Mini-white Gene Research Articles

The white gene controls copulation success in Drosophila melanogaster

Characteristics of male courtship behavior in Drosophila melanogaster have been well-described, but the genetic basis of male-female copulation is largely unknown. Here we show that the white (w) gene, a classical gene for eye color, is associated with copulation success. 82.5% of wild-type Canton-S flies copulated within 60 minutes in circular arenas, whereas few white-eyed mutants mated successfully. The w+ allele exchanged to the X chromosome or duplicated to the Y chromosome in the white-eyed genetic background rescued the defect of copulation success. The w+-associated copulation success was independent of eye color phenotype. Addition of the mini-white (mw+) gene to the white-eyed mutant rescued the defect of copulation success in a manner that was mw+ copy number-dependent. Lastly, male-female sexual experience mimicked the effects of w+/mw+ in improving successful copulation. These data suggest that the w+ gene controls copulation success in Drosophila melanogaster.

Meiotic recombination is suppressed near the histone-defined border of euchromatin and heterochromatin on chromosome 2L ofDrosophila melanogaster

In Drosophila melanogaster, the borders between pericentric heterochromatin and euchromatin on the major chromosome arms have been defined in various ways, including chromatin-specific histone modifications, the binding patterns of heterochromatin-enriched chromosomal proteins, and various cytogenetic techniques. Elucidation of the genetic properties that independently define the different chromatin states associated with heterochromatin and euchromatin should help refine the boundary. Since meiotic recombination is present in euchromatin, but absent in heterochromatin, it constitutes a key genetic property that can be observed transitioning between chromatin states. Using P element insertion lines marked with a su(Hw) insulated mini-white gene, meiotic recombination was found to transition in a region consistent with the H3K9me2 transition observed in ovaries.

Mapping Polycomb Response Elements at the Drosophila melanogaster giant Locus

Polycomb-group (PcG) proteins are highly conserved epigenetic transcriptional regulators. They are capable of either maintaining the transcriptional silence of target genes through many cell cycles or enabling a dynamic regulation of gene expression in stem cells. In Drosophila melanogaster, recruitment of PcG proteins to targets requires the presence of at least one polycomb response element (PRE). Although the sequence requirements for PREs are not well-defined, the presence of Pho, a PRE-binding PcG protein, is a very good PRE indicator. In this study, we identify two PRE-containing regions at the PcG target gene, giant, one at the promoter, and another approximately 6 kb upstream. PRE-containing fragments, which coincide with localized presence of Pho in chromatin immunoprecipitations, were shown to maintain restricted expression of a lacZ reporter gene in embryos and to cause pairing-sensitive silencing of the mini-white gene in eyes. Our results also reinforce previous observations that although PRE maintenance and pairing-sensitive silencing activities are closely linked, the sequence requirements for these functions are not identical.

Distant interactions between enhancers and promoters in Drosophila melanogaster are mediated by transgene-flanking Su(Hw) insulators

Insulators are DNA elements modulating gene activation by enhancers. Interaction between insulators can result in either isolation, or activation of promoter by the enhancer. In the present study, it is demonstrated that in transgenic lines, the yellow enhancers are unable to activate promoter of the tagged gene through the mini-white gene. The mini-white promoter, which functions as an insulator, can block the enhancer activity. In case that the genes and regulatory elements in the construct are flanked by Su(Hw) insulators from retroposon MDG4, interaction between enhancers and the yellow promoter is restored. The data obtained are congruent with the model suggesting that promoters can function as insulators, and that interaction between the insulators facilitates the interaction between enhancers and promoters within transcriptional domain.

