Adaptive Evolution and the Birth of CTCF Binding Sites in the Drosophila Genome

Changes in the physical interaction between cis-regulatory DNA sequences and proteins drive the evolution of gene expression. However, it has proven difficult to accurately quantify evolutionary rates of such binding change or to estimate the relative effects of selection and drift in shaping the binding evolution. Here we examine the genome-wide binding of CTCF in four species of Drosophila separated by between ∼2.5 and 25 million years. CTCF is a highly conserved protein known to be associated with insulator sequences in the genomes of human and Drosophila. Although the binding preference for CTCF is highly conserved, we find that CTCF binding itself is highly evolutionarily dynamic and has adaptively evolved. Between species, binding divergence increased linearly with evolutionary distance, and CTCF binding profiles are diverging rapidly at the rate of 2.22% per million years (Myr). At least 89 new CTCF binding sites have originated in the Drosophila melanogaster genome since the most recent common ancestor with Drosophila simulans. Comparing these data to genome sequence data from 37 different strains of Drosophila melanogaster, we detected signatures of selection in both newly gained and evolutionarily conserved binding sites. Newly evolved CTCF binding sites show a significantly stronger signature for positive selection than older sites. Comparative gene expression profiling revealed that expression divergence of genes adjacent to CTCF binding site is significantly associated with the gain and loss of CTCF binding. Further, the birth of new genes is associated with the birth of new CTCF binding sites. Our data indicate that binding of Drosophila CTCF protein has evolved under natural selection, and CTCF binding evolution has shaped both the evolution of gene expression and genome evolution during the birth of new genes.     

A Functional Insulator Screen Identifies NURF and dREAM Components to Be Required for Enhancer-Blocking

Chromatin insulators of higher eukaryotes functionally divide the genome into active and inactive domains. Furthermore, insulators regulate enhancer/promoter communication, which is evident from the Drosophila bithorax locus in which a multitude of regulatory elements control segment specific gene activity. Centrosomal protein 190 (CP190) is targeted to insulators by CTCF or other insulator DNA-binding factors. Chromatin analyses revealed that insulators are characterized by open and nucleosome depleted regions. Here, we wanted to identify chromatin modification and remodelling factors required for an enhancer blocking function. We used the well-studied Fab-8 insulator of the bithorax locus to apply a genome-wide RNAi screen for factors that contribute to the enhancer blocking function of CTCF and CP190. Among 78 genes required for optimal Fab-8 mediated enhancer blocking, all four components of the NURF complex as well as several subunits of the dREAM complex were most evident. Mass spectrometric analyses of CTCF or CP190 bound proteins as well as immune precipitation confirmed NURF and dREAM binding. Both co-localise with most CP190 binding sites in the genome and chromatin immune precipitation showed that CP190 recruits NURF and dREAM. Nucleosome occupancy and histone H3 binding analyses revealed that CP190 mediated NURF binding results in nucleosomal depletion at CP190 binding sites. Thus, we conclude that CP190 binding to CTCF or to other DNA binding insulator factors mediates recruitment of NURF and dREAM. Furthermore, the enhancer blocking function of insulators is associated with nucleosomal depletion and requires NURF and dREAM.     

CTCF tethers an insulator to subnuclear sites, suggesting shared insulator mechanisms across species

Insulators can block an enhancer of one gene from activating a promoter on another nearby gene. Almost all described vertebrate insulators require binding of the regulatory protein CTCF for their activity. We show that CTCF copurifies with the nucleolar protein nucleophosmin and both are present at insulator sites in vivo. Furthermore, exogenous insulator sequences are tethered to the nucleolus in a CTCF-dependent manner. These interactions, quite different from those of the gypsy insulator element in Drosophila, may generate similar loop structures, suggesting a common theme and model for enhancer-blocking insulator action.     

Insulation of the ubiquitous Rxrb promoter from the cartilage-specific adjacent gene, Col11a2

The retinoid X receptor beta gene (Rxrb) is located just upstream of the alpha2(XI) collagen chain gene (Col11a2) in a head-to-tail manner. However, the domain structures of these genes are unknown. Col11a2 is specifically expressed in cartilage. In the present study, we found Rxrb expression in various tissues with low expression in the cartilage. Col11a2 1st intron enhancer directed cartilage specific expression when linked to the heterologous promoter in transgenic mice. These results suggest the presence of enhancer-blocking elements that insulate Rxrb promoter from the Col11a2 enhancer. So far, most of insulators examined in vertebrates contain a binding site for CTCF. We found two possible CTCF-binding sites: one (11P) in the intergenic region between Rxrb and Col11a2 by electrophoretic mobility shift assays, and the other in the 4th intron of RXRB by data base search. To examine the function of these elements, we prepared bacterial artificial chromosome (BAC) transgene constructs containing a 142-kb genomic DNA insert with RXRB and COL11A2 sequences in the middle. Mutation of 11P significantly decreased the RXRB promoter activity in muscular cells and significantly increased expression levels of RXRB in chondrosarcoma cells. In transgenic mouse assays, the wild-type BAC transgene partly recapitulated endogenous Rxrb expression patterns. A 507-bp deletion mutation including 11P enhanced the cartilage-specific activity of the RXRB promoter in BAC transgenic mice. Chromatin immunoprecipitation analysis showed that CTCF was associated with RX4, but not with 11P. Our results showed that the intergenic sequence including 11P insulates Rxrb promoter from Col11a2 enhancer, possibly associating with unknown factors that recognize a motif similar to CTCF.     

Many facades of CTCF unified by its coding for three-dimensional genome architecture

CCCTC-binding factor (CTCF) is a multifunctional zinc finger protein that is conserved in metazoan species. CTCF is consistently found to play an important role in many diverse biological processes. CTCF/cohesin-mediated active chromatin ‘loop extrusion’ architects three-dimensional (3D) genome folding. The 3D architectural role of CTCF underlies its multifarious functions, including developmental regulation of gene expression, protocadherin (Pcdh) promoter choice in the nervous system, immunoglobulin (Ig) and T-cell receptor (Tcr) V(D)J recombination in the immune system, homeobox (Hox) gene control during limb development, as well as many other aspects of biology. Here, we review the pleiotropic functions of CTCF from the perspective of its essential role in 3D genome architecture and topological promoter/enhancer selection. We envision the 3D genome as an enormous complex architecture, with tens of thousands of CTCF sites as connecting nodes and CTCF proteins as mysterious bonds that glue together genomic building parts with distinct articulation joints. In particular, we focus on the internal mechanisms by which CTCF controls higher order chromatin structures that manifest its many façades of physiological and pathological functions. We also discuss the dichotomic role of CTCF sites as intriguing 3D genome nodes for seemingly contradictory ‘looping bridges’ and ‘topological insulators’ to frame a beautiful magnificent house for a cell's nuclear home.