Arginine-Rich Regions Mediate the RNA Binding and Regulatory Activities of the Protein Encoded by the Drosophila melanogaster suppressor of sable Gene

ABSTRACT The Drosophila melanogaster suppressor of sable gene,su(s), encodes a novel, 150-kDa nuclear RNA binding protein, SU(S), that negatively regulates RNA accumulation from mutant alleles of other genes that have transposon insertions in the 5′ transcribed region. In this study, we delineated the RNA binding domain of SU(S) and evaluated its relevance to SU(S) function in vivo. As a result, we have defined two arginine-rich motifs (ARM1 and ARM2) that mediate the RNA binding activity of SU(S). ARM1 is required for in vitro high-affinity binding of SU(S) to small RNAs that were previously isolated by SELEX (binding site selection assay) and that contain a common consensus sequence. ARM1 is also required for the association of SU(S) with larval polytene chromosomes in vivo. ARM2 promotes binding of SU(S) to SELEX RNAs that lack the consensus sequence and apparently is neither necessary nor sufficient for the stable polytene chromosome association of SU(S). Use of the GAL4/UAS system to drive ectopic expression of su(s) cDNA transgenes revealed two previously unknown properties of SU(S). First, overexpression of SU(S) is lethal. Second, SU(S) negatively regulates expression of su(s)intronless cDNA transgenes, and the ARMs are required for this effect. Considering these and previous results, we propose that SU(S) binds to the 5′ region of nascent transcripts and inhibits RNA production in a manner that can be overcome by splicing complex assembly.

The Drosophila suppressor of sable protein binds to RNA and associates with a subset of polytene chromosome bands.

Mutations of the Drosophila melanogaster suppressor of sable [su(s)] gene, which encodes a 150-kDa nuclear protein [Su(s)], increase the accumulation of specific transcripts in a manner that is not well understood but that appears to involve pre-mRNA processing. Here, we report biochemical analysis of purified, recombinant Su(s) [rSu(s)] expressed in baculovirus and in Escherichia coli as maltose binding protein (MBP) fusions and immunocytochemical analysis of endogenous Su(s). This work has shown that purified, baculovirus-expressed rSu(s) binds to RNA in vitro with a high affinity and limited specificity. Systematic evolution of ligands by exponential enrichment was used to identify preferred RNA targets of rSu(s), and a large proportion of RNAs isolated contain a full or partial match to the consensus sequence UCAGUAGUCU, which was confirmed to be a high-affinity rSu(s) binding site. An MBP-Su(s) fusion protein containing the N-terminal third of Su(s) binds RNAs containing this sequence with a higher specificity than full-length, baculovirus-expressed rSu(s). The consensus sequence resembles both a cryptic 5' splice site and a sequence that is found near the 5' end of some Drosophila transcripts. Immunolocalization studies showed that endogenous Su(s) is distributed in a reticulated pattern in Drosophila embryo and salivary gland nuclei. In salivary gland cells, Su(s) is found both in the nucleoplasm and in association with a subset of polytene chromosome bands. Considering these and previous results, we propose two models to explain how su(s) mutations affect nuclear pre-mRNA processing.

Evidence for a role of the Drosophila melanogaster suppressor of sable gene in the pre-mRNA splicing pathway.

