Physical map of the white locus of Drosophila melanogaster.

Levis, Robert; Bingham, Paul M.; Rubin, Gerald M.

doi:10.1073/pnas.79.2.564

Cited by 94 publications

(26 citation statements)

References 24 publications

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“…The mod(mdg4) bpd1 and mod(mdg4) bpdEX57 mutations were balanced over In(3LR)TM6,Tb ubi-GFP (provided by Kathryn Anderson, Sloan-Kettering Institute, New York, N.Y.), and homozygous mutant embryos and larvae lacking green fluorescent protein were collected using a fluorescence dissection microscope. Genomic DNA was prepared as described elsewhere (37). Genomic DNA samples were analyzed for the presence or absence of specific sequences by PCR using several different primers.…”

Section: Methodsmentioning

confidence: 99%

Insulation of Enhancer-Promoter Communication by a Gypsy Transposon Insert in the Drosophila cut Gene: Cooperation between Suppressor of Hairy-wing and Modifier of mdg4 Proteins

Gause

Morcillo

Dorsett

2001

Molecular and Cellular Biology

125

126

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The Drosophila mod(mdg4) gene products counteract heterochromatin-mediated silencing of the white gene and help activate genes of the bithorax complex. They also regulate the insulator activity of the gypsy transposon when gypsy inserts between an enhancer and promoter. The Su(Hw) protein is required for gypsymediated insulation, and the Mod(mdg4)-67.2 protein binds to Su(Hw). The aim of this study was to determine whether Mod(mdg4)-67.2 is a coinsulator that helps Su(Hw) block enhancers or a facilitator of activation that is inhibited by Su(Hw). Here we provide evidence that Mod(mdg4)-67.2 acts as a coinsulator by showing that some loss-of-function mod(mdg4) mutations decrease enhancer blocking by a gypsy insert in the cut gene. We find that the C terminus of Mod(mdg4)-67.2 binds in vitro to a region of Su(Hw) that is required for insulation, while the N terminus mediates self-association. The N terminus of Mod(mdg4)-67.2 also interacts with the Chip protein, which facilitates activation of cut. Mod(mdg4)-67.2 truncated in the C terminus interferes in a dominant-negative fashion with insulation in cut but does not significantly affect heterochromatin-mediated silencing of white. We infer that multiple contacts between Su(Hw) and a Mod(mdg4)-67.2 multimer are required for insulation. We theorize that Mod(mdg4)-67.2 usually aids gene activation but can also act as a coinsulator by helping Su(Hw) trap facilitators of activation, such as the Chip protein.

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Section: Methodsmentioning

confidence: 99%

Insulation of Enhancer-Promoter Communication by a Gypsy Transposon Insert in the Drosophila cut Gene: Cooperation between Suppressor of Hairy-wing and Modifier of mdg4 Proteins

Gause

Morcillo

Dorsett

2001

Molecular and Cellular Biology

125

126

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“…Drosophila Oregon R genomic DNA was prepared as described by Levis et al (34). Ten micrograms of genomic DNA was digested with restriction endonuclease EcoRI, BglII, or HindIII and electrophoresed through a 0.8% agarose gel (10 by 6 cm) for 400 V-h.…”

Section: Methodsmentioning

confidence: 99%

Isolation of cDNAs encoding the Drosophila GAGA transcription factor.

1993

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To investigate the mechanisms involved in expression of the Drosophila melanogaster engrailed gene, we purified GAGA protein, one of several putative transcriptional activator proteins that binds to the proximal region of the engrailed promoter. Antibodies raised against GAGA protein were used to demonstrate that the protein is present in all nuclei of young embryos. We isolated cDNA clones encoding GAGA protein in which a putative 519-codon open reading frame contains general sequence motifs characteristic of other transcription factors. These include stretches of polyglutamine, a 60-amino-acid region with 18 (30%o) lysine or arginine residues, and a single putative zinc finger motif. In addition, a 120-residue N-terminal region shares significant sequence homology with several other known Drosophila transcription factors, including those encoded by Broad Complex and tramtrack. Up to 35-fold GAGA protein-dependent stimulation of transcription in Schneider line 2 tissue culture cells was observed after transfection of GAGA protein-encoding sequences. The GAGA gene is present in one copy in the Drosophila genome, at cytological location 70EF, and it encodes RNAs which vary in size between 2.4 and 4.4 kb.Many of the gene products that organize the Drosophila melanogaster embryo are expressed in restricted domains, and their accurate deployment is critical to normal development. Among these is engrailed, a homeodomain-containing protein that is expressed in a subset of the ectoderm and neuroectoderm. In gastrulating embryos, cells containing engrailed protein are in 15 concentric, single-cell-wide rings (15,19,29), and the presence of functional engrailed protein in these cells and in the posterior compartments that are populated by their descendants contributes to processes that form and maintain the segments and compartments.Genetic analysis has implicated the pair-rule segmentation genes even-skipped (eve) and fushi tarazu (ftz) in activating engrailed transcription in the gastrulating embryo (reviewed by Lawrence [31]). Genes that have been implicated in its subsequent regulation include engrailed itself (16), Polycomb (9,39), and wingless (3,16,38). It is not known whether the action of the protein products of any of these genes on engrailed regulation is direct, although logic might suggest that eve and ftz proteins, both of which are homeodomain-containing transcription factors, directly activate engrailed transcription in the gastrulating embryo. However, there is little direct evidence to suggest that these or other transcription factors act directly on the engrailed promoter. In vitro studies have identified sequences in the engrailed 5' upstream region that bind eve and ftz proteins (23), and engrailed is activated in a pattern that corresponds precisely with the anterior borders of the eve and ftz stripes (32). However, functional studies of the engrailed promoter failed to identify the eve and ftz binding sites in the engrailed upstream region as important sequences for regulation (10), and the respons...

