Genomic context modulates insulator activity through promoter competition.

Chromatin insulators regulate gene expression by preventing inappropriate enhancer-promoter interactions. Our previous study showed that insulators do not merely function as rigid blockers, rather their activities are quantitative and selective. We have investigated the factors and mechanisms that determine the effectiveness of the suHw insulator in transgenic Drosophila. We show that the suHw-mediated blockage of the AE1 enhancer from a downstream promoter depends on the ability of the promoter to compete for AE1. Promoters that are highly competitive for the enhancer are blocked less effectively. Moreover, blockage of AE1 from its cognate ftz promoter can range from virtually complete to non-detectable, depending on the property of the neighboring upstream promoter. A highly competitive neighboring promoter enhances the suHw-mediated blockage, whereas a less competitive promoter reduces the insulator effectiveness. The influence on insulator effectiveness by both the interacting and the neighboring competing promoters correlates with their ability to compete for the enhancer, which was previously shown to depend on core promoter sequences. Our findings suggest a mechanism at the level of gene organization that modulates insulator effectiveness through promoter competition. The dependence of insulator function on its cis contexts may provide it with more regulatory flexibility while imposing organizational restraints on eukaryotic gene complexes.     

A Functional and Structural Analysis of the Sex Combs Reduced Locus of Drosophila Melanogaster

We have undertaken a developmental genetic analysis of the homeotic gene Sex combs reduced (Scr) of Drosophila melanogaster by examining embryonic and adult phenotypes of mutations affecting Scr gene function. Molecular mapping of Scr breakpoint lesions has defined a segment of greater than 70 kb of DNA necessary for proper Scr gene function. This region is split by the fushi tarazu (ftz) gene, with lesions affecting embryonic Scr function molecularly mapping to the region proximal (5') to ftz and those exhibiting polyphasic semilethality predominantly mapping distal (3') to ftz. Gain-of-function mutations are associated with genomic rearrangements and map throughout the Scr locus. Our analysis has revealed that the Scr locus encompasses genetic elements that are responsible for functions in both the embryonic and larval to adult periods of development. From these studies, we conclude that Scr is a complex genetic locus with an extensive regulatory region that directs functions required for normal head and thoracic development in both the embryo and the adult and that the regulation of Scr during these two periods is distinct.     

Upstream element of the sea urchin arylsulfatase gene serves as an insulator.

Insulator DNAs functionally isolate neighboring genes by blocking interactions between distal cis-regulatory elements and promoters. Here we report that a DNA fragment located in the upstream region of sea urchin, H. pulcherrimus, arylsulfatase (HpArs) gene blocks the interaction of the Ars enhancer when positioned between the enhancer and the target promoter, in an orientation dependent manner. The Ars insulator works only 3' to 5' direction and has no significant stimulatory or inhibitory effects on its own promoter. In transgenic Drosophila, the Ars insulator blocks the interaction between even-skipped stripe enhancer and its target promoter. The insulation mechanism operates also unidirectionally in Drosophila. We also show that the efficiency of transformation of HeLa cells is enhanced when the integrated gene is flanked by the Ars insulator, suggesting the sea urchin insulator overcomes the position-dependent transgene expression in mammalian cells. These results demonstrate that the mechanism of action of the insulator has been conserved throughout evolution.     

Analysis of a fushi tarazu autoregulatory element: multiple sequence elements contribute to enhancer activity.

Regulatory sequences or factors involved in the regulation of target genes of Drosophila homeodomain proteins are largely unknown. Here, we identify sequence elements that are involved in the function of the fushi tarazu (ftz) autoregulatory element AE, a direct in vivo target of the homeodomain protein ftz. A systematic deletion analysis of AE in transgenic embryos defines multiple elements that are redundantly involved in enhancer activity. Sequences juxtaposed to ftz binding sites are not strictly required for enhancer function. Several sequence motifs are conserved in other developmentally regulated genes of Drosophila melanogaster and in the AE homologue of Drosophila virilis. The D. virilis AE is functional in D. melanogaster. The sequence motifs identified here are candidate elements contributing to the target specificity of the homeodomain protein ftz.     

Regulation of the segmentation gene fushi tarazu has been functionally conserved in Drosophila.

An evolutionary approach was applied to identify elements involved in the regulation of the segmentation gene fushi tarazu (ftz) by comparing the Drosophila melanogaster ftz gene with its Drosophila hydei homologue. The overall organization of the ftz gene is very similar in both species. Surprisingly, ftz proved to be inverted in the ANT-C of D. hydei with respect to D. melanogaster. Strong homologies extend over the entire 6 kb of the ftz upstream region with the best match in the 'upstream element'. We identified several highly conserved boxes embedded in unrelated sequences that correspond extremely well to two germ layer specific enhancers in the upstream element. Transformation experiments revealed that D. hydei ftz gene products can restore D. melanogaster ftz function and, furthermore, that trans-acting factors from D. melanogaster recognize and control D. hydei ftz regulatory elements. These findings indicate a conservation of the entire regulatory network among segmentation genes for several millions of years during the evolution of Drosophila.     

