Abstract
Binary expression systems such as GAL4/UAS, LexA/LexAop and QF/QUAS have greatly enhanced the power of Drosophila as a model organism by allowing spatio-temporal manipulation of gene function as well as cell and neural circuit function. Tissue-specific expression of these heterologous transcription factors relies on random transposon integration near enhancers or promoters that drive the binary transcription factor embedded in the transposon. Alternatively, gene-specific promoter elements are directly fused to the binary factor within the transposon followed by random or site-specific integration. However, such insertions do not consistently recapitulate endogenous expression. We used Minos-Mediated Integration Cassette (MiMIC) transposons to convert host loci into reliable gene-specific binary effectors. MiMIC transposons allow recombinase-mediated cassette exchange to modify the transposon content. We developed novel exchange cassettes to convert coding intronic MiMIC insertions into gene-specific binary factor protein-traps. In addition, we expanded the set of binary factor exchange cassettes available for non-coding intronic MiMIC insertions. We show that binary factor conversions of different insertions in the same locus have indistinguishable expression patterns, suggesting that they reliably reflect endogenous gene expression. We show the efficacy and broad applicability of these new tools by dissecting the cellular expression patterns of the Drosophila serotonin receptor gene family.
Highlights
The continued development of novel molecular genetic technologies has been critical for the staying power of Drosophila melanogaster as a model system in biology
A subsequent technological milestone was the development of the first binary gene expression system that uses the yeast transcription factor GAL4 to activate any gene of interest cloned downstream of the Upstream Activating Sequence (UAS) [3]
Neuropil is stained with an antibody against Dlg, showing the outline of the entire mushroom bodies (MBs) in red. (d) Same area of the brain as in (c) showing GFP staining pattern of the Mi{MIC}5-HT1B-T2A-GAL4MI05213 driving expression of the same reporter but with distinct expression in ␣’ and ’ and ␥ lobes
Summary
The continued development of novel molecular genetic technologies has been critical for the staying power of Drosophila melanogaster as a model system in biology. (a) A protein-trap event between 5-HT1A and T2A-GAL4 (5-HT1A-T2A-GAL4MI01140) drives expression of UAS-GFP in PI, AL, OL, SOG and MB (most prominently in the ␣ and  lobes, Supplementary Video 1, see Figure 2).
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