RESUMO
BACKGROUND: Transposable element (TE) sequences are classified into families based on the reconstructed history of replication, and into subfamilies based on more fine-grained features that are often intended to capture family history. We evaluate the reliability of annotation with common subfamilies by assessing the extent to which subfamily annotation is reproducible in replicate copies created by segmental duplications in the human genome, and in homologous copies shared by human and chimpanzee. RESULTS: We find that standard methods annotate over 10% of replicates as belonging to different subfamilies, despite the fact that they are expected to be annotated as belonging to the same subfamily. Point mutations and homologous recombination appear to be responsible for some of this discordant annotation (particularly in the young Alu family), but are unlikely to fully explain the annotation unreliability. CONCLUSIONS: The surprisingly high level of disagreement in subfamily annotation of homologous sequences highlights a need for further research into definition of TE subfamilies, methods for representing subfamily annotation confidence of TE instances, and approaches to better utilizing such nuanced annotation data in downstream analysis.
RESUMO
Comparative genomics from mitochondria, plastids, and mutualistic endosymbiotic bacteria has shown that the stable establishment of a bacterium in a host cell results in genome reduction. Although many highly reduced genomes from endosymbiotic bacteria are stable in gene content and genome structure, organelle genomes are sometimes characterized by dramatic structural diversity. Previous results from Candidatus Hodgkinia cicadicola, an endosymbiont of cicadas, revealed that some lineages of this bacterium had split into two new cytologically distinct yet genetically interdependent species. It was hypothesized that the long life cycle of cicadas in part enabled this unusual lineage-splitting event. Here we test this hypothesis by investigating the structure of the Ca. Hodgkinia genome in one of the longest-lived cicadas, Magicicada tredecim. We show that the Ca. Hodgkinia genome from M. tredecim has fragmented into multiple new chromosomes or genomes, with at least some remaining partitioned into discrete cells. We also show that this lineage-splitting process has resulted in a complex of Ca. Hodgkinia genomes that are 1.1-Mb pairs in length when considered together, an almost 10-fold increase in size from the hypothetical single-genome ancestor. These results parallel some examples of genome fragmentation and expansion in organelles, although the mechanisms that give rise to these extreme genome instabilities are likely different.