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.     

DSP1, a Drosophila HMG protein, is involved in spatiotemporal expression of the homoeotic gene Sex combs reduced

BACKGROUND INFORMATION: The Pc-G (Polycomb group) and trx-G (trithorax group) genes play a key role in the regulation of the homoeotic genes. The homoeotic gene Scr (Sex combs reduced) contained in the Antennapedia complex specifies segmental identity of the labial and prothoracic segments in Drosophila. Regulation of Scr requires the action of different enhancer elements spread over several kilobases. We previously identified an HMGB (high mobility group)-like protein DSP1 (dorsal switch protein 1), which works like a trx-G protein for the normal Scr expression. RESULTS: In the present study, we attempted to characterize the regulatory sequences involved in the maintenance of the Scr activation by DSP1. We report here, using a transgenic line for the Scr10.0XbaI-regulatory element, that lack of DSP1 affects the function of a reporter gene in legs' imaginal discs but not in embryos. We show by immunolocalization that DSP1 is recruited on polytene chromosomes to the insertion site of the transgene. Moreover, using chromatin immunoprecipitation experiments, we identify two regions of 1 kb in Scr10.0XbaI as the main DSP1 targets. CONCLUSION: These results provide strong evidence that the Scr gene expression is influenced by direct interaction between DSP1 and two Scr regulation elements. In addition, our results show that this interaction undergoes dynamic changes during development.     

Drosophila fushi tarazu. a gene on the border of homeotic function

BACKGROUND: Hox genes specify cell fate and regional identity during animal development. These genes are present in evolutionarily conserved clusters thought to have arisen by gene duplication and divergence. Most members of the Drosophila Hox complex (HOM-C) have homeotic functions. However, a small number of HOM-C genes, such as the segmentation gene fushi tarazu (ftz), have nonhomeotic functions. If these genes arose from a homeotic ancestor, their functional properties must have changed significantly during the evolution of modern Drosophila. RESULTS: Here, we have asked how Drosophila ftz evolved from an ancestral homeotic gene to obtain a novel function in segmentation. We expressed Ftz proteins at various developmental stages to assess their potential to regulate segmentation and to generate homeotic transformations. Drosophila Ftz protein has lost the inherent ability to mediate homeosis and functions exclusively in segmentation pathways. In contrast, Ftz from the primitive insect Tribolium (Tc-Ftz) has retained homeotic potential, generating homeotic transformations in larvae and adults and retaining the ability to repress homothorax, a hallmark of homeotic genes. Similarly, Schistocerca Ftz (Sg-Ftz) caused homeotic transformations of antenna toward leg. Primitive Ftz orthologs have moderate segmentation potential, reflected by weak interactions with the segmentation-specific cofactor Ftz-F1. Thus, Ftz orthologs represent evolutionary intermediates that have weak segmentation potential but retain the ability to act as homeotic genes. CONCLUSIONS: ftz evolved from an ancestral homeotic gene as a result of changes in both regulation of expression and specific alterations in the protein-coding region. Studies of ftz orthologs from primitive insects have provided a "snap-shot" view of the progressive evolution of a Hox protein as it took on segmentation function and lost homeotic potential. We propose that the specialization of Drosophila Ftz for segmentation resulted from loss and gain of specific domains that mediate interactions with distinct cofactors.     

黏着素与基因表达调控

黏着素(cohesin)是一种多亚基蛋白复合体,在进化上相当保守。在真核生物细胞中,黏着素主要功能是将复制产生的姐妹染色单体连接在一起,直到细胞分裂的后期,黏着素亚基Scc1水解最终导致染色单体的分离。但是最近研究表明,黏着素在基因表达、染色质结构变化和发育调节等方面也起着非常重要的作用,并且发现黏着素对基因的调节作用与其对染色体的黏着功能无关。在酵母中,黏着素最初定位于其装载蛋白Scc2的DNA结合位点上,但是在细胞周期的G2期,黏着素聚集于转录汇集区之间进而调控转录终止。在果蝇染色体上,黏着素与装载蛋白Scc2的同源物Nipped-B共定位,其作用是阻抑增强子和启动子的远距离接触。而在哺乳动物中,黏着素与CTCF隔离子蛋白共定位,并以依赖于CTCF的方式调控转录。本文概述了黏着素在不同真核生物染色体上的定位与分布,并对其在基因表达调控中的功能机制及其研究现状进行了重点阐述。