Vector and parameters for targeted transgenic RNA interference in Drosophila melanogaster

The conditional expression of hairpin constructs in Drosophila melanogaster has emerged in recent years as a method of choice in functional genomic studies. To date, upstream activating site-driven RNA interference constructs have been inserted into the genome randomly using P-element-mediated transformation, which can result in false negatives due to variable expression. To avoid this problem, we have developed a transgenic RNA interference vector based on the phiC31 site-specific integration method.     

In vitro analysis of RNA interference in Drosophila melanogaster

Double-stranded RNA (dsRNA) triggers the destruction of mRNA sharing sequence with the dsRNA, a phenomenon termed RNA interference (RNAi). The dsRNA is converted by endonucleolytic cleavage into 21- to 23-nt small interfering RNAs (siRNAs), which direct a multiprotein complex, the RNA-induced silencing complex to cleave RNA complementary to the siRNA. RNAi can be recapitulated in vitro in lysates of syncytial blastoderm Drosophila embryos. These lysates reproduce all of the known steps in the RNAi pathway in flies and mammals. Here we explain how to prepare and use Drosophila embryo lysates to dissect the mechanism of RNAi.     

In vitro transcription of Drosophila ribosomal genes using Drosophila RNA polymerases

Drosophila RNA polymerases I &; II were used to transcribe a recombinant bacterial plasmid containing one copy of Drosophila ribosomal DNA. Both supercoiled and relaxed, closed circular plasmids were used. With Mg⁺² as the divalent cation, enzyme I is much more active on both forms of the plasmid; the relaxed form in particular supports almost no RNA synthesis by enzyme II. When Mn⁺² is present, differences in template efficiencies are minimal. The differences observed in the absence of Mn⁺² seem to depend only on different preferences for the physical state of the template and not on recognition of specific promotor sequences, since enzyme I shows no strand selection when transcribing these plasmids.     

In vitro suppression of a nonsense mutant of Drosophila melanogaster.

When RNA isolated from the Drosophila melanogaster alcohol dehydrogenase (ADH) negative mutant CyOnB was translated "in vitro" in the presence of yeast opal suppressor tRNA, a wild type size ADH protein was obtained in addition to the mutant gene product. This identifies the CyOnB mutant as an opal (UGA) nonsense mutant. From the molecular weight of the mutant protein, and from the known sequence of the ADH gene (Benyajati et al., Proc.Natl.Acad.Sci. USA 78, 2717-2721, 1981), we conclude that the tryptophan codon UGG in position 234 has been changed into a UGA nonsense codon in the CyOnB mutant. Furthermore, we show that the UAA stop codon of the wild type ADH gene is resistant to suppression by a yeast ochre suppressor tRNA. This is in contrast to the high efficiency of suppression of the CyOnB UGA nonsense codon, despite an almost identical codon context.     

Paragonial proteins of Drosophila melanogaster adult male: In vitro biosynthesis

When paragonia were incubated for 8 hr in simplified Robb's medium a continuous increase in incorporation of ¹⁴C-amino acids into TCA precipitable proteins was found. The increase is linear over the first 2 hr.Copulation provides the stimulus for an alteration in rate of in vitro incorporation: a rapid and clear increase occurs. A similar increase in rate of incorporation of ¹⁴C-uridine into RNA and ³H-ethanolamine into ‘paragonial substance’ could be found. The pattern of incorporation of ¹⁴C-amino acids into proteins, as determined by polyacrylamide gel electrophoresis, remains qualitatively unaltered. Results from transplantation experiments of single paragonia suggest that the stimulation, at least in part, is neuronal or humoral mediated.In vitro incubations with actinomycin D, under conditions of 90% inhibition, resulted in an increased rate of incorporation of ¹⁴C-amino acids into proteins.     

Transgenic inhibitors of RNA interference in Drosophila

RNA silencing functions as an adaptive antiviral defense in both plants and animals. In turn, viruses commonly encode suppressors of RNA silencing, which enable them to mount productive infection. These inhibitor proteins may be exploited as reagents with which to probe mechanisms and functions of RNA silencing pathways. In this report, we describe transgenic Drosophila strains that allow inducible expression of the viral RNA silencing inhibitors Flock House virus-B2, Nodamura virus-B2, vaccinia virus-E3L, influenza A virus-NS1 and tombusvirus P19. Some of these, especially the B2 proteins, are effective transgenic inhibitors of double strand RNA-induced gene silencing in flies. On the other hand, none of them is effective against the Drosophila microRNA pathway. Their functional selectivity makes these viral silencing proteins useful reagents with which to study biological functions of the Drosophila RNA interference pathway.     

