Distribution and conservation of sequences homologous to the 1731 retrotransposon in Drosophila

The distribution of 1731 retrotransposon-hybridizing sequences in the family Drosophilidae has been studied using a 1731 probe from Drosophila melanogaster. Squash blot and Southern blot analyses of 42 species reveal that the 1731 sequences are widespread within both the Sophophora and Drosophila subgenera and are also present in the genera Scaptomyza and Zaprionus. Hence the 1731 retrotransposon family appears to have a long evolutionary history in the Drosophilidae genome. Differences of hybridization signal intensity suggested that the 1731 sequence is well conserved only in the three species most closely related to D. melanogaster (D. simulans, D. mauritiana, and D. sechellia). A survey of insertion sites in numerous different populations of the previous four species by in situ hybridization to polytene chromosomes has shown in all cases both chromocentric hybridizations and a low number of sites (0-5) on the chromosomal arms. This number of sites is among the lowest observed in D. melanogaster and D. simulans when 1731 is compared with other retrotransposon families. In addition, we have observed species-specific patterns of the chromocentric hybridization signal, suggesting rapid modifications of the beta-heterochromatin components since the radiation of the melanogaster subgroup.      

The DNA-binding polycomb group protein pleiohomeotic mediates silencing of a Drosophila homeotic gene.

Polycomb group (PcG) proteins repress homeotic genes in cells where these genes must remain inactive during development. This repression requires cis-acting silencers, also called PcG response elements. Currently, these silencers are ill-defined sequences and it is not known how PcG proteins associate with DNA. Here, we show that the Drosophila PcG protein Pleiohomeotic binds to specific sites in a silencer of the homeotic gene Ultrabithorax. In an Ultrabithorax reporter gene, point mutations in these Pleiohomeotic binding sites abolish PcG repression in vivo. Hence, DNA-bound Pleiohomeotic protein may function in the recruitment of other non-DNA-binding PcG proteins to homeotic gene silencers.     

An in vitro-selected RNA-binding site for the KH domain protein PSI acts as a splicing inhibitor element

P element somatic inhibitor (PSI) is a 97-kDa RNA-binding protein with four KH motifs that is involved in the inhibition of splicing of the Drosophila P element third intron (IVS3) in somatic cells. PSI interacts with a negative regulatory element in the IVS3 5' exon. This element contains two pseudo-5' splice sites, termed F1 and F2. To identify high affinity binding sites for the PSI protein, in vitro selection (SELEX) was performed using a random RNA oligonucleotide pool. Alignment of high affinity PSI-binding RNAs revealed a degenerate consensus sequence consisting of a short core motif of CUU flanked by alternative purines and pyrimidines. Interestingly, this sequence resembles the F2 pseudo-5' splice site in the P element negative regulatory element. Additionally, a negative in vitro selection of PCR-mutagenized P element 5' exon regulatory element RNAs identified two U residues in the F1 and F2 pseudo-5' splice sites as important nucleotides for PSI binding and the U residue in the F2 region is a nearly invariant nucleotide in the consensus SELEX motif. The high affinity PSI SELEX sequence acted as a splicing inhibitor when placed in the context of a P element splicing pre-mRNA in vitro. Data from in vitro splicing assays, UV crosslinking and RNA-binding competition experiments indicates a strong correlation between the binding affinities of PSI for the SELEX sequences and their ability to modulate splicing of P element IVS3 in vitro.     

Drosophila U6 promoter-driven short hairpin RNAs effectively induce RNA interference in Schneider 2 cells

The effect of RNA interference (RNAi) is generally more potent in Drosophila Schneider 2 (S2) cells than in mammalian cells. In mammalian cells, PolIII promoter-based DNA vectors can be used to express small interfering RNA (siRNA) or short hairpin RNA (shRNA); however, this has not been demonstrated in cultured Drosophila cells. Here we show that shRNAs transcribed from the Drosophila U6 promoter can efficiently trigger gene silencing in S2 cells. By targeting firefly luciferase mRNA, we assessed the efficacy of the shRNAs and examined the structural requirements for highly effective shRNAs. The silencing effect was dependent on the length of the stem region and the sequence of the loop region. Furthermore, we demonstrate that the expression of the endogenous cyclin E protein can be repressed by the U6 promoter-driven shRNAs. Drosophila U6 promoter-based shRNA expression systems may permit stable gene silencing in S2 cells.