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ABSTRACT: The structural complexity of the vertebrate brain is mirrored by its unparalleled transcriptome complexity. In particular, two post-transcriptional processes, alternative splicing and RNA editing, greatly diversify brain transcriptomes. Here we report a close connection between these two processes: we show A-to-I RNA editing in Nova1, a key brain-specific regulator of alternative splicing. Nova1 editing levels increase during embryonic development in mouse and chicken brains and show significant variation across postnatal brain regions. Evolutionary conservation of both editing and editing-associated RNA secondary structure of the Nova1 mRNA for 300 million years attests to the functional importance of Nova1 editing. Using a combination of different assays in human HEK293T cell lines, we report a novel post-translational role for this RNA editing. Whereas functional assays showed no effect of RNA editing on the regulatory splicing activity of the encoded proteins, we found evidence that edited forms exhibit reduced proteasome targeting and increased protein half-life. In addition, we found evidence for similar regulation of protein half-life by an evolutionarily conserved alternative splicing event in Nova1. These results open new venues of research on the multi-level integration of gene expression by: (1) revealing the novel role of RNA editing in regulating protein stability, and (2) establishing protein stability as a new target of multifaceted regulation.
RNA biology 01/2012; 9(1):12-21. · 5.56 Impact Factor
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ABSTRACT: Organisms show striking differences in genome structure; however, the functional implications and fundamental forces that govern these differences remain obscure. The intron-exon organization of nuclear genes is involved in a particularly large variety of structures and functional roles. We performed a 22-species study of Meis/hth genes, intron-rich homeodomain-containing transcription factors involved in a wide range of developmental processes. Our study revealed three surprising results that suggest important and very different functions for Meis intron-exon structures. First, we find unexpected conservation across species of intron positions and lengths along most of the Meis locus. This contrasts with the high degree of structural divergence found in genome-wide studies and may attest to conserved regulatory elements residing within these conserved introns. Second, we find very different evolutionary histories for the 5' and 3' regions of the gene. The 5'-most 10 exons, which encode the highly conserved Meis domain and homeodomain, show striking conservation. By contrast, the 3' of the gene, which encodes several domains implicated in transcriptional activation and response to cell signaling, shows a remarkably active evolutionary history, with diverse isoforms and frequent creation and loss of new exons and splice sites. This region-specific diversity suggests evolutionary "tinkering," with alternative splicing allowing for more subtle regulation of protein function. Third, we find a large number of cases of convergent evolution in the 3' region, including 1) parallel losses of ancestral coding sequence, 2) parallel gains of external and internal splice sites, and 3) recurrent truncation of C-terminal coding regions. These results attest to the importance of locus-specific splicing functions in differences in structural evolution across genes, as well as to commonalities of forces shaping the evolution of individual genes along different lineages.
Genome Biology and Evolution 06/2011; 3:551-64. · 4.62 Impact Factor
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Manuel Irimia,
Amanda Denuc,
Demián Burguera,
Ildiko Somorjai,
Jose M Martín-Durán,
Grigory Genikhovich,
Senda Jimenez-Delgado,
Ulrich Technau, Scott W Roy,
Gemma Marfany,
Jordi Garcia-Fernàndez
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ABSTRACT: Novel organismal structures in metazoans are often undergirded by complex gene regulatory networks; as such, understanding the emergence of new structures through evolution requires reconstructing the series of evolutionary steps leading to these underlying networks. Here, we reconstruct the step-by-step assembly of the vertebrate splicing network regulated by Nova, a splicing factor that modulates alternative splicing in the vertebrate central nervous system by binding to clusters of YCAY motifs on pre-RNA transcripts. Transfection of human HEK293T cells with Nova orthologs indicated vertebrate-like splicing regulatory activity in bilaterian invertebrates, thus Nova acquired the ability to bind YCAY clusters and perform vertebrate-like splicing modulation at least before the last common ancestor of bilaterians. In situ hybridization studies in several species showed that Nova expression became restricted to CNS later on, during chordate evolution. Finally, comparative genomics studies revealed a diverse history for Nova-regulated exons, with target exons arising through both de novo exon creation and acquisition of YCAY motifs by preexisting exons throughout chordate and vertebrate history. In addition, we find that tissue-specific Nova expression patterns emerged independently in other lineages, suggesting independent assembly of tissue-specific regulatory networks.
Proceedings of the National Academy of Sciences 03/2011; 108(13):5319-24. · 9.68 Impact Factor
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ABSTRACT: In contrast to the typically streamlined genomes of prokaryotes, many eukaryotic genomes are riddled with long intergenic regions, spliceosomal introns, and repetitive elements. What explains the persistence of these and other seemingly suboptimal structures? There are three general hypotheses: (1) the structures in question are not actually suboptimal but optimal, being favored by selection, for unknown reasons; (2) the structures are not suboptimal, but of (essentially) equal fitness to "optimal" ones; or (3) the structures are truly suboptimal, but selection is too weak to systematically eliminate them. The 5' splice sites of introns offer a rare opportunity to directly test these hypotheses. Intron-poor species show a clear consensus splice site; most introns begin with the same six nucleotide sequence (typically GTAAGT or GTATGT), indicating efficient selection for this consensus sequence. In contrast, intron-rich species have much less pronounced boundary consensus sequences, and only small minorities of introns in intron-rich species share the same boundary sequence. We studied rates of evolutionary change of 5' splice sites in three groups of closely related intron-rich species--three primates, five Drosophila species, and four Cryptococcus fungi. Surprisingly, the results indicate that changes from consensus-to-variant nucleotides are generally disfavored by selection, but that changes from variant to consensus are neither favored nor disfavored. This evolutionary pattern is consistent with selective differences across introns, for instance, due to compensatory changes at other sites within the gene, which compensate for the otherwise suboptimal consensus-to-variant changes in splice boundaries.