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“…Plasmids pMG1 and pMG2 ( Fig. 1) were constructed by inserting the PvuII (white nucleotide 11078)-SalI (position 11867) DNA fragments from plasmids pml2.5 (35) and pClLTR (46), respectively, between the SmaI and SalI sites of the vector pIBI24 (International Biotechnologies, Inc.), downstream of the promoter for T7 RNA polymerase. The resulting clones contained portions of the second and third exons of the wild-type white gene with either the wild-type second intron (pMG1) or the same intron carrying an sLTR insertion (pMG2).…”

Section: Methodsmentioning

confidence: 99%

Species-specific signals for the splicing of a short Drosophila intron in vitro.

Guo

Mount

1993

Mol. Cell. Biol.

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The effects of branchpoint sequence, the pyrimidine stretch, and intron size on the splicing efficiency of the Drosophila white gene second intron were examined in nuclear extracts from Drosophila and human cells. This 74-nucleotide intron is typical of many Drosophila introns in that it lacks a significant pyrimidine stretch and is below the minimum size required for splicing in human nuclear extracts. Alteration of sequences adjacent to the 3' splice site to create a pyrimidine stretch was necessary for splicing in human, but not Drosophila, extracts. Increasing the size of this intron with insertions between the 5' splice site and the branchpoint greatly reduced the efficiency of splicing of introns longer than 79 nucleotides in Drosophila extracts but had an opposite effect in human extracts, in which introns longer than 78 nucleotides were spliced with much greater efficiency. The white-apricot copia insertion is immediately adjacent to the branchpoint normally used splice site is a pyrimidine-rich region. The way in which sequences at the 5' splice site, the branchpoint, the pyrimidine-rich stretch, and the 3' splice site act together in mammalian splicing to specify intron boundaries has been investigated in detail, and much is known of the factors that recognize these sites. For example, the 5' splice site is recognized by the Ul small nuclear ribonucleoprotein (sn-RNP) via base pairing in both mammals and in yeasts (8,34,47,76,78,90), and the branchpoint is similarly recognized by the U2 snRNP (50,58,84,89,91). Binding of the U2 snRNP to the branchpoint requires a number of factors, including the Ul snRNP (2, 67, 75) and U2AF, a factor that binds to the pyrimidine-rich stretch (70).Despite the relatively large amount that is known about the sequence requirements for splicing, it is still not possible to accurately predict the positions of introns from sequence information alone, and the basis of alternative, or regulated, splicing is still being elucidated. The genetics of Drosophila melanogaster has allowed regulatory factors to be identified for several examples of alternative splicing (4,10,11,41,49,85), and it appears that this organism will prove useful for the (25,51,57). In contrast, the branchpoint sequence of mammalian introns has greater flexibility (26,28,50,65,69,88), and the pyrimidine-rich stretch is more important (13,64,68 (5,15,56,60). In We, the level of normally spliced mRNA is greatly reduced, and a number of aberrant RNAs that are polyadenylated within copia are observed (36,46,61,86). Interest in we derives from the existence of mutations in unlinked genes which alter its expression, resulting in increased or decreased eye pigmentation (6,7,11,38,59,62,81,85). Correlation of the structure of a number of derivatives of wa with their phenotypes, the RNAs that they produce, and their response to genetic modifiers has led to the conclusion that there is competition between polyadenylation within copia and the splicing of this intron (31). Furthermore, it appears that the copia inser...

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Physical map of the white locus of Drosophila melanogaster.

Cited by 94 publications

References 24 publications

Insulation of Enhancer-Promoter Communication by a Gypsy Transposon Insert in the Drosophila cut Gene: Cooperation between Suppressor of Hairy-wing and Modifier of mdg4 Proteins

Insulation of Enhancer-Promoter Communication by a Gypsy Transposon Insert in the Drosophila cut Gene: Cooperation between Suppressor of Hairy-wing and Modifier of mdg4 Proteins

Isolation of cDNAs encoding the Drosophila GAGA transcription factor.

Species-specific signals for the splicing of a short Drosophila intron in vitro.

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