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.     

The GAGA factor of Drosophila interacts with SAP18, a Sin3-associated polypeptide

SAP18, a polypeptide associated with the Sin3–HDAC co-repressor complex, was identified in a yeast two-hybrid screen as capable of interacting with the Drosophila GAGA factor. The interaction was confirmed in vitro by glutathione S-transferase pull-down assays using recombinant proteins and crude SL2 nuclear extracts. The first 245 residues of GAGA, including the POZ domain, are necessary and sufficient to bind dSAP18. In polytene chromosomes, dSAP18 and GAGA co-localize at a few discrete sites and, in particular, at the bithorax complex where GAGA binds some silenced polycomb response elements. When the dSAP18 dose is reduced, flies heterozygous for the GAGA mutation Trl⁶⁷ show the homeotic transformation of segment A6 into A5, indicating that GAGA–dSAP18 interaction contributes to the functional regulation of the iab-6 element of the bithorax complex. These results suggest that, through recruitment of the Sin3–HDAC complex, GAGA might contribute to the regulation of homeotic gene expression.     

Vertebrate Homologue of Drosophila GAGA Factor

Polycomb group (PcG) and trithorax group (trxG) proteins are chromatin-mediated regulators of a number of developmentally important genes including the homeotic genes. In Drosophila melanogaster, one of the trxG members, Trithorax like (Trl), encodes the essential multifunctional DNA binding protein called GAGA factor (GAF). While most of the PcG and trxG genes are conserved from flies to humans, a Trl-GAF homologue has been conspicuously missing in vertebrates. Here, we report the first identification of c-Krox/Th-POK as the vertebrate homologue of GAF on the basis of sequence similarity and comparative structural analysis. The in silico structural analysis of the zinc finger region showed preferential interaction of vertebrate GAF with GAGA sites similar to that of fly GAF. We also show by cross-immunoreactivity studies that both fly and vertebrate GAFs are highly conserved and share a high degree of structural similarity. Electrophoretic mobility shift assays show that vertebrate GAF binds to GAGA sites in vitro. Finally, in vivo studies by chromatin immunoprecipitation confirmed that vertebrate GAF binds to GAGA-rich DNA sequences present in hox clusters. Identification of vertebrate GAF and the presence of its target sites at various developmentally regulated loci, including hox complexes, highlight the evolutionarily conserved components involved in developmental mechanisms across the evolutionary lineage and answer a long-standing question of the presence of vertebrate GAF.     

GAGA protein is essential for male germ cell development in Drosophila

The Drosophila Trithorax‐like (Trl) gene encodes a GAGA factor which regulates a number of developmentally important genes. In this study, we identify a new function for Drosophila GAGA factor in male germ cell development. Trl mutants carrying strong hypomorphic alleles display loss of primordial germ cells during their migration in embryogenesis and severe disruption in mitochondria structure during early spermatogenesis. The mutation resulted in small testes formation, a deficit of germ cells, abnormal mitochondrial morphogenesis, spermatocyte death through autophagy, and partial or complete male sterility. Pleiotropic mutation effects can be explained by the misexpression of GAGA factor target genes, the products of which are required for germ cell progression into mature sperm. genesis 52:738–751, 2014. © 2014 Wiley Periodicals, Inc.     

Histone H1 Genes and Histone Gene Clusters in the Genus Drosophila

Whereas the genomes of many organisms contain several nonallelic types of linker histone genes, one single histone H1 type is known in Drosophila melanogaster that occurs in about 100 copies per genome. Amplification of H1 gene sequences from genomic DNA of wild type strains of D. melanogaster from Oregon, Australia, and central Africa yielded numerous clones that all exhibited restriction patterns identical to each other and to those of the known H1 gene sequence. Nucleotide sequences encoding the evolutionarily variable domains of H1 were determined in two gene copies of strain Niamey from central Africa and were found to be identical to the known H1 sequence. Most likely therefore, the translated sequences of D. melanogaster H1 genes do not exhibit intragenomic or intergenomic variations. In contrast, three different histone H1 genes were isolated from D. virilis and found to encode proteins that differ remarkably from each other and from the H1 of D. melanogaster and D. hydei. About 40 copies of H1 genes are organized in the D. virilis genome with copies of core histone genes in gene quintets that were found to be located in band 25F of chromosome 2. Another type of histone gene cluster is present in about 15 copies per genome and contains a variable intergenic sequence instead of an H1 gene. The H1 heterogeneity in D. virilis may have arisen from higher recombination rates than occur near the H1 locus in D. melanogaster and might provide a basis for formation of different chromatin subtypes. Received: 2 March 2000 / Accepted: 1 June 2000     

