The Drosophila eve Insulator Homie Promotes eve Expression and Protects the Adjacent Gene from Repression by Polycomb Spreading

Insulators can block the action of enhancers on promoters and the spreading of repressive chromatin, as well as facilitating specific enhancer-promoter interactions. However, recent studies have called into question whether the activities ascribed to insulators in model transgene assays actually reflect their functions in the genome. The Drosophila even skipped (eve) gene is a Polycomb (Pc) domain with a Pc-group response element (PRE) at one end, flanked by an insulator, an arrangement also seen in other genes. Here, we show that this insulator has three major functions. It blocks the spreading of the eve Pc domain, preventing repression of the adjacent gene, TER94. It prevents activation of TER94 by eve regulatory DNA. It also facilitates normal eve expression. When Homie is deleted in the context of a large transgene that mimics both eve and TER94 regulation, TER94 is repressed. This repression depends on the eve PRE. Ubiquitous TER94 expression is “replaced” by expression in an eve pattern when Homie is deleted, and this effect is reversed when the PRE is also removed. Repression of TER94 is attributable to spreading of the eve Pc domain into the TER94 locus, accompanied by an increase in histone H3 trimethylation at lysine 27. Other PREs can functionally replace the eve PRE, and other insulators can block PRE-dependent repression in this context. The full activity of the eve promoter is also dependent on Homie, and other insulators can promote normal eve enhancer-promoter communication. Our data suggest that this is not due to preventing promoter competition, but is likely the result of the insulator organizing a chromosomal conformation favorable to normal enhancer-promoter interactions. Thus, insulator activities in a native context include enhancer blocking and enhancer-promoter facilitation, as well as preventing the spread of repressive chromatin.     

Several copies of insulator from MDG4 can determine the interaction between positively and negatively acting regulatory elements and promoter of the miniwhite gene of Drosophila melanogaster

Fine regulation of complex gene loci in higher eukaryotes is realized through the interaction of promoters with enhancers and repressors, which can be located long distance from the promoter regulated. A question arises, what mechanisms determine proper contacts between the regulatory elements over large distances in the genome. It is suggested that the important role in this process is played by a special class of regulatory elements, insulators, which block the interaction of enhancer and promoter, if they are positioned between them. Furthermore, enhancers do not directly inactivate the activities of enhancer and promoter. Nevertheless, an enhancer, isolated from one of the promoters by an insulator, can activate another, not isolated promoter. The best studied insulator of Drosophila melanogaster was found in the 5′ regulatory region of retrotransposon MDG4. It consists of 12 binding sites for the Su(Hw) protein, which is critical for the activity of this insulator. It was demonstrated that Su(Hw) insulator could protect the gene expression from the negative influence of heterochromatin and from repression, induced by the Polycomb group proteins (Pc proteins). In the present study, it was demonstrated that in transgenic lines, two or three copies of the Su(Hw) insulator could determine the interaction of the miniwhite enhancer and Pc dependant silencer with the miniwhite promoter. Thus, it was first demonstrated that insulators could participate in the regulation of the contacts between promoter and functionally opposite elements, responsible for either gene activation, or repression. Original Russian Text ? M.V. Kostyuchenko, E.E. Savitskaya, M.N. Krivega, P.G. Georgiev, 2008, published in Genetika, 2008, Vol. 44, No. 12, pp. 1693–1697.     

Multiple Promoter Targeting Sequences exist in Abdominal-B to regulate long-range gene activation

In complex genomes, insulators set up chromatin domain boundaries and protect promoters from inappropriate activation by enhancers from neighboring genes. The Drosophila Abdominal-B locus uses insulator elements to organize its large regulatory region into several body segment-specific chromatin domains. This organization leads to a problem in enhancer-promoter communication, that is, how do distal enhancers activate the Abd-B promoter when there are several insulators in between? This issue is partially resolved by the Promoter Targeting Sequence, which can overcome the enhancer blocking effect of an insulator. In this study, we describe a new Promoter Targeting Sequence, PTS-6, from the Abd-B 3' regulatory region. PTS-6, comprised of approximately 200 bp, was found to bypass both homologous Abdominal-B insulators, such as Fab-7 and Fab-8, and a heterologous insulator, suHw. Most importantly, it also overcomes a combination of two insulators such as Fab-7/Fab-8. Thus, PTS-6 could, in principle, target remote enhancers that are separated from the Abd-B promoter by multiple insulators. In addition, PTS-6 selectively targets the distal enhancer to only one transgenic promoter, and it strongly facilitates Abd-B enhancers. These results suggest that promoter targeting is necessary for long-range enhancer-promoter communication in Abd-B, and PTS elements could be a common occurrence in large, complex genetic loci.     

The Mcp element from the bithorax complex contains an insulator that is capable of pairwise interactions and can facilitate enhancer-promoter communication

Chromatin insulators, or boundary elements, appear to control eukaryotic gene expression by regulating interactions between enhancers and promoters. Boundaries have been identified in the 3' cis-regulatory region of Abd-B, which is subdivided into a series of separate iab domains. Boundary elements such as Mcp, Fab-7, and Fab-8 and adjacent silencers flank the iab domains and restrict the activity of the iab enhancers. We have identified an insulator in the 755-bp Mcp fragment that is linked to the previously characterized Polycomb response element (PRE) and silences the adjacent genes. This insulator blocks the enhancers of the yellow and white genes and protects them from PRE-mediated repression. The interaction between the Mcp elements, each containing the insulator and PRE, allows the eye enhancer to activate the white promoter over the repressed yellow domain. The same level of white activation was observed when the Mcp element combined with the insulator alone was interposed between the eye enhancer and the promoter, suggesting that the insulator is responsible for the interaction between the Mcp elements.     

