Targeted insertion in well-characterized Drosophila cell lines using φC31 integrase

We describe an adaptation of φC31 integrase-mediated targeted cassette exchange for use in Drosophila cell lines. Single copies of an attP-bounded docking platform carrying a GFP-expression marker, with and without insulator elements flanking the attP sites, were inserted by P-element transformation into the Kc167 and Sg4 cell lines; each of the resulting docking site lines carries a single mapped copy of one of the docking platforms. Vectors for targeted substitution contain a cloning cassette flanked by attB sites. Targeted substitution occurs by integrase-mediated substitution between the attP sites (integrated) and the attB sites (vector). We describe procedures for isolating cells carrying the substitutions and for eliminating the products of secondary off-target events. We demonstrated the technology by integrating a cassette containing a Cu++-inducible mCherry marker, and we report the expression properties of those lines. When compared with clonal lines made by traditional transformation methods, which lead to the illegitimate insertion of tandem arrays, targeted insertion lines give more uniform expression, lower basal expression and higher induction ratios. Targeted substitution, though intricate, affords results that should greatly improve comparative expression assays ??? a major emphasis of cell-based studies.

Genetic and molecular characterization of a variegating hsp70-lacZ fusion gene in the euchromatic 31B region of Drosophila melanogaster

A hsp70–lacZ fusion gene introduced into Drosophila melanogaster at the euchromatic 31B region by P-element transformation displayed a variegated expression with respect to the lacZ fusion protein in the salivary gland cells under heat-shock conditions. The variegation is also reflected by the chromosome puffing pattern. Subsequent transposition of the 31B P element to other euchromatic positions restored wild-type activity, that is, a nonvariegated phenotype. A lower developmental temperature reduced the amount of expression under heat-shock conditions, similar to genes undergoing position-effect variegation (PEV). However, other modifiers of PEV did not affect the expression pattern of the gene. These results show a novel euchromatic tissue-specific variegation that is not associated with classical heterochromatic PEV.Key words: Drosophila, euchromatic position effect, heat shock construct.

The promoter of DNA puff gene II/9-1 of Sciara coprophila is inducible by ecdysone in late prepupal salivary glands of Drosophila melanogaster.

DNA puffs occur in Sciarid salivary gland chromosomes; they are sites of DNA amplification and intense transcription and they appear to encode secreted structural proteins needed for pupation. In this report we have used P-element transformation of Drosophila to study regulation of a Sciara DNA puff gene. We found that a 718-bp promoter fragment of DNA puff gene II/9-1 from Sciara coprophila directs expression of the bacterial reporter gene CAT in late prepupal salivary glands of transgenic Drosophila melanogaster. The identical tissue and analogous stage specificity indicate that some aspects of the ecdysone response are evolutionarily conserved between Drosophila and Sciara. When transgenic salivary glands are cultured in vitro, CAT activity is rapidly induced by ecdysone, suggesting direct control of gene expression by the ecdysone receptor. Putative stage-specific factors limit expression of the chimeric Sciara-CAT gene in transgenic Drosophila to late prepupae but not to third instar larvae when ecdysone titers are also high.

Detailed structure of the Drosophila melanogaster stellate genes and their transcripts.

The X-linked Stellate locus contains two major size classes of a tandemly repeated gene. An example of each class has been sequenced. The steady-state level of Stellate RNA is much higher in XO testis than in XY testis. Sequencing of six cDNA clones derived from XO testis RNA shows that there are two major introns in the Stellate genes. Primer extension and RNase protection analyses show that these introns are spliced much more efficiently in XO than in XY testis. These results also indicate the major transcriptional start site for Stellate RNA. P element transformation results with a marked Stellate gene demonstrate that at least one of the genes sequenced contains a functional promoter, which generates low levels of RNA in XY testis and high levels of RNA in XO testis. This promoter does not contain a TATA element in the -30 region relative to the transcriptional start. Previous results had implicated a specific region of the Y chromosome, designated here as the Su(Ste) locus, in the control of the Stellate genes on the X. Analysis using segmental Y deficiencies shows that the Su(Ste) region suppresses both the high levels and efficient splicing of Stellate RNA.

Physical and functional definition of the Drosophila Notch locus by P element transformation.

Notch is a developmentally regulated locus which controls the differentiation of various Drosophila tissues, among them the embryonic nervous system. Molecular analysis has suggested that Notch is defined by an approximately 40-kb transcription unit which is spliced into a 10.2-kb mRNA composed of nine exonic regions and coding for a 2703-amino acid long transmembrane protein that shows homology to the mammalian epidermal growth factor. Here, we define the 5' end of the transcription unit and determine the sequences deleted in a Notch mutation involving the 5' nontranscribed region. Using a Notch cosmid vector we demonstrate by P element-mediated transformation that all sequences necessary for Notch function are confined in an approximately 40-kb long genomic region. cDNA sequences are used to construct a 15-kb "minigene" which lacks most, but not all, introns and its functionality is also tested by P element transformation. We show that, unlike the cosmid vector which is capable of rescuing completely all Notch mutations, only certain phenotypes can be rescued by the "minigene." The functional implications of our findings are discussed.