Abstract
The proximal promoter regions of heat-shock genes harbor a remarkable number of P transposable element (TE) insertions relative to both positive and negative control proximal promoter regions in natural populations of Drosophila melanogaster. We have screened the sequenced genomes of 12 species of Drosophila to test whether this pattern is unique to these populations. In the 12 species' genomes, transposable element insertions are no more abundant in promoter regions of single-copy heat-shock genes than in promoters with similar or dissimilar architecture. Also, insertions appear randomly distributed across the promoter region, whereas insertions clustered near the transcription start site in promoters of single-copy heat-shock genes in D. melanogaster natural populations. Hsp70 promoters exhibit more TE insertions per promoter than all other genesets in the 12 species, similarly to in natural populations of D. melanogaster. Insertions in the Hsp70 promoter region, however, cluster away from the transcription start site in the 12 species, but near it in natural populations of D. melanogaster. These results suggest that D. melanogaster heat-shock promoters are unique in terms of their interaction with transposable elements, and confirm that Hsp70 promoters are distinctive in TE insertions across Drosophila.
Highlights
The massive accumulation of comparative genomic data due to recent large-scale sequencing projects [1] can help test whether a putatively general pattern in a species is unique or is recurrent in evolution
Analysis and Distribution of transposable element (TE) Insertions Hsp70 is uniformly a multi-copy gene in the genus Drosophila, with 50 proximal promoter regions in total computationally identified for the 12 species (Figure 1)
In some cases these promoters overlap, reducing the total promoter sequence into which TEs could insert to the equivalent of 46 promoters
Summary
The massive accumulation of comparative genomic data due to recent large-scale sequencing projects [1] can help test whether a putatively general pattern in a species is unique or is recurrent in evolution. We undertake such a test upon the remarkable abundance of a DNA transposon, the P element, in the proximal promoter regions of heat-shock genes in natural populations of the model organism Drosophila melanogaster [2]. In heat-shock promoters, the constitutive decondensation of the chromatin and nucleosome-free regions correspond to the preference of P elements for such DNA [5]. Once inserted in the germ line, such TEs may persist due to genetic drift or positive selection [6,7,8,9,10,11,12,13] or decay and be lost due to unconstrained degeneration and/or negative selection
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