Overexpression of kermit/dGIPC is associated with lethality in Drosophila melanogaster

Insertional mutagenesis is an important tool for functional genomics in Drosophila melanogaster. The insertion site in the KG00562 mutant fly line has been mapped to the CG8709 (herein named DmLpin) locus and to the 3’ of kermit (also called dGIPC). This mutant line presents a high lethality rate resulting from a gain of function. To obtain some insight into the biological role of the mutated locus, we have characterized the mutation and its relation to the high mortality of the KG00562 fly line. In this mutant, we did not detect one of the DmLpin transcripts, namely DmLpinK, but we did detect an unusual 2.3-kb mRNA (LpinK-w). Further investigation revealed that the LpinK-w transcript results from an aberrant splicing between the untranslated first exon of DmLpinK and the mini-white marker gene. Lack of DmLpinK or LpinK-w expression does not contribute to lethality, since heterozygous KG00562/Def7860 animals presented lethality rates comparable to those of the wild type. In contrast, the overexpression of kermit was associated with lethality of the KG00562 fly line. Significantly higher levels of kermit were detected in the Malpighian tubules of KG00562/+ flies that presented higher lethality rates than wild-type or KG00562/Def7860 animals, in which the lethality was rescued. In agreement with a recently reported study, our data support the hypothesis that misexpression of kermit/dGIPC could interfere with Drosophila development, with further investigations being needed in this direction.

Overexpression of kermit/dGIPC is associated with lethality in Drosophila melanogaster

Insertional mutagenesis is an important tool for functional genomics in Drosophila melanogaster. The insertion site in the KG00562 mutant fly line has been mapped to the CG8709 (herein named DmLpin) locus and to the 3' of kermit (also called dGIPC). This mutant line presents a high lethality rate resulting from a gain of function. To obtain some insight into the biological role of the mutated locus, we have characterized the mutation and its relation to the high mortality of the KG00562 fly line. In this mutant, we did not detect one of the DmLpin transcripts, namely DmLpinK, but we did detect an unusual 2.3-kb mRNA (LpinK-w). Further investigation revealed that the LpinK-w transcript results from an aberrant splicing between the untranslated first exon of DmLpinK and the mini-white marker gene. Lack of DmLpinK or LpinK-w expression does not contribute to lethality, since heterozygous KG00562/Def7860 animals presented lethality rates comparable to those of the wild type. In contrast, the overexpression of kermit was associated with lethality of the KG00562 fly line. Significantly higher levels of kermit were detected in the Malpighian tubules of KG00562/+ flies that presented higher lethality rates than wild-type or KG00562/Def7860 animals, in which the lethality was rescued. In agreement with a recently reported study, our data support the hypothesis that misexpression of kermit/dGIPC could interfere with Drosophila development, with further investigations being needed in this direction.

Paucity and preferential suppression of transgenes in late replication domains of the D. melanogaster genome

BackgroundEukaryotic genomes are organized in extended domains with distinct features intimately linking genome structure, replication pattern and chromatin state. Recently we identified a set of long late replicating euchromatic regions that are underreplicated in salivary gland polytene chromosomes of D. melanogaster.ResultsHere we demonstrate that these underreplicated regions (URs) have a low density of P-element and piggyBac insertions compared to the genome average or neighboring regions. In contrast, Minos-based transposons show no paucity in URs but have a strong bias to testis-specific genes. We estimated the suppression level in 2,852 stocks carrying a single P-element by analysis of eye color determined by the mini-white marker gene and demonstrate that the proportion of suppressed transgenes in URs is more than three times higher than in the flanking regions or the genomic average. The suppressed transgenes reside in intergenic, genic or promoter regions of the annotated genes. We speculate that the low insertion frequency of P-elements and piggyBacs in URs partially results from suppression of transgenes that potentially could prevent identification of transgenes due to complete suppression of the marker gene. In a similar manner, the proportion of suppressed transgenes is higher in loci replicating late or very late in Kc cells and these loci have a lower density of P-elements and piggyBac insertions. In transgenes with two marker genes suppression of mini-white gene in eye coincides with suppression of yellow gene in bristles.ConclusionsOur results suggest that the late replication domains have a high inactivation potential apparently linked to the silenced or closed chromatin state in these regions, and that such inactivation potential is largely maintained in different tissues.