Chromatin insulator and the promoter targeting sequence modulate the timing of long-range enhancer-promoter interactions in the Drosophila embryo

The homeotic genes are essential to the patterning of the anterior-posterior axis along the developing Drosophila embryo. The expression timing and levels of these genes are crucial for the correct specification of segmental identity. The Abdominal-B (Abd-B) gene is first detected in the most posterior abdominal segments at high levels and gradually appears in progressively anterior abdominal segments in lower amounts. Regulatory mutations affecting this expression pattern produce homeotic transformations in the abdomen. The promoter targeting sequences (PTS) from Abd-B locus overcome the enhancer blocking effect of insulators and facilitate long-range enhancer-promoter interactions in transgenic flies (1, 2). In this study, we found that transgene activation by the IAB5 enhancer can be delayed by inserting a 9.5 kb 3′ Abd-B regulatory region containing the Frontabdominal-8 (Fab-8) insulator and the PTS element. We found that the delay is caused by the PTS and an insulator, and it is not specific to the enhancer or the promoter tested. Based on these findings, we hypothesize that the delay of remote enhancers is responsible for the Abd-B expression pattern, which is at least in part due to the regulatory activities of the PTS elements and chromatin boundaries.     

The β-phaseolin 5′ matrix attachment region acts as an enhancer facilitator

MARs found flanking the -phaseolin gene (phas) were tested for insulating activity in an enhancer blocking assay. True insulators should block enhancer dependent expression of a reporter gene when placed between the enhancer and a promoter. Insertion of phas 3 MAR or coding sequences lowered CaMV 35S enhancer driven GUS expression from the phas basal promoter, indicating a distance dependence of the 35S enhancer. 5 MAR or 5 MAR core fragments could not act as independent enhancers when fused to the phas basal promoter, and did not lower expression when inserted in the enhancer blocking assay construct, indicating that they facilitated 35S enhancer expression at a distance when located between the enhancer and the promoter.     

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.     

Drosophila gypsy insulator and yellow enhancers regulate activity of yellow promoter through the same regulatory element

There is ample evidence that the enhancers of a promoterless yellow locus in one homologous chromosome can activate the yellow promoter in the other chromosome where the enhancers are inactive or deleted, which is indicative of a high specificity of the enhancer–promoter interaction in yellow. In this paper, we have found that the yellow sequence from −100 to −69 is essential for stimulation of the heterologous eve (TATA-containing) and white (TATA-less) promoters by the yellow enhancers from a distance. However, the presence of this sequence is not required when the yellow enhancers are directly fused to the heterologous promoters or are activated by the yeast GAL4 activator. Unexpectedly, the same promoter proximal region defines previously described promoter-specific, long-distance repression of the yellow promoter by the gypsy insulator on the mod(mdg4) ^u1 background. These finding suggest that proteins bound to the −100 to −69 sequence are essential for communication between the yellow promoter and upstream regulatory elements.     

hairy mediates dominant repression in the Drosophila embryo.

hairy encodes a bHLH repressor that regulates several developmental processes in Drosophila, including embryonic segmentation and neurogenesis. Segmentation repressors such as Krüppel and knirps have been shown to function over short distances, less than 50-100 bp, to inhibit or quench closely linked upstream activators. This mode of repression permits multiple enhancers to work independently of one another within a modular promoter. Here, we employ a transgenic embryo assay to present evidence that hairy acts as a dominant repressor, which can function over long distances to block multiple enhancers. hairy is shown to repress a heterologous enhancer, the rhomboid NEE, when bound 1 kb from the nearest upstream activator. Moreover, the binding of hairy to a modified NEE leads to the repression of both the NEE and a distantly linked mesoderm-specific enhancer within a synthetic modular promoter. Additional evidence that hairy is distinct from previously characterized embryonic repressors stems from the analysis of the gypsy insulator DNA. This insulator selectively blocks the hairy repressor, but not the linked activators, within a modified NEE. We compare hairy with previously characterized repressors and discuss the consequences of short-range and long-range repression in development.     

1A2 Insulator can interact with promoter of hsp70 gene in D. melanogaster

Insulators are regulatory DNA elements that participate in the modulation of the interactions between enhancers and promoters. Depending on the situation, insulators can either stabilize or destroy the contacts between enhancers and promoters. A possible explanation for the activity of insulators is their ability to directly interact with gene promoters. In the present study, it was demonstrated that, in model systems, a 1A2 insulator could interact with the core sequence of an hsp70 promoter. In this case, the insulator protein CP190 is found on the hsp70 promoter, which depends on the presence of an insulator in the transgene. The data obtained are consistent with the model, which implies that direct contacts between insulators and promoters make a considerable contribution to the modulation of the interactions between insulators and promoters.