Molecular cloning of suppressor of sable, a Drosophila melanogaster transposon-mediated suppressor

Modifier of rudimentary p1, mod(r)p1, a trans-acting regulatory mutation of rudimentary

Modifier of rudimentaryp1 (mod(r)p1) is a hybrid dysgenesis-induced mutation isolated as a suppressor of rhd1, a hypomorphic rudimentary(r) allele in Drosophila melanogaster.mod(r)p1 has opposite effects on two of the rudimentary mutant phenotypes. It suppresses the wing truncation associated with hypomorphic r alleles, which was the phenotype used to isolate it. On the other hand, it does not suppress the sterility of r females and in fact decreases the fertility of wild-type females. This infertility is associated with a drastic decrease in r expression in mod(r)p1 females. P elementagging was used to clone the mutant allele, mod(r)p1. Subsequently, 28 kb of genomic DNA encompassing the wild-type mod(r) gene in the chromosomal region 1B was cloned. mod(r) encodes a 1.3 kb transcript which is not detected in the mod(r)p1 mutant. The sequences of mod(r) cDNA clones reveal that the gene encodes a protein of 200 amino acids in length. When compared to sequences in GenBank, the amino acid sequence did not reveal any long sequences similarities. However, the structure of the protein reveals similarities to known transcription factors. The N-terminal half of the protein is very acidic, whereas the C-terminal half is basic. The basic domain suggests a possible DNA-binding domain, while the acidic domain suggests a transcriptional activation domain. Consistent with this possibility is the fact that mod(r) acts through the 5' control region of the rudimentary gene to control its expression.

Mutations in the su(s) gene affect RNA processing in Drosophila melanogaster

We have studied the effect of mutations in the suppressor of sable [su(s)] gene on P element-induced yellow alleles. Two independent mutations tested, y76d28 and y1#7, contain a 1.1-kilobase (kb) P element inserted in the 5' transcribed untranslated portion of the yellow gene. Sequences responsible for the y1#7 mutation are inserted in the same transcriptional orientation as yellow and cannot be processed by splicing, and this mutation is not suppressed by su(s) mutations. P element sequences are located in a transcriptional orientation opposite to that of the yellow gene in y76d28; these sequences can be spliced from a composite P element-yellow mRNA, resulting in low accumulation of a functional 1.9-kb yellow transcript. The levels of both the putative precursor P element-yellow RNA and the 1.9-kb yellow transcript increase in y76d28 su(s) flies, suggesting that mutations in su(s) do not affect the efficiency of splicing of the P element sequences. Analysis of y76d28 cDNAs isolated from flies carrying a wild-type or mutant su(s) gene demonstrates that the choice of splice junctions to process P element sequences is unchanged in these different backgrounds, suggesting that mutations in su(s) do not affect the selection of donor and acceptor splice sites. We propose that the su(s) protein functions to control the stability of unprocessed RNA during the splicing reaction.

The Drosophila suppressor of sable gene encodes a polypeptide with regions similar to those of RNA-binding proteins

The nucleotide sequence of the Drosophila melanogaster suppressor of sable [su(s)] gene has been determined. Comparison of genomic and cDNA sequences indicates that an approximately 7,860-nucleotide primary transcript is processed into an approximately 5-kb message, expressed during all stages of the life cycle, that contains an open reading frame capable of encoding a 1,322-amino-acid protein of approximately 150 kDa. The putative protein contains an RNA recognition motif-like region and a highly charged arginine-, lysine-, serine-, aspartic or glutamic acid-rich region that is similar to a region contained in several RNA-processing proteins. In vitro translation of in vitro-transcribed RNA from a complete cDNA yields a product whose size agrees with the size predicted by the open reading frame. Antisera against su(s) fusion proteins recognize the in vitro-translated protein and detect a protein of identical size in the nuclear fractions from tissue culture cells and embryos. The protein is also present in smaller amounts in cytoplasmic fractions of embryos. That the su(s) protein has regions similar in structure to RNA-processing protein is consistent with its known role in affecting the transcript levels of those alleles that it suppresses.

