Systematic identification of balanced transposition polymorphisms in Saccharomyces cerevisiae.

High-throughput techniques for detecting DNA polymorphisms generally do not identify changes in which the genomic position of a sequence, but not its copy number, varies among individuals. To explore such balanced structural polymorphisms, we used array-based Comparative Genomic Hybridization (aCGH) to conduct a genome-wide screen for single-copy genomic segments that occupy different genomic positions in the standard laboratory strain of Saccharomyces cerevisiae (S90) and a polymorphic wild isolate (Y101) through analysis of six tetrads from a cross of these two strains. Paired-end high-throughput sequencing of Y101 validated four of the predicted rearrangements. The transposed segments contained one to four annotated genes each, yet crosses between S90 and Y101 yielded mostly viable tetrads. The longest segment comprised 13.5 kb near the telomere of chromosome XV in the S288C reference strain and Southern blotting confirmed its predicted location on chromosome IX in Y101. Interestingly, inter-locus crossover events between copies of this segment occurred at a detectable rate. The presence of low-copy repetitive sequences at the junctions of this segment suggests that it may have arisen through ectopic recombination. Our methodology and findings provide a starting point for exploring the origins, phenotypic consequences, and evolutionary fate of this largely unexplored form of genomic polymorphism.

Evidence for the adaptive significance of an LTR retrotransposon sequence in a Drosophila heterochromatic gene.

BACKGROUND: The potential adaptive significance of transposable elements (TEs) to the host genomes in which they reside is a topic that has been hotly debated by molecular evolutionists for more than two decades. Recent genomic analyses have demonstrated that TE fragments are associated with functional genes in plants and animals. These findings suggest that TEs may contribute significantly to gene evolution. RESULTS: We have analyzed two transposable elements associated with genes in the sequenced Drosophila melanogaster y; cn bw sp strain. A fragment of the Antonia long terminal repeat (LTR) retrotransposon is present in the intron of Chitinase 3 (Cht3), a gene located within the constitutive heterochromatin of chromosome 2L. Within the euchromatin of chromosome 2R a full-length Burdock LTR retrotransposon is located immediately 3' to cathD, a gene encoding cathepsin D. We tested for the presence of these two TE/gene associations in strains representing 12 geographically diverse populations of D. melanogaster. While the cathD insertion variant was detected only in the sequenced y; cn bw sp strain, the insertion variant present in the heterochromatic Cht3 gene was found to be fixed throughout twelve D. melanogaster populations and in a D. mauritiana strain suggesting that it maybe of adaptive significance. To further test this hypothesis, we sequenced a 685bp region spanning the LTR fragment in the intron of Cht3 in strains representative of the two sibling species D. melanogaster and D. mauritiana (approximately 2.7 million years divergent). The level of sequence divergence between the two species within this region was significantly lower than expected from the neutral substitution rate and lower than the divergence observed between a randomly selected intron of the Drosophila Alcohol dehydrogenase gene (Adh). CONCLUSIONS: Our results suggest that a 359 bp fragment of an Antonia retrotransposon (complete LTR is 659 bp) located within the intron of the Drosophila melanogaster Cht3 gene is of adaptive evolutionary significance. Our results are consistent with previous suggestions that the presence of TEs in constitutive heterochromatin may be of significance to the expression of heterochromatic genes.

Evolutionary history of Oryza sativa LTR retrotransposons: a preliminary survey of the rice genome sequences.

BACKGROUND: LTR Retrotransposons transpose through reverse transcription of an RNA intermediate and are ubiquitous components of all eukaryotic genomes thus far examined. Plant genomes, in particular, have been found to be comprised of a remarkably high number of LTR retrotransposons. There is a significant body of direct and indirect evidence that LTR retrotransposons have contributed to gene and genome evolution in plants. RESULTS: To explore the evolutionary history of long terminal repeat (LTR) retrotransposons and their impact on the genome of Oryza sativa, we have extended an earlier computer-based survey to include all identifiable full-length, fragmented and solo LTR elements in the rice genome database as of April 2002. A total of 1,219 retroelement sequences were identified, including 217 full-length elements, 822 fragmented elements, and 180 solo LTRs. In order to gain insight into the chromosomal distribution of LTR-retrotransposons in the rice genome, a detailed examination of LTR-retrotransposon sequences on Chromosome 10 was carried out. An average of 22.3 LTR-retrotransposons per Mb were detected in Chromosome 10. CONCLUSIONS: Gypsy-like elements were found to be >4 x more abundant than copia-like elements. Eleven of the thirty-eight investigated LTR-retrotransposon families displayed significant subfamily structure. We estimate that at least 46.5% of LTR-retrotransposons in the rice genome are older than the age of the species (< 680,000 years). LTR-retrotransposons present in the rice genome range in age from those just recently inserted up to nearly 10 million years old. Approximately 20% of LTR retrotransposon sequences lie within putative genes. The distribution of elements across chromosome 10 is non-random with the highest density (48 elements per Mb) being present in the pericentric region.

