Molecular identification of the active ninja retrotransposon and the inactive aurora element in Drosophila simulans and D. melanogaster

Population Genetics and Molecular Evolution of DNA Sequences in Transposable Elements. II. Accumulation of Variation and Evolution of a New Subfamily

In order to understand how DNA sequences of transposable elements (TEs) evolve, extensive simulations were carried out. We first used our previous model, in which the copy number of TEs is mainly controlled by selection against ectopic recombination. It was found that along a simulation run, the shape of phylogeny changes quite much, from monophyletic trees to dimorphic trees with two clusters. Our results demonstrated that the change of the phase is usually slow from a monomorphic phase to a dimorphic phase, accompanied with a growth of an internal branch by accumulation of variation between two types. Then, the phase immediately changes back to a monomorphic phase when one group gets extinct. Under this condition, monomorphic and dimorphic phases arise repeatedly, and it is very difficult to maintain two or more different types of TEs for a long time. Then, how a new subfamily can evolve? To solve this, we developed a new model, in which ectopic recombination is restricted between two types under some condition, for example, accumulation of mutations between them. Under this model, because selection works on the copy number of each types separately, two types can be maintained for a long time. As expected, our simulations demonstrated that a new type arises and persists quite stably, and that it will be recognized as a new subfamily followed by further accumulation of mutations. It is indicated that how ectopic recombination is regulated in a genome is an important factor for the evolution of a new subfamily.

A rapid decrease in number of the complete ninja element and concomitant increase of the defective element in a strain of Drosophila simulans

The ninja element, originally isolated from an unstable white mutant strain white-milky (w(mky)) of Drosophila simulans, is a member of the retrotransposon family with long terminal repeats (LTRs). We show that ninja is present in high copy numbers in the w(mky)-derivative sublines white-chocolate (w(cho)) and white-persimmonl (w(psm1)), in a low copy number in another derivative subline white-milky 3 (w(mky3)), and in only a few copies in a wild type strain. We have cloned the ninja elements from these sublines and examined their structures. Most of the elements cloned (38 out of 41 independent clones) from w(cho) were full length. In contrast, only 9 of 23 independent clones from w(mky3) were full length. We hypothesize that ninja elements were integrated and lost frequently in the w(mky) strain and its derivative genomes, and that a rapid decrease in numbers of the ninja element was caused not by an increased rate of loss but by a reduction of integration of full length ninja elements in w(mky3). Each defective element had a unique deletion and/or an insertion except for the three from w(mky3), which had exactly the same 81-bp deletion in each of the 5' and 3' LTRs. The 5' and 3' ends of the deletion appeared to represent sequences similar to those of Drosophila consensussplicing sites. Ectopic splicing may have produced these defective ninja elements.

The transposable elements of the Drosophila melanogaster euchromatin: a genomics perspective

BACKGROUND

Transposable elements are found in the genomes of nearly all eukaryotes. The recent completion of the Release 3 euchromatic genomic sequence of Drosophila melanogaster by the Berkeley Drosophila Genome Project has provided precise sequence for the repetitive elements in the Drosophila euchromatin. We have used this genomic sequence to describe the euchromatic transposable elements in the sequenced strain of this species.

RESULTS

We identified 85 known and eight novel families of transposable element varying in copy number from one to 146. A total of 1,572 full and partial transposable elements were identified, comprising 3.86% of the sequence. More than two-thirds of the transposable elements are partial. The density of transposable elements increases an average of 4.7 times in the centromere-proximal regions of each of the major chromosome arms. We found that transposable elements are preferentially found outside genes; only 436 of 1,572 transposable elements are contained within the 61.4 Mb of sequence that is annotated as being transcribed. A large proportion of transposable elements is found nested within other elements of the same or different classes. Lastly, an analysis of structural variation from different families reveals distinct patterns of deletion for elements belonging to different classes.

CONCLUSIONS

This analysis represents an initial characterization of the transposable elements in the Release 3 euchromatic genomic sequence of D. melanogaster for which comparison to the transposable elements of other organisms can begin to be made. These data have been made available on the Berkeley Drosophila Genome Project website for future analyses.