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.     

Flexible interaction of Drosophila Smad complexes with bipartite binding sites

A subset of BMP-responsive enhancer elements are characterized by pairing of a GC-rich Smad1 binding site and an SBE-type Smad4 binding site. Such paired, or bipartite, sites are in some cases just 5 bp apart and thus might be contacted by a single Smad1-Smad4 complex. Other potential pairings are separated as much as 60 bp but it is not known whether such longer distances can be spanned by a Smad1-Smad4 complex, indeed binding of native Smad1-Smad4 complexes to any of these bipartite elements has yet to be reported. Here we report that a complex of the homologous Drosophila Smad proteins, Mad and Medea, is capable of concerted binding to GC-rich and SBE sites separated by as much as 20 bp. The wider the separation, the more severely binding affinity was reduced by shortening of the linker region that tethers the DNA binding domain of Medea. In contrast, length of the Mad linker did not affect the allowed distance between paired sites, rather it contributes specifically to Mad contact with the GC-rich site. Finally, we show that Smad1 and Smad4 can participate in binding to bipartite sites.     

The Drosophila P-element KP repressor protein dimerizes and interacts with multiple sites on P-element DNA.

Drosophila P elements are mobile DNA elements that encode an 87-kDa transposase enzyme and transpositional repressor proteins. One of these repressor proteins is the 207-amino-acid KP protein which is encoded by a naturally occurring P element with an internal deletion. To study the molecular mechanisms by which KP represses transposition, the protein was expressed, purified, and characterized. We show that the KP protein binds to multiple sites on the ends of P-element DNA, unlike the full-length transposase protein. These sites include the high-affinity transposase binding site, an 11-bp transpositional enhancer, and, at the highest concentrations tested, the terminal 31-hp inverted repeats. The DNA binding domain was localized to the N-terminal 98 amino acids and contains a CCHC sequence, a potential metal binding motif. We also demonstrate that the KP repressor protein can dimerize and contains two protein-protein interaction regions and that this dimerization is essential for high-affinity DNA binding.     

The beta 3 tubulin gene is a direct target of bagpipe and biniou in the visceral mesoderm of Drosophila

Previous studies have identified the NK homeobox gene bagpipe and the FoxF fork head domain gene biniou as essential regulators of visceral mesoderm development in Drosophila. Here we present additional genetic and molecular information on the functions of these two genes during visceral mesoderm morphogenesis and differentiation. We show that both genes are required for the activation of beta 3Tub60D in the visceral mesoderm, which encodes beta 3 tubulin. We demonstrate that a 254 bp derivative of a previously defined visceral mesoderm-specific enhancer element, vm1, from beta 3Tub60D contains one specific in vitro binding site for Bagpipe and two such sites for Biniou. While the wild-type version of the 254 bp enhancer is able to drive significant levels of reporter gene expression within the entire trunk visceral mesoderm, mutation of either the Bagpipe or the Biniou binding sites within this element results in a severe decrease of enhancer activity. Moreover, mutation of all three binding sites for Bagpipe and Biniou, respectively, results in the complete loss of enhancer activity. Together, these observations suggest that Bagpipe and Biniou serve as direct, partially redundant, and tissue-specific activators of the terminal differentiation gene beta 3Tub60D in the visceral mesoderm.