/content/early/2020/07/01/2020.07.01.182089.short
4100  - http://biorxiv.org/content/early/2020/07/01/2020.07.01.182089.full
AB  - Mammalian genomes are subdivided into large (50-2000 kb) regions of chromatin referred to as Topologically Associating Domains (TADs or sub-TADs). Chromatin within an individual TAD contacts itself more frequently than with regions in surrounding TADs thereby directing enhancer-promoter interactions. In many cases, the borders of TADs are defined by convergently orientated boundary elements associated with CCCTC-binding factor (CTCF), which stabilises the cohesin complex on chromatin and prevents its translocation. This delimits chromatin loop extrusion which is thought to underlie the formation of TADs. However, not all CTCF-bound sites act as boundaries and, importantly, not all TADs are flanked by convergent CTCF sites. Here, we examined the CTCF binding sites within a ∼70 kb sub-TAD containing the duplicated mouse α-like globin genes and their five enhancers (5’-R1-R2-R3-Rm-R4-α1-α2-3’). The 5’ border of this sub-TAD is defined by a pair of CTCF sites. Surprisingly, we show that deletion of the CTCF binding sites within and downstream of the α-globin locus leaves the sub-TAD largely intact. The predominant 3’ border of the sub-TAD is defined by a steep reduction in contacts: this corresponds to the transcribed α2-globin gene rather than the CTCF sites at the 3’-end of the sub-TAD. Of interest, the almost identical α1- and α2-globin genes interact differently with the enhancers, resulting in preferential expression of the proximal α1-globin gene which behaves as a partial boundary between the enhancers and the distal α2-globin gene. Together, these observations provide direct evidence that actively transcribed genes can behave as boundary elements.Significance Statement Mammalian genomes are complex, organised 3D structures, partitioned into Topologically Associating Domains (TADs): chromatin regions that preferentially self-interact. These chromatin interactions are thought to be driven by a mechanism that continuously extrudes chromatin loops, forming structures delimited by chromatin boundary elements and reflecting the activity of enhancers and promoters. Boundary elements bind architectural proteins such as CCCTC-binding factor (CTCF). Previously, an overlap between the functional roles of enhancers and promoters has been shown. However, whether there is overlap between enhancers/promoters and boundary elements is not known. Here, we show that actively transcribed genes can also behave as boundary elements, similar to CTCF boundaries. In both cases, multi-protein complexes bound to these regions may stall the process of chromatin loop extrusion.Competing Interest StatementJ.R.H is a founder and shareholder of Nucleome Therapeutics.