We have used 160 kilobases of cloned Drosophila genomic DNA from the rudimentary (r) region to examine the organization of amplified DNA in Drosophila cells resistant to 10 mM N-(phosphonacetyl)-L-aspartate (PALAr cells) obtained by stepwise selection. Evidence for the direct tandem linkage of the amplified sequences is presented. The pattern and intensity of amplified bands as well as the presence of novel junctions in the DNA sequence of PALAr cells indicate that there are two types of units of 150 and 120 kilobases long. The sequence of the smaller unit is entirely included within the larger one. The longer of the two units is present twice while the shorter one is amplified eightfold as compared to the level of the relevant DNA sequences in the wild-type. These data are consistent with a model in which successive crossing-over events over several cell cycles lead to amplification of the selected r gene and flanking sequences. However, these data can also be accounted for by a totally different mechanism in which multiple copies of DNA are generated by rolling circle replication. Transcription units other than the r gene are present within the 150 kilobase region of amplified DNA. These are found to be overexpressed in PALAr cells, though some transcripts are underrepresented relative to the copy number of the corresponding coding sequences.
The transcriptional activity of the Bicoid morphogen is directly downregulated by the Torso signal transduction cascade at the anterior pole of the Drosophila embryo. This regulation does not involve the homeodomain or direct phosphorylation of Bicoid. We analyse the transcriptional regulation of Bicoid in response to the Torso pathway, using Bicoid variants and fusion proteins between the Bicoid domains and the Gal4 DNA-binding domain. We show that Bicoid possesses three autonomous activation domains. Two of these domains, the serine/threonine-rich and the acidic domains, are downregulated by Torso, whereas the third activation domain, which is rich in glutamine, is not. The alanine-rich domain, previously described as an activation domain in vitro, has a repressive activity that is independent of Torso. Thus, Bicoid downregulation by Torso results from a competition between the glutamine-rich domain that is insensitive to Torso and the serine/threonine-rich and acidic activation domains downregulated by Torso. The alanine-rich domain contributes to this process indirectly by reducing the global activity of the protein and in particular the activity of the glutamine-rich domain that might otherwise prevent downregulation by Torso.
In the I±R hybrid dysgenesis system, Drosophila melanogaster strains fall into two categories denoted inducer (I) and reactive (R). Among the reactive strains we can distinguish strains with weak, medium or strong reactivity levels. These levels are inherited in a complex way involving both chromosomal and nonchromosomal determinants, the nonchromosomal determinant being mainly maternally inherited. We were interested in determining the molecular basis of this maternal transmission. In this article we analyse the possible implication of the mitochondrial DNA in the determination of the reactivity levels. The mtDNA was analysed in lines with very dierent reactivity levels with the aim of correlating sequence dierences with reactivity levels. The mtDNA was analysed by sequencing and restriction fragment length. No correlation was established between reactivity level and mtDNA sequence. This may favour the hypothesis that epigenetic changes would be responsible for the dierent reactivity levels and their transgenerational transmission.
We have previously shown the presence, in the amplified DNA of a Drosophila cell line resistant to N-phosphonacetyl-L-aspartate (PALA), of two units of 150 kb and 120 kb respectively duplicated and amplified. The two joints (J1 and J2) linking these units as well as their respective wild-type counterparts have been sequenced. Sequence analysis indicates that a region of the Drosophila genome which corresponds to the proximal boundary of the 150 kb unit is common to both joints. In addition to this common region, the J1 junction possesses a 26-nucleotide sequence belonging to the J2 junction. This indicates that the J2 junction was the first formed, and that J1, therefore, results from recombination between J2 and a region of the wild-type genome 120 kb distal to J2. Sequence analysis also reveals that the joints result from illegitimate recombination between unrelated regions. AT-rich sequences, strand bias composition and putative topoisomerase I and II sites were found in at least one of the two parental sequences involved in the formation of the joints. On the basis of these results we can hypothesize that after two illegitimate recombinations between sister chromatids, leading first to J2 and then to J1, the amplification may have arisen by a series of homologous (unequal crossing-over) or illegitimate recombinations, or by an intrachromosomal rolling circle.
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