Remote homologue identification of Drosophila GAGA factor in mouse

GAGA factor (GAF) is involved in both gene activation and gene repression and plays a role in the modulation of chromatin structure. In Drosophila, Trithroax like (Trl) gene encodes the DNA binding protein called GAGA factor (GAF). Trl-GAF binds to GAGA sites through its C2H2 zinc finger domain and has an N-terminal BTB/POZ domain. Identification of Trl-GAF homologue in mouse helps in deeper understanding of the mechanism and function. Conventional alignment tools such as BLAST and FASTA cannot identify homologues in mouse genome as their sequence identity is below 30%. In the present study, various sequence and structure analyses were followed for the detection of remote homologues of Drosophila GAGA FACTOR in mouse to identify as Zbtb3. Through homology modeling and docking approach, the zinc finger region of mouse Zbtb3 showed conserved residues and favorable DNA binding sites with GAGA sites similar to that of Drosophila GAGA FACTOR.     

Generation and analysis of novel mutations of the trithorax-like gene in Drosophila melanogaster

The Trithorax-like (Trl) gene of Drosophila melanogaster encodes the multifunctional GAGA factor. The expression of Trl is known to depend on numerous factors, such as the organ, the tissue, the ontogenetic stage, and the ambient temperature. Apparently, this expression is controlled by a complex system of regulatory elements, which so far has been scarcely studied. Our preliminary results indicate that the second intron of the Trl gene bears functionally significant elements. To test this assumption, we generated 23 novel alleles of the gene via P-induced male recombination and analyzed them cytogenetically. Of these mutations, 13 (recessive lethals) are deletions, disrupting the coding gene region. Ten mutations (seven deletions and three duplications) remove parts of the second Trl intron only. Some of these mutant stocks exhibit lower viability at different temperatures. These results suggest that the second intron region harbors functionally significant elements. The deletion mapping results verified the localization of the Trl gene in the 70F1-2 region.     

Site-Specific Recognition of a 70-Base-Pair Element Containing d(GA)n Repeats Mediates bithoraxoid Polycomb Group Response Element-Dependent Silencing

Polycomb group proteins act through Polycomb group response elements (PREs) to maintain silencing at homeotic loci. The minimal 1.5-kb bithoraxoid (bxd) PRE contains a region required for pairing-sensitive repression and flanking regions required for maintenance of embryonic silencing. Little is known about the identity of specific sequences necessary for function of the flanking regions. Using gel mobility shift analysis, we identify DNA binding activities that interact specifically with a multipartite 70-bp fragment (MHS-70) downstream of the pairing-sensitive sequence. Deletion of MHS-70 in the context of a 5.1-kb bxd Polycomb group response element derepresses maintenance of silencing in embryos. A partially purified binding activity requires multiple, nonoverlapping d(GA)(3) repeats for MHS-70 binding in vitro. Mutation of d(GA)(3) repeats within MHS-70 in the context of the 5.1-kb bxd PRE destabilizes maintenance of silencing in a subset of cells in vivo but gives weaker derepression than deletion of MHS-70. These results suggest that d(GA)(3) repeats are important for silencing but that other sequences within MHS-70 also contribute to silencing. Antibody supershift assays and Western analyses show that distinct isoforms of Polyhomeotic and two proteins that recognize d(GA)(3) repeats, the TRL/GAGA factor and Pipsqueak (Psq), are present in the MHS-70 binding activity. Mutations in Trl and psq enhance homeotic phenotypes of ph, indicating that TRL/GAGA factor and Psq are enhancers of Polycomb which have sequence-specific DNA binding activity. These studies demonstrate that site-specific recognition of the bxd PRE by d(GA)(n) repeat binding activities mediates PcG-dependent silencing.     

Molecular and genetic description of a new hypomorphic mutation of Trithorax-like gene and analysis of its effect on Drosophila melanogaster oogenesis

The Trithorax-like (Trl) gene of Drosophila melanogaster encodes the multifunctional protein GAGA involved in many cellular processes. We have isolated and described a new hypomorphic mutation of the Trl gene--Trl(en82). The mutation is the insertion of a 1.4 kb P-element into the 5' untranslated region. Trl expression decreased in the ovaries of mutant flies by about 30%; however, it caused abnormalities. The Trl(en82) mutation combined with the null allele of Trl caused female sterility: the females laid a few small eggs with abnormal shape. Many egg chambers demonstrated abnormalities in the Trl(en82) mutants: the oocyte had a regular shape and intruded into the egg chamber region with nurse cells; the rapid transport of nurse cell cytoplasm into the oocyte was disturbed, which resulted in the "dumpless" phenotype of the chambers in mutants; follicular cells often did not completely cover the oocyte and concentrated on its posterior end; and the migration of centripetal cells was affected. We propose that the sterility of the Trl(en82) females is due to the abnormal functioning of follicular cells resulting from low Trl expression. This proposal is confirmed by normalizing the mutant phenotype of Trl(en82) females after the transfection of Trl cDNA. Note that even an insignificant decrease in Trl expression in such females seriously affected the somatic cell functioning, while a significant decrease in its expression in strong hypomorphic mutants affected both somatic and germline cells in the egg chambers.     

GAGA factor and the TFIID complex collaborate in generating an open chromatin structure at the Drosophila melanogaster hsp26 promoter

The upstream regulatory region of the Drosophila melanogaster hsp26 gene includes two DNase I-hypersensitive sites (DH sites) that encompass the critical heat shock elements. This chromatin structure is required for heat shock-inducible expression and depends on two (CT)n*(GA)n elements bound by GAGA factor. To determine whether GAGA factor alone is sufficient to drive formation of the DH sites, we have created flies with an hsp26/lacZ transgene wherein the entire DNA segment known to interact with the TFIID complex has been replaced by a random sequence. The replacement results in a loss of heat shock-inducible hsp26 expression and drastically diminishes nuclease accessibility in the chromatin of the regulatory region. Chromatin immunoprecipitation experiments show that the decrease in TFIID binding does not reduce GAGA factor binding. In contrast, the loss of GAGA factor binding resulting from (CT)n mutations decreases TFIID binding. These data suggest that both GAGA factor and TFIID are necessary for formation of the appropriate chromatin structure at the hsp26 promoter and predict a regulatory mechanism in which GAGA factor binding precedes and contributes to the recruitment of TFIID.