Divergence in expression between duplicated genes in Arabidopsis.

New genes may arise through tandem duplication, dispersed small-scale duplication, and polyploidy, and patterns of divergence between duplicated genes may vary among these classes. We have examined patterns of gene expression and coding sequence divergence between duplicated genes in Arabidopsis thaliana. Due to the simultaneous origin of polyploidy-derived gene pairs, we can compare covariation in the rates of expression divergence and sequence divergence within this group. Among tandem and dispersed duplicates, much of the divergence in expression profile appears to occur at or shortly after duplication. Contrary to findings from other eukaryotic systems, there is little relationship between expression divergence and synonymous substitutions, whereas there is a strong positive relationship between expression divergence and nonsynonymous substitutions. Because this pattern is pronounced among the polyploidy-derived pairs, we infer that the strength of purifying selection acting on protein sequence and expression pattern is correlated. The polyploidy-derived pairs are somewhat atypical in that they have broader expression patterns and are expressed at higher levels, suggesting differences among polyploidy- and nonpolyploidy-derived duplicates in the types of genes that revert to single copy. Finally, within many of the duplicated pairs, 1 gene is expressed at a higher level across all assayed conditions, which suggests that the subfunctionalization model for duplicate gene preservation provides, at best, only a partial explanation for the patterns of expression divergence between duplicated genes.

The contribution of LTR retrotransposon sequences to gene evolution in Mus musculus.

Approximately 1.5% of mouse genes (Mus musculus) contain long terminal repeat retrotransposon sequences (LRS). Consistent with earlier findings in Caenorhabditis elegans, Drosophila melanogaster, and Homo sapiens, LRS are more likely to be associated with newly evolved genes. Evidence is presented that LRS are often recruited as novel exons or as spliced additions to existing exons. These novel gene configurations may be expressed initially as alternative transcripts providing an opportunity for the evolution of new gene function.

LTR retrotransposon-gene associations in Drosophila melanogaster.

Thirty-three percent (228/682) of all long terminal repeat (LTR) retrotransposon sequences (LRSs) present in the sequenced Drosophila melanogaster genome were found to be located in or within 1000 bp of a gene. Recently inserted LTR retrotransposons are significantly more likely to be located in or within genes than are older, fragmented LTR retrotransposon sequences, indicating that most LRS-gene associations are selected against over evolutionary time. LRSs associated with conserved genes (homologenes) are especially prone to negative selection. In contrast, fragmented LRSs that have persisted in the genome over long spans of evolutionary time are preferentially associated with genes involved in signal transduction and other newly evolved functions.

Retrotransposon-gene associations are widespread among D. melanogaster populations.

We have surveyed 18 natural populations of Drosophila melanogaster for the presence of 23 retrotransposon-gene-association alleles (i.e., the presence of an LTR retrotransposon sequence in or within 1,000 bp of a gene) recently identified in the sequenced D. melanogaster genome. The identified associations were detected only in the D. melanogaster populations. The majority (61%) of the identified retrotransposon-gene associations were present only in the sequenced strain in which they were first identified. Thirty percent of the associations were detected in at least one of the natural populations, and 9% of the associations were detected in all of the D. melanogaster populations surveyed. Sequence analysis of an association allele present in all populations indicates that selection is a significant factor in the spread and/or maintenance of at least some of retroelement-gene associations in D. melanogaster.

Evidence for the contribution of LTR retrotransposons to C. elegans gene evolution.

LTR retrotransposons may be important contributors to host gene evolution because they contain regulatory and coding signals. In an effort to assess the possible contribution of LTR retrotransposons to C. elegans gene evolution, we searched upstream and downstream of LTR retrotransposon sequences for the presence of predicted genes. Sixty-three percent of LTR retrotransposon sequences (79/124) are located within 1 kb of a gene or within gene boundaries. Most gene-retrotransposon associations were located along the chromosome arms. Our results are consistent with the hypothesis that LTR retrotransposons have contributed to the structural and/or regulatory evolution of genes in C. elegans.