Recessive mutations of the Drosophila melanogaster suppressor of sable [su(s)] gene result in elevated accumulation of RNA from vermilion (v) mutant alleles that have an insertion of the 7.5-kb retrotransposon 412 in the first exon of the v gene. During transcription of such a v mutant gene, the 412 sequences are incorporated into the primary transcripts and are subsequently removed by splicing at cryptic sites within 412 sequences. In a su(s)+ background, the level of these unusually spliced transcripts is exceedingly low, and su(s) mutations increase their accumulation. We previously proposed that v RNA levels are elevated in su(s) mutants because of increased recognition of the cryptic splice sites, and the aim of this study was to test this hypothesis. We generated a v mutant derivative with a smaller 412 insertion, introduced alterations into the 412-associated splice sites, and examined the effect of su(s) mutations on expression of these derivatives after germ line transformation. To increase overall expression levels, the v promoter was replaced with the stronger Metallothionein (Mtn) gene promoter. We found that transformants bearing a v derivative with 480 bp of 412 sequences accumulate both transcripts, with 412 sequences spliced out and transcripts that retain 412 sequences. Mutations of su(s) increase the levels of both transcript classes without affecting the relative amounts of the two forms. Strikingly, replacement of the cryptic 5' splice sites with a 5' consensus produces the same effect as, and eliminates the response to, a su(s) mutation. In addition, we demonstrated that mutations of su(s) lead to increased accumulation of v transcripts even when the previously identified cryptic 412 5' and 3' splice sites were destroyed and that other cryptic splice sites reside within Mtn and 412 sequences. These results indicate that the v mutant transcripts are stabilized by assembly of the 412 sequences into splicing complexes and support the hypothesis that splicing complexes more readily assemble on cryptic splice sites in su(s) mutants.

Evidence for a role of the Drosophila melanogaster suppressor of sable gene in the pre-mRNA splicing pathway

Recessive mutations of the Drosophila melanogaster suppressor of sable [su(s)] gene result in elevated accumulation of RNA from vermilion (v) mutant alleles that have an insertion of the 7.5-kb retrotransposon 412 in the first exon of the v gene. During transcription of such a v mutant gene, the 412 sequences are incorporated into the primary transcripts and are subsequently removed by splicing at cryptic sites within 412 sequences. In a su(s)+ background, the level of these unusually spliced transcripts is exceedingly low, and su(s) mutations increase their accumulation. We previously proposed that v RNA levels are elevated in su(s) mutants because of increased recognition of the cryptic splice sites, and the aim of this study was to test this hypothesis. We generated a v mutant derivative with a smaller 412 insertion, introduced alterations into the 412-associated splice sites, and examined the effect of su(s) mutations on expression of these derivatives after germ line transformation. To increase overall expression levels, the v promoter was replaced with the stronger Metallothionein (Mtn) gene promoter. We found that transformants bearing a v derivative with 480 bp of 412 sequences accumulate both transcripts, with 412 sequences spliced out and transcripts that retain 412 sequences. Mutations of su(s) increase the levels of both transcript classes without affecting the relative amounts of the two forms. Strikingly, replacement of the cryptic 5' splice sites with a 5' consensus produces the same effect as, and eliminates the response to, a su(s) mutation. In addition, we demonstrated that mutations of su(s) lead to increased accumulation of v transcripts even when the previously identified cryptic 412 5' and 3' splice sites were destroyed and that other cryptic splice sites reside within Mtn and 412 sequences. These results indicate that the v mutant transcripts are stabilized by assembly of the 412 sequences into splicing complexes and support the hypothesis that splicing complexes more readily assemble on cryptic splice sites in su(s) mutants.

Splicing of retrotransposon insertions from transcripts of the Drosophila melanogaster vermilion gene in a revertant.

A mutation of the Drosophila melanogaster vermilion (v) gene known as v1 is caused by the insertion of a 412 retrotransposon into the 5' untranslated region of the first exon. Mutants carrying this insertion accumulate a low level of mRNA from which most of the transposon sequences have been eliminated by splicing at cryptic sites within transposon sequences. Here, we demonstrate that a revertant of the v1 allele called v+37 is caused by the insertion of a second retrotransposon, the B104/roo element, into a site near one end of the 412 element. The revertant strain accumulates a higher level of mRNA from which most of both transposons have been removed by splicing at new donor sites introduced by the B104/roo insertion and the same acceptor site within 412. Mutations at suppressor of sable [su(s)], which increase the accumulation of v1 transcripts, slightly elevate the level of v+37 RNA. In addition, we show that the first v intron downstream of the 412 insertion is not efficiently removed in the v1 mutant, and suppressor and reversion mutations increase the proportion of transcripts that are properly spliced at that downstream intron. Thus, it appears that both the suppressor and reversion mutations exert an effect at the level of pre-mRNA splicing.

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.