Drosophila mini-white model system: new insights into positive position effects and the role of transcriptional terminators and gypsy insulator in transgene shielding

The white gene, which is responsible for eye pigmentation, is widely used to study position effects in Drosophila. As a result of insertion of P-element vectors containing mini-white without enhancers into random chromosomal sites, flies with different eye color phenotypes appear, which is usually explained by the influence of positive/negative regulatory elements located around the insertion site. We found that, in more than 70% of cases when mini-white expression was subject to positive position effects, deletion of the white promoter had no effect on eye pigmentation; in these cases, the transposon was inserted into the transcribed regions of genes. Therefore, transcription through the mini-white gene could be responsible for high levels of its expression in most of chromosomal sites. Consistently with this conclusion, transcriptional terminators proved to be efficient in protecting mini-white expression from positive position effects. On the other hand, the best characterized Drosophila gypsy insulator was poorly effective in terminating transcription and, as a consequence, only partially protected mini-white expression from these effects. Thus, to ensure maximum protection of a transgene from position effects, a perfect boundary/insulator element should combine three activities: to block enhancers, to provide a barrier between active and repressed chromatin, and to terminate transcription.

Several copies of insulator from MDG4 can determine the interaction between positively and negatively acting regulatory elements and promoter of the miniwhite gene of Drosophila melanogaster

Fine regulation of complex gene loci in higher eukaryotes is realized through the interaction of promoters with enhancers and repressors, which can be located long distance from the promoter regulated. A question arises, what mechanisms determine proper contacts between the regulatory elements over large distances in the genome. It is suggested that the important role in this process is played by a special class of regulatory elements, insulators, which block the interaction of enhancer and promoter, if they are positioned between them. Furthermore, enhancers do not directly inactivate the activities of enhancer and promoter. Nevertheless, an enhancer, isolated from one of the promoters by an insulator, can activate another, not isolated promoter. The best studied insulator of Drosophila melanogaster was found in the 5' regulatory region of retrotransposon MDG4. It consists of 12 binding sites for the Su(Hw) protein, which is critical for the activity of this insulator. It was demonstrated that Su(Hw) insulator could protect the gene expression from the negative influence of heterochromatin and from repression, induced by the Polycomb group proteins (Pc proteins). In the present study, it was demonstrated that in transgenic lines, two or three copies of the Su(Hw) insulator could determine the interaction of the miniwhite enhancer and Pc dependant silencer with the miniwhite promoter. Thus, it was first demonstrated that insulators could participate in the regulation of the contacts between promoter and functionally opposite elements, responsible for either gene activation, or repression.

Study of functional interaction between three copies of the insulator from the MDG4 transposable element in the model system of the miniwhite gene of Drosophila melanogaster

Study of functional interaction between three copies of the insulator from the MDG4 transposable element in the model system of the miniwhite gene of Drosophila melanogaster

Site-Specific Transformation of Drosophila via ϕC31 Integrase-Mediated Cassette Exchange

Position effects can complicate transgene analyses. This is especially true when comparing transgenes that have inserted randomly into different genomic positions and are therefore subject to varying position effects. Here, we introduce a method for the precise targeting of transgenic constructs to predetermined genomic sites in Drosophila using the C31 integrase system in conjunction with recombinase-mediated cassette exchange (RMCE). We demonstrate the feasibility of this system using two donor cassettes, one carrying the yellow gene and the other carrying GFP. At all four genomic sites tested, we observed exchange of donor cassettes with an integrated target cassette carrying the mini-white gene. Furthermore, because RMCE-mediated integration of the donor cassette is necessarily accompanied by loss of the target cassette, we were able to identify integrants simply by the loss of mini-white eye color. Importantly, this feature of the technology will permit integration of unmarked constructs into Drosophila, even those lacking functional genes. Thus, C31 integrase-mediated RMCE should greatly facilitate transgene analysis as well as permit new experimental designs.

