Cis interactions in the Irf8 locus regulate stage-dependent enhancer activation.

Individual elements within a superenhancer can act in a cooperative or temporal manner, but the underlying mechanisms remain obscure. We recently identified an Irf8 superenhancer, within which different elements act at distinct stages of type 1 classical dendritic cell (cDC1) development. The +41-kb Irf8 enhancer is required for pre-cDC1 specification, while the +32-kb Irf8 enhancer acts to support subsequent cDC1 maturation. Here, we found that compound heterozygous Δ32/Δ41 mice, lacking the +32- and +41-kb enhancers on different chromosomes, show normal pre-cDC1 specification but, surprisingly, completely lack mature cDC1 development, suggesting cis dependence of the +32-kb enhancer on the +41-kb enhancer. Transcription of the +32-kb Irf8 enhancer-associated long noncoding RNA (lncRNA) Gm39266 is also dependent on the +41-kb enhancer. However, cDC1 development in mice remained intact when Gm39266 transcripts were eliminated by CRISPR/Cas9-mediated deletion of lncRNA promoters and when transcription across the +32-kb enhancer was blocked by premature polyadenylation. We showed that chromatin accessibility and BATF3 binding at the +32-kb enhancer were dependent on a functional +41-kb enhancer located in cis Thus, the +41-kb Irf8 enhancer controls the subsequent activation of the +32-kb Irf8 enhancer in a manner that is independent of associated lncRNA transcription.

Liu TT ，Ou F ，Belk JA ，Bagadia P ，Anderson DA 3rd ，Durai V ，Yao W ，Satpathy AT ，Murphy TL ，Murphy KM ... -  《-》

Anatomy of a superenhancer.

Kim S ，Liu TT ，Ou F ，Murphy TL ，Murphy KM ... -  《-》

Cryptic activation of an Irf8 enhancer governs cDC1 fate specification.

Durai V ，Bagadia P ，Granja JM ，Satpathy AT ，Kulkarni DH ，Davidson JT 4th ，Wu R ，Patel SJ ，Iwata A ，Liu TT ，Huang X ，Briseño CG ，Grajales-Reyes GE ，Wöhner M ，Tagoh H ，Kee BL ，Newberry RD ，Busslinger M ，Chang HY ，Murphy TL ，Murphy KM ... -  《-》

Physical and functional interaction among Irf8 enhancers during dendritic cell differentiation.

The production of type 1 conventional dendritic cells (cDC1s) requires high expression of the transcription factor IRF8. Three enhancers at the Irf8 3' region function in a differentiation stage-specific manner. However, whether and how these enhancers interact physically and functionally remains unclear. Here, we show that the Irf8 3' enhancers directly interact with each other and contact the Irf8 gene body during cDC1 differentiation. The +56 kb enhancer, which functions from multipotent progenitor stages, activates the other 3' enhancers through an IRF8-dependent transcription factor program, that is, in trans. Then, the +32 kb enhancer, which operates in cDC1-committed cells, reversely acts in cis on the other 3' enhancers to maintain the high expression of Irf8. Indeed, mice with compound heterozygous deletion of the +56 and +32 kb enhancers are unable to generate cDC1s. These results illustrate how multiple enhancers cooperate to induce a lineage-determining transcription factor gene during cell differentiation.

Yamasaki T ，Nishiyama A ，Kurogi N ，Nishimura K ，Nishida S ，Kurotaki D ，Ban T ，Ramilowski JA ，Ozato K ，Toyoda A ，Tamura T ... -  《Cell Reports》

A lncRNA identifies Irf8 enhancer element in negative feedback control of dendritic cell differentiation.

Transcription factors play a determining role in lineage commitment and cell differentiation. Interferon regulatory factor 8 (IRF8) is a lineage determining transcription factor in hematopoiesis and master regulator of dendritic cells (DC), an important immune cell for immunity and tolerance. IRF8 is prominently upregulated in DC development by autoactivation and controls both DC differentiation and function. However, it is unclear how Irf8 autoactivation is controlled and eventually limited. Here, we identified a novel long non-coding RNA transcribed from the +32 kb enhancer downstream of Irf8 transcription start site and expressed specifically in mouse plasmacytoid DC (pDC), referred to as lncIrf8. The lncIrf8 locus interacts with the lrf8 promoter and shows differential epigenetic signatures in pDC versus classical DC type 1 (cDC1). Interestingly, a sequence element of the lncIrf8 promoter, but not lncIrf8 itself, is crucial for mouse pDC and cDC1 differentiation, and this sequence element confers feedback inhibition of Irf8 expression. Taken together, in DC development Irf8 autoactivation is first initiated by flanking enhancers and then second controlled by feedback inhibition through the lncIrf8 promoter element in the +32 kb enhancer. Our work reveals a previously unrecognized negative feedback loop of Irf8 that orchestrates its own expression and thereby controls DC differentiation.

Xu H ，Li Z ，Kuo CC ，Götz K ，Look T ，de Toledo MAS ，Seré K ，Costa IG ，Zenke M ... -  《-》