The phylogeny of insects, one of the most spectacular radiations of life on earth, has received considerable attention. However, the evolutionary roots of one intriguing group of insects, the twisted-wing parasites (Strepsiptera), remain unclear despite centuries of study and debate. Strepsiptera exhibit exceptional larval developmental features, consistent with a predicted step from direct (hemimetabolous) larval development to complete metamorphosis that could have set the stage for the spectacular radiation of metamorphic (holometabolous) insects. Here we report the sequencing of a Strepsiptera genome and show that the analysis of sequence-based genomic data (comprising more than 18 million nucleotides from nearly 4,500 genes obtained from a total of 13 insect genomes), along with genomic metacharacters, clarifies the phylogenetic origin of Strepsiptera and sheds light on the evolution of holometabolous insect development. Our results provide overwhelming support for Strepsiptera as the closest living relatives of beetles (Coleoptera). They demonstrate that the larval developmental features of Strepsiptera, reminiscent of those of hemimetabolous insects, are the result of convergence. Our analyses solve the long-standing enigma of the evolutionary roots of Strepsiptera and reveal that the holometabolous mode of insect development is more malleable than previously thought.
A plethora of new functions of non-coding RNAs have been discovered in past few years. In fact, RNA is emerging as the central player in cellular regulation, taking on active roles in multiple regulatory layers from transcription, RNA maturation, and Manuscript January 2005RNA modification to translational regulation. Nevertheless, very little is known about the evolution of this "Modern RNA World" and its components. In this contribution we attempt to provide at least a cursory overview of the diversity of non-coding RNAs and functional RNA motifs in non-translated regions of regular messenger RNAs (mRNAs) with an emphasis on evolutionary questions. This survey is complemented by an in-depth analysis of examples from different classes of RNAs focusing mostly on their evolution in the vertebrate lineage. We present a survey of Y RNA genes in vertebrates, studies of the molecular evolution of the U7 snRNA, the snoRNAs E1/U17, E2, and E3, the Y RNA family, the let-7 microRNA family, and the mRNA-like evf-1 gene. We furthermore discuss the statistical distribution of microRNAs in metazoans, which suggests an explosive increase in the microRNA repertoire in vertebrates. The analysis of the transcription of non-coding RNAs (ncRNAs) suggests that small RNAs in general are genetically mobile in the sense that their association with a hostgene (e.g. when transcribed from introns of a mRNA) can change on evolutionary time scales. The let-7 family demonstrates, that even the mode of transcription (as intron or as exon) can change among paralogous ncRNA.
Today, the reconstruction of the organismal evolutionary tree is based mainly on molecular sequence data. However, sequence data are sometimes insufficient to reliably resolve in particular deep branches. Thus, it is highly desirable to find novel, more reliable types of phylogenetic markers that can be derived from the wealth of genomic data. Here, we consider the gain of introns close to older preexisting ones. Because correct splicing is impeded by very small exons, nearby pairs of introns very rarely coexist, that is, the gain of the new intron is nearly always associated with the loss of the old intron. Both events may even be directly connected as in cases of intron migration. Therefore, it should be possible to identify one of the introns as ancient (plesiomorphic) and the other as novel (derived or apomorphic). To test the suitability of such near intron pairs (NIPs) as a marker class for phylogenetic analysis, we undertook an analysis of the evolutionary positions of bees and wasps (Hymenoptera) and beetles (Coleoptera) in relation to moths (Lepidoptera) and dipterans (Diptera) using recently completed genome project data. By scanning 758 putatively orthologous gene structures of Apis mellifera (Hymenoptera) and Tribolium castaneum (Coleoptera), we identified 189 pairs of introns, one from each species, which are located less than 50 nt from each other. A comparison with genes from 5 other holometabolan and 9 metazoan outgroup genomes resulted in 22 shared derived intron positions found in beetle as well as in butterflies and/or dipterans. This strongly supports a basal position of hymenopterans in the holometabolous insect tree. In addition, we found 31 and 12 intron positions apomorphic for A. mellifera and T. castaneum, respectively, which seem to represent changes inside these branches. Another 12 intron pairs indicate parallel intron gains or extraordinarily small exons. In conclusion, we show here that the analysis of phylogenetically nested, nearby intron pairs is suitable to identify evolutionarily younger intron positions and to determine their relative age, which should be of equal importance for the understanding of intron evolution and the reconstruction of the eukaryotic tree.
BackgroundPositions of spliceosomal introns are often conserved between remotely related genes. Introns that reside in non-conserved positions are either novel or remnants of frequent losses of introns in some evolutionary lineages. A recent gain of such introns is difficult to prove. However, introns verified as novel are needed to evaluate contemporary processes of intron gain.ResultsWe identified 25 unambiguous cases of novel intron positions in 31 Drosophila genes that exhibit near intron pairs (NIPs). Here, a NIP consists of an ancient and a novel intron position that are separated by less than 32 nt. Within a single gene, such closely-spaced introns are very unlikely to have coexisted. In most cases, therefore, the ancient intron position must have disappeared in favour of the novel one. A survey for NIPs among 12 Drosophila genomes identifies intron sliding (migration) as one of the more frequent causes of novel intron positions. Other novel introns seem to have been gained by regional tandem duplications of coding sequences containing a proto-splice site.ConclusionsRecent intron gains sometimes appear to have arisen by duplication of exonic sequences and subsequent intronization of one of the copies. Intron migration and exon duplication together may account for a significant amount of novel intron positions in conserved coding sequences.
Motivation: In the last years more than 20 vertebrate genomes have been sequenced, and the rate at which genomic DNA information becomes available is rapidly accelerating. Gene duplication and gene loss events inherently limit the accuracy of orthology detection based on sequence similarity alone. Fully automated methods for orthology annotation do exist but often fail to identify individual members in cases of large gene families, or to distinguish missing data from traceable gene losses. This situation can be improved in many cases by including conserved synteny information.
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