BackgroundThe synaptonemal complex (SC) is a highly conserved meiotic structure that functions to pair homologs and facilitate meiotic recombination in most eukaryotes. Five Drosophila SC proteins have been identified and localized within the complex: C(3)G, C(2)M, CONA, ORD, and the newly identified Corolla. The SC is required for meiotic recombination in Drosophila and absence of these proteins leads to reduced crossing over and chromosomal nondisjunction. Despite the conserved nature of the SC and the key role that these five proteins have in meiosis in D. melanogaster, they display little apparent sequence conservation outside the genus. To identify factors that explain this lack of apparent conservation, we performed a molecular evolutionary analysis of these genes across the Drosophila genus.ResultsFor the five SC components, gene sequence similarity declines rapidly with increasing phylogenetic distance and only ORD and C(2)M are identifiable outside of the Drosophila genus. SC gene sequences have a higher dN/dS (ω) rate ratio than the genome wide average and this can in part be explained by the action of positive selection in almost every SC component. Across the genus, there is significant variation in ω for each protein. It further appears that ω estimates for the five SC components are in accordance with their physical position within the SC. Components interacting with chromatin evolve slowest and components comprising the central elements evolve the most rapidly. Finally, using population genetic approaches, we demonstrate that positive selection on SC components is ongoing.ConclusionsSC components within Drosophila show little apparent sequence homology to those identified in other model organisms due to their rapid evolution. We propose that the Drosophila SC is evolving rapidly due to two combined effects. First, we propose that a high rate of evolution can be partly explained by low purifying selection on protein components whose function is to simply hold chromosomes together. We also propose that positive selection in the SC is driven by its sex-specificity combined with its role in facilitating both recombination and centromere clustering in the face of recurrent bouts of drive in female meiosis.Electronic supplementary materialThe online version of this article (doi:10.1186/s12862-016-0670-8) contains supplementary material, which is available to authorized users.
Centromeres are chromosomal regions essential for coordinating chromosome segregation during cell division. While centromeres are defined by the presence of a centromere-specific histone H3 variant called CENP-A rather than a particular DNA sequence, they are typically embedded in repeat-dense and heterochromatic chromosomal genome regions. In many species, centromeres are associated with transposable elements but it is unclear if these elements are selfish and target centromeres for insertion or if they play a role in centromere specification and function. Here we use Drosophila melanogaster as a model to understand the evolution of centromere-associated transposable elements. G2/Jockey-3 is a non-LTR retroelement in the Jockey clade and the only sequence shared by all centromeres. We study the evolution of G2/Jockey-3 using short and long read population genomic data to infer insertion polymorphisms across the genome. We combine estimates of the age, frequency, and location of insertions to infer the evolutionary processes shaping G2/Jockey-3 and its association with the centromeres. We find that G2/Jockey-3 is an active retroelement that is targeted by the piRNA pathway. Our results suggest that G2-Jockey-3 is highly enriched in centromeres at least in part due to an insertion bias. We do not detect any signature of positive selection on any G2/Jockey-3 insertions that would suggest than individual insertions are favored by natural selection. Instead, we infer that most insertions are neutral or weakly deleterious both inside and outside of the centromeres. Therefore, G2/Jockey-3 evolution is consistent with it being a selfish genetic element that targets centromeres. We suspect targeting centromeres for insertion helps active retroelements like G2/Jockey-3 escape host defenses, as the unique centromeric chromatin may prevent targeting by the host silencing machinery. On the other hand, centromeric TEs insertions may be tolerated or even beneficial if they also contribute to the right transcriptional and chromatin environment. Thus, we suspect centromere-associated retroelements like G2/Jockey-3 reflect a balance between conflict and cooperation at the centromeres.
Background: Transposable elements (TEs) are endogenous mutagens and their harmful effects are especially evident in syndromes of hybrid dysgenesis. In Drosophila virilis, hybrid dysgenesis is a syndrome of incomplete gonadal atrophy that occurs when males with multiple active TE families fertilize females that lack active copies of the same families. This has been demonstrated to cause the transposition of paternally inherited TE families, with gonadal atrophy driven by the death of germline stem cells. Because there are abundant, active TEs in the male inducer genome, that are not present in the female reactive genome, the D. virilis syndrome serves as an excellent model for understanding the effects of hybridization between individuals with asymmetric TE profiles. Results: Using the D. virilis syndrome of hybrid dysgenesis as a model, we sought to determine how the landscape of germline recombination is affected by parental TE asymmetry. Using a genotyping-by-sequencing approach, we generated a high-resolution genetic map of D. virilis and show that recombination rate and TE density are negatively correlated in this species. We then contrast recombination events in the germline of dysgenic versus non-dysgenic F1 females to show that the landscape of meiotic recombination is hardly perturbed during hybrid dysgenesis. In contrast, hybrid dysgenesis in the female germline increases transmission of chromosomes with mitotic recombination. Using a de novo PacBio assembly of the D. virilis inducer genome we show that clusters of mitotic recombination events in dysgenic females are associated with genomic regions with transposons implicated in hybrid dysgenesis. Conclusions: Overall, we conclude that increased mitotic recombination is likely the result of early TE activation in dysgenic progeny, but a stable landscape of meiotic recombination indicates that either transposition is ameliorated in the adult female germline or that regulation of meiotic recombination is robust to ongoing transposition. These results indicate that the effects of parental TE asymmetry on recombination are likely sensitive to the timing of transposition.
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