Functional conservation of a glucose-repressible amylase gene promoter from Drosophila virilis in Drosophila melanogaster

Summary Previous studies have demonstrated that the expression of the -amylase gene is repressed by dietary glucose in Drosophila melanogaster. Here, we show that the -amylase gene of a distantly related species, D. virilis, is also subject to glucose repression. Moreover, the cloned amylase gene of D. virilis is shown to be glucose repressible when it is transiently expressed in D. melanogaster larvae. This cross-species, functional conservation is mediated by a 330-bp promoter region of the D. virilis amylase gene. These results indicate that the promoter elements required for glucose repression are conserved between distantly related Drosophila species. A sequence comparison between the amylase genes of D. virilis and D. melanogaster shows that the promoter sequences diverge to a much greater degree than the coding sequences. The amylase promoters of the two species do, however, share small clusters of sequence similarity, suggesting that these conserved cis-acting elements are sufficient to control the glucose-regulated expression of the amylase gene in the genus Drosophila.Offprint requests to: D.A. Hickey     

A comparative study of male meiosis in Drosophila melanogaster and D. virilis

Male meiosis in D. melanogaster cytologically follows the usual pattern, whereas in D. melanogaster and in D. virilis oocytes the chromosomes clump into a karyosphere at early meiotic prophase and remain so up to metaphase I.Male meiosis in D. virilis spermatocytes has an intermediate character: a part of the chromatin clumps together in a karyosphere at early prophase, whereas the other part of the chromatin remains diffuse all through prophase. At the end of prophase, the diffuse chromatin becomes integrated into the karyosphere before metaphase I. During the meiotic divisions the chromosomes have the same clumped aspect as those in Drosophila oocytes and thus differ strikingly from the dividing chromosomes in D. melanogaster spermatocytes.In D. virilis spermatocytes the nucleolus exhibits changes during the meiotic prophase that may be related to synthetical activities. The DNA specific staining with the fluorochrome DAPI reveals the existence of extrachromosomal DNA in the later prophase. Other striking differences in meiotic events between the two Drosophila species concern the centrioles and spermiogenesis.     

A functionally conserved boundary element from the mouse HoxD locus requires GAGA factor in Drosophila

Hox genes are necessary for proper morphogenesis and organization of various body structures along the anterior-posterior body axis. These genes exist in clusters and their expression pattern follows spatial and temporal co-linearity with respect to their genomic organization. This colinearity is conserved during evolution and is thought to be constrained by the regulatory mechanisms that involve higher order chromatin structure. Earlier studies, primarily in Drosophila, have illustrated the role of chromatin-mediated regulatory processes, which include chromatin domain boundaries that separate the domains of distinct regulatory features. In the mouse HoxD complex, Evx2 and Hoxd13 are located ～ 9 kb apart but have clearly distinguishable temporal and spatial expression patterns. Here, we report the characterization of a chromatin domain boundary element from the Evx2-Hoxd13 region that functions in Drosophila as well as in mammalian cells. We show that the Evx2-Hoxd13 region has sequences conserved across vertebrate species including a GA repeat motif and that the Evx2-Hoxd13 boundary activity in Drosophila is dependent on GAGA factor that binds to the GA repeat motif. These results show that Hox genes are regulated by chromatin mediated mechanisms and highlight the early origin and functional conservation of such chromatin elements.     

Interspecies comparison of a gene pair with partially redundant function: the rst and kirre genes in D. virilis and D. melanogaster

Abstract The D. melanogaster rst and kirre genes encode two highly related immunoglobulin-like cell adhesion molecules that function redundantly during embryonic muscle development. The two genes appear to be derived from a common ancestor by gene duplication. Gene duplications have been proposed to be of major evolutionary significance since duplicated redundant sequences can accumulate mutations without detrimental effects for the organism and leave the duplicated genes free to assume novel functions. To address the issue of conservation of the duplicated sequences and their putative redundancy, as well as to identify putative functional divergence of the paralogs during drosophilid evolution, we performed an interspecies comparison of the rst and kirre genes from D. virilis and D. melanogaster. The D. virilis genome contains orthologues of both rst and kirre and hence the duplication took place before the split of the two lineages and has subsequently been conserved. However, whilst the Rst orthologues show a high degree of sequence similarity, this similarity is lower in Kirre orthologues. Especially the intracellular domains of D. virilis and D. melanogaster Kirre sequences are highly divergent: the D. virilis kirre gene lacks the 3′-most exon present in D. melanogaster, which contains motifs conserved between kirre and rst in D. melanogaster. Hence, while each of the two genes is highly conserved at the level of its exon-intron organization, the selection forces acting on the rst and kirre coding sequences are different. These findings are discussed in the light of general evolutionary mechanisms.     

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.