The Drosophila suppressor of sable gene encodes a polypeptide with regions similar to those of RNA-binding proteins

The nucleotide sequence of the Drosophila melanogaster suppressor of sable [su(s)] gene has been determined. Comparison of genomic and cDNA sequences indicates that an approximately 7,860-nucleotide primary transcript is processed into an approximately 5-kb message, expressed during all stages of the life cycle, that contains an open reading frame capable of encoding a 1,322-amino-acid protein of approximately 150 kDa. The putative protein contains an RNA recognition motif-like region and a highly charged arginine-, lysine-, serine-, aspartic or glutamic acid-rich region that is similar to a region contained in several RNA-processing proteins. In vitro translation of in vitro-transcribed RNA from a complete cDNA yields a product whose size agrees with the size predicted by the open reading frame. Antisera against su(s) fusion proteins recognize the in vitro-translated protein and detect a protein of identical size in the nuclear fractions from tissue culture cells and embryos. The protein is also present in smaller amounts in cytoplasmic fractions of embryos. That the su(s) protein has regions similar in structure to RNA-processing protein is consistent with its known role in affecting the transcript levels of those alleles that it suppresses.

Mobile element insertions causing mutations in the Drosophila suppressor of sable locus occur in DNase I hypersensitive subregions of 5'-transcribed nontranslated sequences

The locations of 16 mobile element insertions causing mutations at the Drosophila suppressor of sable [su(s)] locus were determined by restriction mapping and DNA sequencing of the junction sites. The transposons causing the mutations are: P element (5 alleles), gypsy (3 alleles), 17.6, HMS Beagle, springer, Delta 88, prygun, Stalker, and a new mobile element which was named roamer (2 alleles). Four P element insertions occur in 5' nontranslated leader sequences, while the fifth P element and all 11 non-P elements inserted into the 2053 nucleotide, 5'-most intron that is spliced from the 5' nontranslated leader approximately 100 nucleotides upstream of the translation start. Fifteen of the 16 mobile elements inserted within a approximately 1900 nucleotide region that contains seven 100-200-nucleotide long DNase I-hypersensitive subregions that alternate with DNase I-resistant intervals of similar lengths. The locations of these 15 insertion sites correlate well with the roughly estimated locations of five of the DNase I-hypersensitive subregions. These findings suggest that the features of chromatin structure that accompany gene activation may also make the DNA susceptible to insertion of mobile elements.

Structure and transcription of the Drosophila melanogaster vermilion gene and several mutant alleles

The nucleotide sequence and intron-exon structure of the Drosophila melanogaster vermilion (v) gene have been determined. In addition, the sites of several mutations and the effects of these mutations on transcription have been examined. The major v mRNA is generated upon splicing six exons of lengths (5' to 3') 83, 161, 134, 607, 94, and 227 nucleotides (nt). A minor species of v mRNA is initiated at an upstream site and has a 5' exon of at least 152 nt which overlaps the region included in the 83-nt exon of the major v RNA. The three v mutations, v1, v2, and vk, which can be suppressed by mutations at suppressor of sable, su(s), are insertions of transposon 412 at the same position in exon 1, 36 nt downstream of the major transcription initiation site. Despite the 7.5-kilobase insertion in these v alleles, a reduced level of wild-type-sized mRNA accumulates in suppressed mutant strains. The structure and transcription of several unsuppressible v alleles have also been examined. The v36f mutation is a B104/roo insertion in intron 4 near the splice donor site. A mutant carrying this alteration accumulates a very low level of mRNA that is apparently polyadenylated at a site within the B104/roo transposon. The v48a mutation, which deletes approximately 200 nt of DNA, fuses portions of exons 3 and 4 without disruption of the translational reading frame. A smaller transcript accumulates at a wild-type level, and thus an altered, nonfunctional polypeptide is likely to be synthesized in strains carrying this mutation. The v(H2a) mutants has a P element insertion in exon 6 within the coding region.