Polycomb group-dependent Cyclin A repression in Drosophila

Polycomb group (PcG) and trithorax group (trxG) proteins are well known for their role in the maintenance of silent and active expression states of homeotic genes. However, PcG proteins may also be required for the control of cellular proliferation in vertebrates. In Drosophila, PcG factors act by associating with specific DNA regions termed PcG response elements (PREs). Here, we have investigated whether Drosophila cell cycle genes are directly regulated by PcG proteins through PREs. We have isolated a PRE that regulates Cyclin A (CycA) expression. This sequence is bound by the Polycomb (PC) and Polyhomeotic (PH) proteins of the PcG, and also by GAGA factor (GAF), a trxG protein that is usually found associated with PREs. This sequence causes PcG- and trxG-dependent variegation of the mini-white reporter gene in transgenic flies. The combination of FISH with PC immunostaining in embryonic cells shows that the endogenous CycA gene colocalizes with PC at foci of high PC concentration named PcG bodies. Finally, loss of function of the Pc gene and overexpression of Pc and ph trigger up-regulation and down-regulation, respectively, of CycA expression in embryos. These results demonstrate that CycA is directly regulated by PcG proteins, linking them to cell cycle control in vivo.

Interaction between Su(Hw) insulators regulates cis- and trans- activity of the miniwhite gene enhancer

Interaction between Su(Hw) insulators regulates cis- and trans- activity of the miniwhite gene enhancer

Analysis of the Effect of the Su(Hw) Insulator on the Expression of the miniwhite Gene in Drosophila melanogaster

Analysis of the Effect of the Su(Hw) Insulator on the Expression of the miniwhite Gene in Drosophila melanogaster

Telomeric associated sequences of Drosophila recruit polycomb-group proteins in vivo and can induce pairing-sensitive repression.

In Drosophila, relocation of a euchromatic gene near centromeric or telomeric heterochromatin often leads to its mosaic silencing. Nevertheless, modifiers of centromeric silencing do not affect telomeric silencing, suggesting that each location requires specific factors. Previous studies suggest that a subset of Polycomb-group (PcG) proteins could be responsible for telomeric silencing. Here, we present the effect on telomeric silencing of 50 mutant alleles of the PcG genes and of their counteracting trithorax-group genes. Several combinations of two mutated PcG genes impair telomeric silencing synergistically, revealing that some of these genes are required for telomeric silencing. In situ hybridization and immunostaining experiments on polytene chromosomes revealed a strict correlation between the presence of PcG proteins and that of heterochromatic telomeric associated sequences (TASs), suggesting that TASs and PcG complexes could be associated at telomeres. Furthermore, lines harboring a transgene containing an X-linked TAS subunit and the mini-white reporter gene can exhibit pairing-sensitive repression of the white gene in an orientation-dependent manner. Finally, an additional binding site for PcG proteins was detected at the insertion site of this type of transgene. Taken together, these results demonstrate that PcG proteins bind TASs in vivo and may be major players in Drosophila telomeric position effect (TPE).

Stellate repeats: targets of silencing and modules causing cis-inactivation and trans-activation.

The mechanism of silencing of testis expressed X-linked Stellate repeats by homologous Y-linked Suppressor of Stellate [Su(Ste)] repeats localized in the crystal locus was studied. The double stranded RNA as a product of symmetrical transcription of Su(Ste) repeat and small interference Su(Ste) siRNA were revealed suggesting the mechanism of RNA interference (RNAi) for Stellate silencing. The relief of Stellate silencing as a result of impaired complementarity between the sequences of putative target Stellate transcripts and Su(Ste) repeats was shown. The role of RNAi mechanism in the silencing of heterochromatic retrotransposon GATE inserted in Stellate cluster was revealed. The studies of cis-effects of Stellate tandem repeats causing variegated expression of juxtaposed reporter genes were extended and the lacZ variegation in imaginal disc was shown. The exceptional case of a non-variegated expression of mini-white gene juxtaposed to Stellate repeats in a construct inserted into the 39C region was shown to be accompanied by trans-activation in homozygous state. Trans-activation effect was retained after transposition of this construct into heterochromatic environment in spite of strong variegation of a mini-white gene.