Transfer RNA genes of Drosophila melanogaster.

Three recombinant plasmids containing randomly sheared genomic D. melanogaster tRNAs have been identified and characterized in detail. One of these, the plasmid 14C4, has a D. melanogaster (Dm) DNA segment of 18 kb, and has three tRNA2Arg and two tRNAAsN genes. The second plasmid, 38B10, has tRNAHis genes, while the third plasmid, 63H5, contains coding sequences for tRNA2Asp. The Dm DNA segments in each recombinant plasmid are derived from unique cytogenetic loci. 14C4 is from 84 F, 38B10 is from 48 F and 63H5 is from 70 A.     

The in vitro synthesis and characteristics of ribosomal RNA in imaginal discs of Drosophila melanogaster

Summary Late third instar imaginal discs of Drosophila melanogaster cultured in vitro in Robb's tissue culture medium synthesize 38S, 28S and 18S ribosomal RNAs which are qualitatively indistinguishable from their in vivo synthesized counterparts (Fig. 1). As found in other insect systems, the 38S molecule appears to be the precursor for both the 28S and 18S rRNAs (Figs. 2, 3 and 4). The 28S rRNA and a portion of the 38S pre-rRNA shift in sedimentation value upon exposure to heat or dimethylsulfoxide (Figs. 5 and 8). Studies of the thermal denaturations of these molecules (Figs. 6, 7 and 9) indicate the existence of a single class of 28S rRNA, but three classes of 38S pre-rRNAs. The addition of -ecdysone to the in vitro culture medium stimulates the net amount of rRNA synthesized, increases the rate of processing of the 38S precursor and increases the relative amount of 18S material produced (Figs. 10 and 12).This work was supported in part by grants from the National Science Foundation (GB-8176) and from the Atomic Energy Commission (AT-04-3-34).Predoctoral Trainees, PHS Training Grant No. 2-Tl-GM367 from Research Training Grants Branch, National Institute of General Medical Sciences.1 For purposes of simplification we shall refer to the rRNA molecules of D. melanogaster as being 38S, 30S, 28S and 18S; however, it should be noted that these values are approximate (see Hastings and Kirby, 1966; Greenberg, 1969; Tartof and Perry, 1970).     

In vitro and in vivo analysis of somatic and germline mutability of 2-amino-N6-hydroxyadenine in Drosophila melanogaster

Two complementary assays were employed to examine the mutagenicity of 2-amino-N6-hydroxyadenine (AHA) in Drosophila melanogaster. A lambda phage-based shuttle vector system, utilizing the supF transfer RNA gene of Escherichia coli, questioned the mutagenicity of AHA in established cell cultures derived from somatic tissue while the standard sex-linked recessive lethal assay measured mutational events in vivo. Consistent with studies in other systems, AHA appears strongly mutagenic when cells are exposed directly. Conversely, in vivo studies suggest that AHA is not a strong mutagen. Further studies will determine if AHA is weakly or not mutagenic in vivo and, using the supF system, what the nature of the mutational events at the molecular level is.     

RNA metabolism during puff induction in Drosophila melanogaster

RNA metabolism of the salivary glands of Drosophila melanogaster was studied for possible changes coinciding with the induction of new puffs by heat treatment.—The rate of ³H-uridine incorporation into RNA is identical at 37° C and at 24° C. It declines with time of incubation, possibly indicating the existence of a class of rapidly turning over RNA.—RNA extracted from glands pulselabelled at either 24° or at 37° C displays similar profiles if subjected to gel electrophoresis. Processing of the 38s ribosomal RNA precursor comes to a halt at 37° between 30 and 60 minutes of incubation, i.e., some time after puff induction is completed. At both temperatures newly synthesized pre-ribosomal RNA accumulates with time of incubation more rapidly than heterodisperse RNA, again suggesting that some heterodisperse RNA is of relatively short life span. After short pulses the portion of heterodisperse RNA is larger in glands kept at 37° C than in glands kept at 24° C. With increasing time this difference disappears.—Some of the pulse-labelled, high molecular weight heterodisperse RNA is rapidly degraded, if RNA synthesis is blocked by actinomycin D. If the chase is performed at 24° C, about 30% of the newly synthesized RNA is degraded within about 15 minutes. At 37° C the beginning of degradation appears delayed for about 30 minutes; subsequently the same percentage of RNA is degraded as at 24° C.—The possibility is considered that the local RNA accumulation visualized by the heat-induced puffs may have resulted from a change in RNA degradation rather than from a local stimulation of RNA synthesis.