Structure and transcription of the Drosophila melanogaster vermilion gene and several mutant alleles

The nucleotide sequence and intron-exon structure of the Drosophila melanogaster vermilion (v) gene have been determined. In addition, the sites of several mutations and the effects of these mutations on transcription have been examined. The major v mRNA is generated upon splicing six exons of lengths (5' to 3') 83, 161, 134, 607, 94, and 227 nucleotides (nt). A minor species of v mRNA is initiated at an upstream site and has a 5' exon of at least 152 nt which overlaps the region included in the 83-nt exon of the major v RNA. The three v mutations, v1, v2, and vk, which can be suppressed by mutations at suppressor of sable, su(s), are insertions of transposon 412 at the same position in exon 1, 36 nt downstream of the major transcription initiation site. Despite the 7.5-kilobase insertion in these v alleles, a reduced level of wild-type-sized mRNA accumulates in suppressed mutant strains. The structure and transcription of several unsuppressible v alleles have also been examined. The v36f mutation is a B104/roo insertion in intron 4 near the splice donor site. A mutant carrying this alteration accumulates a very low level of mRNA that is apparently polyadenylated at a site within the B104/roo transposon. The v48a mutation, which deletes approximately 200 nt of DNA, fuses portions of exons 3 and 4 without disruption of the translational reading frame. A smaller transcript accumulates at a wild-type level, and thus an altered, nonfunctional polypeptide is likely to be synthesized in strains carrying this mutation. The v(H2a) mutants has a P element insertion in exon 6 within the coding region.

Four tandem defective P elements associated with positive regulation of the Drosophila melanogaster glucose-6-phosphate dehydrogenase gene

Three high-glucose-6-phosphate dehydrogenase (G6PD)-activity mutants (2512H, S44H, and 1FH) are characterized by two insertion sequences associated with the G6PD locus; one (Ins1; 3.5 kb long in 2512H and S44H and 2.9 kb long in 1FH) is present just 5' to exon I and consists of a KP' (the 32nd base of the KP was replaced by guanine), a core sequence and a KP, and the other is 4.2 kb long and resides within an intron. Southern blot analyses of revertants showing low G6PD activity suggested that the insertion sequence responsible for high G6PD activity may be the core sequence but not the flanking KP and KP' or the Ins2. DNA sequencing data of the clone carrying the core sequence of 2512H demonstrated that the core sequence is another type of defective P elements (core P). Interestingly, a protein(s) was found in the nuclear extract of Canton S embryos that specifically binds to the core P but not to the KP or various fragments of p pi 25.1. In addition, the mutant G6PD activity was found to be affected not only by the genotype, but also by cytoplasmic factors.

A genetic and molecular analysis of P-induced mutations at the glucose-6-phosphate dehydrogenase locus in Drosophila melanogaster

We examined P factor induced mutations of the Zw gene of Drosophila melanogaster in order to learn more about the site specificity of such mutations. Approximately 70,000 chromosomes were screened using a powerful positive selection scheme. As only two mutants were discovered, Zw is a "cold spot" for transposable element insertion. One mutation involved a complex P element associated chromosomal rearrangement which was used to define the orientation of the gene with respect to the centromere of the X chromosome. The second mutation was either a simple, non-dysgenically induced point mutation or a very unstable insertion.

Positive regulation of the Drosophila melanogaster G6PD gene by an insertion sequence

In a previous study, we have shown that the three high-G6PD activity mutants are characterized by insertion of the Ins1 sequence consisting of a core sequence flanked by two defective P elements (KP and KP'; the 32nd base of the KP was replaced by guanine in the KP') in front of exonI of the G6PD gene and that the sequence responsible for positive regulation of the G6PD gene expression might be the core sequence but not the flanking KP and KP' elements. The core sequence is composed of either one or two identical units in each mutant. In this report we present evidence (1) that insertion of the Ins1 sequence gives rise to overproduction of G6PD mRNA, (2) that the length and the 5' end of G6PD mRNA do not differ in wild-type and three mutants, (3) that the insertion site of the Ins1 sequence is the same in the mutants, and (4) that each unit of the core sequence has the same in the mutants, and (4) that each unit of the core sequence has a pair of DNase I-hypersensitive sites. The possibility exists that the binding of some regulatory proteins to the DNase I-hypersensitive sites might accelerate the transcription rate of the G6PD gene.