Inactivation of reporter genes by cloned heterochromatic repeats of Drosophila melanogaster is accompanied by chromatin compaction

Cloned Stellate heterochromatic repeats caused unstable mosaic inactivation (position effect variegation; PEV) of the reporter gene mini-white. A number of known protein modifiers of the classical position effect induced by large heterochromatin blocks do not affect the expression of mini-white. This raises the question as to the specificity of chromatin compaction around the reporter gene. The inactivation of the mini-white gene has been found to be accompanied by a decrease in its methylation catalyzed by Escherichia coli dam-methyltransferase expressed in the genome of Drosophila. However, no changes in the nucleosome organization of mini-white have been found.

Use of mini-white as a reporter gene to screen for GAL4 insertions with spatially restricted expression pattern in the developing eye in drosophila.

We have previously used mini-white as a reporter gene in an enhancer trap screen to identify enhancers/silencers that specify spatially restricted expression patterns during Drosophila eye development (Sun et al., 1995). The mini-white gene carries its own eye-specific enhancer (Pirrotta et al., 1988), therefore causing uniform eye pigmentation. In rare cases, the P[mini-white] insertions cause a spatially restricted pigmentation pattern in the adult eye (Sun et al., 1995), suggesting that the mini-white enhancer activity can be suppressed by local silencer activities. The spatial expression pattern is likely a net effect of local enhancers and silencers. The screen yielded more than 20 loci with a position-specific expression (POSE) pattern in the developing eye (Sun et al., 1995). In this study, we employed the same strategy to screen for GAL4 insertion lines with a POSE pattern in the developing eye. We induced P[GawB] or P[hs-GAL4] (Brand and Perrimon, 1993) transposition from several independent starting chromosomal locations to avoid bias in transposition preference. A total of about 420,000 flies were screened and 22 lines with nonuniform eye pigmentation patterns were isolated. One line (Notch) was identified by a notched wing phenotype. Three of the lines showed no GAL4 expression pattern. Nineteen lines showed specific expression patterns in the eye disc (Fig. 1), indicating that the mini-white-based screen is an efficient screening method. The GAL4 lines were named based on their pattern of eye pigmentation (Table 1, Fig. 1). The site of insertions was mapped by segregation analysis, followed by plasmid rescue to clone the flanking genomic fragment and sequencing the ends of the rescued fragments (Table 1). The nearest gene is indicated (Table 1). In four lines (AG2, PDM1, Cir2, and Cwh1), plasmid rescue using multiple restriction enzymes failed to recover any genomic fragment, suggesting that the P-element has undergone some deletion or rearrangement. Eleven of the lines are homozygous lethal or semilethal. Two lines have dominant phenotypes: VG1 has a grooved notum (Fig. 4a), and Notch has notched wings (not shown). Insertions into Notch (N), four jointed ( fj), wingless (wg), optomototr-blind (omb), homothorax (hth), and patched (ptc) that caused mutant phenotypes were confirmed by complementation tests with known mutant alleles (see Table legend). Kruppel (Kr), hth, and omb each have two insertion lines, indicating that these are hot spots for P insertions. Multiple insertions in hth and omb were also isolated in our previous screen (Sun et al., 1995). The P5 line has an insertion within the hth locus, but the lethality was complemented by hth and hth, and the lethality may thus be caused by a second site mutation. The two insertions into Kr are located in the same position (Table 1), but one (AG1) caused no phenotype, while the other (AM1) is homozygous semilethal, suggesting that the two lines may differ in some rearrangement or deletion in the region flanking the insertion. Similarly, omb1 and omb3 are also inserted in the same position upstream of omb but caused different phenotypes (Table 1). The GAL4s were crossed to UAS-lacZ and the expression patterns in embryos, third instar larval imaginal discs (Fig. 1, 2), and in adult testes and ovaries (Fig. 3) were examined. When the GAL4 is inserted in or near a gene with a published expression pattern, the expression patterns were compared. In AG1 and AM1, the GAL4 is inserted in a region near the telomere that has a very low gene density. The closest gene is Kr, which is about 30 kb away. The AG1 and AM1 lines show similar expression patterns. The embryonic expression is similar to the expression of Kr in the Bolwig organ (Schmucker et al., 1992). In Notch, the insertion is within the N gene, but the expression pattern is dissimilar to that of N (Kidd et al., 1989). In VG1, the GAL4 is inserted within the fj gene, and the expression pattern is similar to that of fj (Villano and Katz, 1995; Brodsky and Steller, 1996). In A4, the GAL4 insertion is 749 bp upstream of tiptop, which has no reported expression pattern. The expression pattern in wing and leg discs is similar to that of teashirt (tsh; Erkner et al., 1999;

