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.     

A novel protein activity mediates DNA binding of an ATR-ATRIP complex

The function of the ATR (ataxia-telangiectasia mutated and Rad3-related)-ATRIP (ATR-interacting protein) protein kinase complex is central to the cellular response to replication stress and DNA damage. In order to better understand the function of this complex, we have studied its interaction with DNA. We find that both ATR and ATRIP associate with chromatin in vivo, and they exist as a large molecular weight complex that can bind single-stranded (ss)DNA cellulose in vitro. Although replication protein A (RPA) is sufficient for the recruitment of ATRIP to ssDNA, we show that a distinct ATR-ATRIP complex is able to bind to DNA with lower affinity in the absence of RPA. In this latter complex, we show that neither ATR nor ATRIP are able to bind DNA individually, nor do they bind DNA in a cooperative manner. However, the addition of HeLa nuclear extract is able to reconstitute the DNA binding of both ATR and ATRIP, suggesting the requirement for an additional protein activity. We also show that ATR is necessary for ATRIP to bind DNA in this low affinity mode and to form a large DNA binding complex. These observations suggest that there are at least two in vitro ATR-ATRIP DNA binding complexes, one which binds DNA with high affinity in an RPA-dependent manner and a second, which binds DNA with lower affinity in an RPA-independent manner but which requires an as of yet unidentified protein.     

Decoding cis-regulatory DNAs in the Drosophila genome

Cis-regulatory DNAs control the timing and sites of gene expression during metazoan development. Changes in gene expression are responsible for the morphological diversification of metazoan body plans. However, traditional methods for the identification and characterization of cis-regulatory DNAs are tedious. During the past year, computational methods have been used to identify novel cis-DNAs within the entire Drosophila genome. These methods change the way that cis-DNAs will be analyzed in future studies and offer the promise of unraveling complex gene networks.     

The Mcp element mediates stable long-range chromosome-chromosome interactions in Drosophila

Chromosome organization inside the nucleus is not random but rather is determined by a variety of factors, including interactions between chromosomes and nuclear components such as the nuclear envelope or nuclear matrix. Such interactions may be critical for proper nuclear organization, chromosome partitioning during cell division, and gene regulation. An important, but poorly documented subset, includes interactions between specific chromosomal regions. Interactions of this type are thought to be involved in long-range promoter regulation by distant enhancers or locus control regions and may underlie phenomena such as transvection. Here, we used an in vivo microscopy assay based on Lac Repressor/operator recognition to show that Mcp, a polycomb response element from the Drosophila bithorax complex, is able to mediate physical interaction between remote chromosomal regions. These interactions are tissue specific, can take place between multiple Mcp elements, and seem to be stable once established. We speculate that this ability to interact may be part of the mechanism through which Mcp mediates its regulatory function in the bithorax complex.     

Formation of the BMP activity gradient in the Drosophila embryo

The dorsoventral axis of the Drosophila embryo is patterned by a gradient of bone morphogenetic protein (BMP) ligands. In a process requiring at least three additional extracellular proteins, a broad domain of weak signaling forms and then abruptly sharpens into a narrow dorsal midline peak. Using experimental and computational approaches, we investigate how the interactions of a multiprotein network create the unusual shape and dynamics of formation of this gradient. Starting from observations suggesting that receptor-mediated BMP degradation is an important driving force in gradient dynamics, we develop a general model that is capable of capturing both subtle aspects of gradient behavior and a level of robustness that agrees with in vivo results.     

The novel gene glaikit, is expressed during neurogenesis in the Drosophila melanogaster embryo

A novel gene glaikit (gkt) has been identified which is expressed in the delaminating neuroblasts of the D. melanogaster embryonic central nervous system. At the earliest stages of embryonic development the expression of glaikit was ubiquitous, but by the time the neuroblasts are delaminating gkt expression became restricted to neuroblasts and a few ganglion mother cells. The gkt gene has no characterized homologues and encodes no previously described protein motifs. There are, however, evolutionary conserved predicted genes present in S. pombe, S. cerevisiae and C. elegans. Ectopic neuroblasts induced in either Notch or Delta mutant backgrounds also showed expression of glaikit.     

Using hexamers to predict cis-regulatory motifs in Drosophila

Background  

Cis-regulatory modules (CRMs) are short stretches of DNA that help regulate gene expression in higher eukaryotes. They have been found up to 1 megabase away from the genes they regulate and can be located upstream, downstream, and even within their target genes. Due to the difficulty of finding CRMs using biological and computational techniques, even well-studied regulatory systems may contain CRMs that have not yet been discovered.