In the work reported here we have undertaken a functional dissection of a Polycomb response element (PRE) from the iab-7 cis-regulatory domain of the Drosophila melanogaster bithorax complex (BX-C). Previous studies mapped the iab-7 PRE to an 860-bp fragment located just distal to the Fab-7 boundary. Located within this fragment is an~230-bp chromatin-specific nuclease-hypersensitive region called HS3. We have shown that HS3 is capable of functioning as a Polycomb-dependent silencer in vivo, inducing pairing-dependent silencing of a mini-white reporter. The HS3 sequence contains consensus binding sites for the GAGA factor, a protein implicated in the formation of nucleosome-free regions of chromatin, and Pleiohomeotic (Pho), a Polycomb group protein that is related to the mammalian transcription factor YY1. We show that GAGA and Pho interact with these sequences in vitro and that the consensus binding sites for the two proteins are critical for the silencing activity of the iab-7 PRE in vivo.Segment identity in the posterior two-thirds of the Drosophila melanogaster embryo, from parasegment 5 (PS5) to PS14, is determined by the pattern of expression of the bithorax complex (BX-C) homeotic genes, Ultrabithorax (Ubx), abdominal-A (abd-A), and Abdominal-B (Abd-B) (13,32,39,46). These three homeotic genes are regulated by an elaborate cis-regulatory region that spans a DNA segment of over 300 kb. This large cis-regulatory region is subdivided into nine functionally autonomous domains, abx/bx, bxd/pbx, and iab-2 to iab-8 (2, 9, 29, 32). Each domain specifies the identity of a specific parasegment by activating one of the BX-C homeotic genes in a pattern appropriate for that parasegment. For example, the iab-5 cis-regulatory domain regulates Abd-B expression in a pattern that confers PS10 identity to the cells in this parasegment. Similarly, the iab-6, iab-7, and iab-8 cis-regulatory domains activate Abd-B expression in patterns appropriate for PS11, PS12, and PS13 identity, respectively (5, 9, 45). When one of the BX-C cis-regulatory domains is inactivated, the parasegment specified by the affected regulatory domain is transformed into a copy of the parasegment immediately anterior. Thus, in a deletion that inactivates iab-7, iab-7 Sz , PS12 is transformed into a duplicate copy of PS11 (16). In this case, Abd-B expression in both PS11 and PS12 is driven by the iab-6 cis-regulatory domain.
The three homeotic genes of the bithorax complex (BX-C), Ubx, abd-A and Abd-B control the identity of the posterior thorax and all abdominal segments. Large segment-specific cis-regulatory regions control the expression of Ubx, abd-A or Abd-B in each of the segments. These segment-specific cis-regulatory regions span the whole 300 kb of the BX-C and are arranged on the chromosome in the same order as the segments they specify. Experiments with lacZ reporter constructs revealed the existence of several types of regulatory elements in each of the cis-regulatory regions. These include initiation elements, maintenance elements, cell type-or tissue-specific enhancers, chromatin insulators and the promoter targeting sequence. In this paper, we extend the analysis of regulatory elements within the BX-C by describing a series of internal deficiencies that affect the Abd-B regulatory region. Many of the elements uncovered by these deficiencies are further verified in transgenic reporter assays. Our results highlight four key features of the iab-5, iab-6 and iab-7 cis-regulatory region of Abd-B. First, the whole Abd-B region is modular by nature and can be divided into discrete functional domains. Second, each domain seems to control specifically the level of Abd-B expression in only one parasegment. Third, each domain is itself modular and made up of a similar set of definable regulatory elements. And finally, the activity of each domain is absolutely dependent on the presence of an initiator element.
Eukaryotic chromosomes are thought to be organized into a series of discrete higher-order chromatin domains. This organization is believed to be important not only in the compaction of the chromatin fibre, but also in the utilization of genetic information. Critical to this model are the domain boundaries that delimit and segregate the chromosomes into units of independent gene activity. In Drosophila, such domain boundaries have been identified through two different approaches. On the one hand, elements like scs/scs' and the reiterated binding site for the SU(HW) protein have been characterized through their activity of impeding enhancer-promoter interactions when intercalated between them. Their role of chromatin insulators can protect transgenes from genomic position effects, thereby establishing independent functional domains within the chromosome. On the other hand, domain boundaries of the Bithorax complex (BX-C) like Fab-7 and Mcp have been identified through mutational analysis. Mcp and Fab-7, however, may represent a specific class of boundary elements; instead of separating adjacent domains that contain separate structural genes. Mcp and Fab-7 delimit adjacent cis-regulatory domains, each of which interacts independently with their target promoters. In this article, we review the genetic and molecular characteristics of the domain boundaries of the BX-C. We describe how Fab-7 functions to confine activating as well as repressive signals to the flanking regulatory domains. Although the mechanisms by which Fab-7 works as a domain boundary remain an open issue, we provide preliminary evidence that Fab-7 is not a mere insulator like scs or the reiterated binding site for the SU(HW) protein.
Chromatin domain boundaries, like scs or gypsy insulators in Drosophila, have been identified in transgene assays through their enhancer-blocking activity. Boundary elements in the bithorax complex (BX-C), such as Fab-7 and Fab-8, have been identified genetically and been shown to have insulator activity in transgene assays. However, it is not clear whether boundary elements identified in transgene assays will function appropriately in chromosomal contexts such as BX-C. Using gene conversion, we have substituted the scs or gypsy insulators for Fab-7. We find that both scs and gypsy are very potent insulators in the ectoderm, but surprisingly, the insulating activity of gypsy (but not scs) is lost in the CNS. Our results reveal that the Fab-7 boundary must have special properties that scs and gypsy lack, which allow it to function appropriately in BX-C regulation.
The Drosophila bithorax complex Abdominal-B (Abd-B) gene specifies parasegmental identity at the posterior end of the fly. The specific pattern of Abd-B expression in each parasegment (PS) determines its identity and, in PS10-13, Abd-B expression is controlled by four parasegment-specific cis-regulatory domains, iab-5 to iab-8, respectively. In order to properly determine parasegmental identity, these four cis-regulatory domains must function autonomously during both the initiation and maintenance phases of BX-C regulation. The studies reported here demonstrate that the (centromere) distal end of iab-7 domain is delimited by the Fab-8 boundary. Initiators that specify PS12 identity are located on the proximal iab-7 side of Fab-8, while initiators that specify PS13 identity are located on the distal side of Fab-8, in iab-8. We use transgene assays to demonstrate that Fab-8 has enhancer blocking activity and that it can insulate reporter constructs from the regulatory action of the iab-7 and iab-8 initiators. We also show that the Fab-8 boundary defines the realm of action of a nearby iab-8 Polycomb Response Element, preventing this element from ectopically silencing the adjacent domain. Finally, we demonstrate that the insulating activity of the Fab-8 boundary in BX-C is absolutely essential for the proper specification of parasegmental identity by the iab-7 and iab-8 cis-regulatory domains. Fab-8 together with the previously identified Fab-7 boundary delimit the first genetically defined higher order domain in a multicellular eukaryote.
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