A complex array of DNA-binding proteins required for pairing-sensitive silencing by a polycomb group response element from the Drosophila engrailed gene.

Regulatory DNA from the Drosophila gene engrailed causes silencing of a linked reporter gene (mini-white) in transgenic Drosophila. This silencing is strengthened in flies homozygous for the transgene and has been called "pairing-sensitive silencing." The pairing-sensitive silencing activities of a large fragment (2.6 kb) and a small subfragment (181 bp) were explored. Since pairing-sensitive silencing is often associated with Polycomb group response elements (PREs), we tested the activities of each of these engrailed fragments in a construct designed to detect PRE activity in embryos. Both fragments were found to behave as PREs in a bxd-Ubx-lacZ reporter construct, while the larger fragment showed additional silencing capabilities. Using the mini-white reporter gene, a 139-bp minimal pairing-sensitive element (PSE) was defined. DNA mobility-shift assays using Drosophila nuclear extracts suggested that there are eight protein-binding sites within this 139-bp element. Mutational analysis showed that at least five of these sites are important for pairing-sensitive silencing. One of the required sites is for the Polycomb group protein Pleiohomeotic and another is GAGAG, a sequence bound by the proteins GAGA factor and Pipsqueak. The identity of the other proteins is unknown. These data suggest a surprising degree of complexity in the DNA-binding proteins required for PSE function.

Molecular analysis of novel Drosophila gene, Gap69C, encoding a homolog of ADP-ribosylation factor GTPase-activating protein.

Adenosine diphosphate-ribosylation factor, ARF1, regulates membrane traffic and structure in the endoplasmic reticulum-Golgi and endosomal systems. The ARF activity, in turn, is regulated by the guanine nucleotide exchange factors and GTPase-activating proteins (GAPs). We have cloned by transposon tagging a novel Drosophila gene, Gap69C, coding for a putative homolog of ARF1 GTPase-activating protein. The GAP69C protein shares an extensive similarity within its N-terminal zinc-finger domain with the rat and yeast homologs. This domain is known to be required for ARF-GAP activity. The Gap69C is a single-copy gene producing a major 2.1-kb mRNA throughout development, but its amount is decreased in larvae. The eye pigmentation produced by the reporter mini-white gene inserted into the 5' UTR of Gap69C suggests that the expression of Gap69C is nonuniform. In situ hybridization revealed a high level of Gap69C transcripts in the morphogenetic furrow of the eye imaginal disc, where cells are arrested in G(1). Generated by the excision of the P-element, the null allele of Gap69C was found to be viable and fertile and showed no apparent abnormal phenotype, indicating that Gap69C is not essential for fly development. Analysis of the Drosophila genome sequence revealed the presence of other genes related to Gap69C. We propose that the absence of a distinctive phenotype in Gap69C null mutants is attributable to redundancy with other homologs.