Perspective: transposable elements, parasitic DNA, and genome evolution

The nature of the role played by mobile elements in host genome evolution is reassessed considering numerous recent developments in many areas of biology. It is argued that easy popular appellations such as "selfish DNA" and "junk DNA" may be either inaccurate or misleading and that a more enlightened view of the transposable element-host relationship encompasses a continuum from extreme parasitism to mutualism. Transposable elements are potent, broad spectrum, endogenous mutators that are subject to the influence of chance as well as selection at several levels of biological organization. Of particular interest are transposable element traits that early evolve neutrally at the host level but at a later stage of evolution are co-opted for new host functions.     

Amplification and Phylogenetic Relationships of a Subfamily of blood, a Retrotransposable Element of Drosophila

To get a better understanding of the effect of interelement selection on the variation of long terminal repeat retrotransposon families, we have investigated the evolutionary history of blood in the Drosophila melanogaster species complex. We carried out a PCR approach to amplify the 5′ untranslated region from blood in the four species of the complex. This procedure revealed two main classes of size variants. Phylogenetic analyses of nucleotide sequences from these variants and blood elements from the Drosophila Genome Projects database show that elements are grouped according to their size, so that they probably correspond to two subfamilies. These two subfamilies arose prior to the split of the complex, and several facts indicate that the expansion of one of them is leading to the competitive exclusion of the other, at least from the euchromatic regions of the genome. Received: 17 August 2000 / Accepted: 20 November 2000     

The ingi and RIME non-LTR retrotransposons are not randomly distributed in the genome of Trypanosoma brucei

The ingi (long and autonomous) and RIME (short and nonautonomous) non--long-terminal repeat retrotransposons are the most abundant mobile elements characterized to date in the genome of the African trypanosome Trypanosoma brucei. These retrotransposons were thought to be randomly distributed, but a detailed and comprehensive analysis of their genomic distribution had not been performed until now. To address this question, we analyzed the ingi/RIME sequences and flanking sequences from the ongoing T. brucei genome sequencing project (TREU927/4 strain). Among the 81 ingi/RIME elements analyzed, 60% are complete, and 7% of the ingi elements (approximately 15 copies per haploid genome) appear to encode for their own transposition. The size of the direct repeat flanking the ingi/RIME retrotransposons is conserved (i.e., 12-bp), and a strong 11-bp consensus pattern precedes the 5'-direct repeat. The presence of a consensus pattern upstream of the retroelements was confirmed by the analysis of the base occurrence in 294 GSS containing 5'-adjacent ingi/RIME sequences. The conserved sequence is present upstream of ingis and RIMEs, suggesting that ingi-encoded enzymatic activities are used for retrotransposition of RIMEs, which are short nonautonomous retroelements. In conclusion, the ingi and RIME retroelements are not randomly distributed in the genome of T. brucei and are preceded by a conserved sequence, which may be the recognition site of the ingi-encoded endonuclease.     

Construction of a BAC Contig for a 3 cM Biologically Significant Region of Mouse Chromosome 1

One QTL and genes and phenotypes have been localized in the region between 92 cM and 95cM of mouse chromosome 1. The QTL locus contributes to approximately 40% of the variation of the peak bone density between C57BL/6J (B6) and CAST/EiJ (CAST) strains. Other loci located in this chromosomal region include a neural tube defect mutant loop-tail (Lp), a lymphocyte-stimulating determinant (Lsd), and the Transgelin 2 (Tagln 2). The human chromosome region homologous to this region is 1q21-23, which also contains a QTL locus for high bone mineral density (BMD). Furthermore, it has been reported that this region may have duplicated several times in the mouse genome. Therefore, genomic sequencing of this region will provide important information for mouse genome structure, for positional cloning of mouse genes, and for the study of human homologous genes. In order to provide a suitable template for genomic sequencing by the NIH-sponsored genomic centers, we have constructed a BAC contig of this region using the RPCI-23 library. We have also identified the currently available mouse genomic sequences localized in our BAC contig. Further analysis of these sequences and BAC clones indicated a high frequency of repetitive sequences within this chromosomal area. This region also contains L1 retrotransposon sequences, providing a potential mechanism for the repetitive sequences described in the literature.     

Study on the evolution of the grande retrotransposon in the zea genus

The study of Grande retrotransposon (RTN) variation reported here comprises the intrinsic element variability and the changes that element insertion provokes in the Zea genome, including its abundance among species. Sequence analysis of a defined long-terminal repeat (LTR) region from Grande RTN revealed a high level of sequence divergence since no identical sequences were found among the 65 clones examined that belong to different Zea species or maize inbred lines. Average diversity values within accessions ranged from 0.17 to 0.37 substitutions per nucleotide. Phylogenetic analysis revealed a lack of concordance between the phylogenetic tree obtained from LTR sequences and the conventional taxonomic tree, suggesting that different subfamilies of Grande elements existed before Zea speciation. When sequence-specific amplification polymorphism (SSAP) marker data, which combines genomic and RTN variation, are used, the derived trees reflect the established species phylogeny and allow, as well, differentiating among some maize lines. Finally, the evaluation of Grande abundance, using different element probes in all the Zea species but Z. luxurians, revealed around 5,700 copies per haploid genome in all the diploid species examined, indicating a similar expansion process of Grande in all the Zea genomes. This number of copies represents in all cases around a 3% of the genome, which implies that Grande RTN is an important component of the maize genome. The copy number ratio LTR/gag is around 2 in all the species analyzed, indicating that overwhelming majority of elements have internal region. Thus, mechanisms such as homologous recombination between LTRs of a single RTN, which would remove the internal region and one LTR, leaving behind a single recombinant LTR, seems not to be active in maize for Grande RTN.     

Fitness costs of Doc expression are insufficient to stabilize its copy number in Drosophila melanogaster

The stable coexistence of transposable elements (TEs) with their host genome over long periods of time suggests TEs have to impose some deleterious effect upon their host fitness. Three mechanisms have been proposed to account for the deleterious effect caused by TEs: host gene interruptions by TE insertions, chromosomal rearrangements by TE-induced ectopic recombination, and costly TE expression. However, the relative importance of these mechanisms remains controversial. Here, we test specifically if TE expression accounts for the host fitness cost imposed by TE insertions. In the retrotransposon Doc, expression requires binding of the host RNA polymerase to the internal promoter. If expression of Doc elements is deleterious to their host, Doc copies with promoters would be more strongly selected against and would persist in the population for shorter periods of time compared with Docs lacking promoters. We tested this prediction using sequence-specific amplified polymorphism (SSAP) analyses. We compared the populations of these two types of Doc elements in two sets of lines of Drosophila melanogaster: selection-free isogenic lines accumulating new Doc insertions and isogenized isofemale lines sampled from a natural population. We found that (1) there is no difference in the proportion of promoter-bearing and promoter-lacking copies between sets of lines, and (2) the site occupancy distribution of promoter-bearing copies does not skew toward lower frequency compared with that of promoter-lacking copies. Thus, selection against promoter-bearing copies does not appear to be stronger than that of promoter-lacking copies. Our results show that expression is not playing a major role in stabilizing Doc copy numbers.