Genome Research 10/2009; 19(11):2021-7. · 13.61 Impact Factor
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ABSTRACT: Alternative splicing (AS) is a widespread mechanism with an important role in increasing transcriptome and proteome diversity by generating multiple different products from the same gene. Evolutionary studies of AS have focused primarily on the conservation of alternatively spliced sequences or of the AS pattern of those sequences itself. Less is known about the evolution of the regulation of AS, but several studies, working from different perspectives, have recently made significant progress. Here, we categorize the different levels of AS evolution, and summarize the studies on evolution of AS regulation, which point to a high level of evolutionary conservation of the regulation of AS events conserved between related species. This suggests that the quantitative regulation of AS is an intrinsic part of AS function. We discuss the potential role of changes in developmental regulation of AS as an additional layer in complex gene regulatory networks and in the emergence of genetic novelties.
BioEssays 02/2009; 31(1):40-50. · 4.95 Impact Factor
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ABSTRACT: Alternative splicing (AS) contributes to increased transcriptome and proteome diversity in various eukaryotic lineages. Previous studies showed low levels of conservation of alternatively spliced (cassette) exons within mammals and within dipterans. We report a strikingly different pattern in Caenorhabditis nematodes-more than 92% of cassette exons from Caenorhabditis elegans are conserved in Caenorhabditis briggsae and/or Caenorhabditis remanei. High levels of conservation extend to minor-form exons (present in a minority of transcripts) and are particularly pronounced for exons showing complex patterns of splicing. The functionality of the vast majority of cassette exons is underscored by various other features. We suggest that differences in conservation between lineages reflect differences in levels of functionality and further suggest that these differences are due to differences in intron length and the strength of consensus boundaries across lineages. Finally, we demonstrate an inverse relationship between AS and gene duplication, suggesting that the latter may be primarily responsible for the emergence of new functional transcripts in nematodes.
Molecular Biology and Evolution 03/2008; 25(2):375-82. · 5.55 Impact Factor
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ABSTRACT: Spliceosomal intron numbers and boundary sequences vary dramatically in eukaryotes. We found a striking correspondence between low intron number and strong sequence conservation of 5' splice sites (5'ss) across eukaryotic genomes. The phylogenetic pattern suggests that ancestral 5'ss were relatively weakly conserved, but that some lineages independently underwent both major intron loss and 5'ss strengthening. It seems that eukaryotic ancestors had relatively large intron numbers and 'weak' 5'ss, a pattern associated with frequent alternative splicing in modern organisms.
Trends in Genetics 08/2007; 23(7):321-5. · 10.06 Impact Factor
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ABSTRACT: Eukaryotic protein-coding genes are interrupted by spliceosomal introns, which are removed from transcripts before protein translation. Many facets of spliceosomal intron evolution, including age, mechanisms of origins, the role of natural selection, and the causes of the vast differences in intron number between eukaryotic species, remain debated. Genome sequencing and comparative analysis has made possible whole genome analysis of intron evolution to address these questions.
We analyzed intron positions in 1,161 sets of orthologous genes across 25 eukaryotic species. We find strong support for an intron-rich fungus-animal ancestor, with more than four introns per kilobase, comparable to the highest known modern intron densities. Indeed, the fungus-animal ancestor is estimated to have had more introns than any of the extant fungi in this study. Thus, subsequent fungal evolution has been characterized by widespread and recurrent intron loss occurring in all fungal clades. These results reconcile three previously proposed methods for estimation of ancestral intron number, which previously gave very different estimates of ancestral intron number for eight eukaryotic species, as well as a fourth more recent method. We do not find a clear inverse correspondence between rates of intron loss and gain, contrary to the predictions of selection-based proposals for interspecific differences in intron number.
Our results underscore the high intron density of eukaryotic ancestors and the widespread importance of intron loss through eukaryotic evolution.
Genome biology 02/2007; 8(10):R223. · 6.63 Impact Factor
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Scott W Roy
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ABSTRACT: Eukaryotic genes are interrupted by spliceosomal introns, which are removed from gene transcripts. The number of introns per gene varies by more than two orders of magnitude between species, implying that there has been extensive intron loss and/or gain throughout eukaryotic evolution. A recent study of intron positions in animals confirms that the ancestral bilaterian was rich in introns, and that differences in intron number between animals largely reflect different levels of intron loss. These results refocus our attention on the evolutionary history and importance of introns in early eukaryotic evolution.
Trends in Genetics 10/2006; 22(9):468-71. · 10.06 Impact Factor
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ABSTRACT: We use the pattern of intron conservation in 684 groups of orthologs from seven fully sequenced eukaryotic genomes to provide maximum likelihood estimates of the number of introns present in the same orthologs in various eukaryotic ancestors. We find: (i) intron density in the plant-animal ancestor was high, perhaps two-thirds that of humans and three times that of Drosophila; and (ii) intron density in the ancestral bilateran was also high, equaling that of humans and four times that of Drosophila. We further find that modern introns are generally very old, with two-thirds of modern bilateran introns dating to the ancestral bilateran and two-fifths of modern plant, animal, and fungus introns dating to the plant-animal ancestor. Intron losses outnumber gains over a large range of eukaryotic lineages. These results show that early eukaryotic gene structures were very complex, and that simplification, not embellishment, has dominated subsequent evolution.
Proceedings of the National Academy of Sciences 03/2005; 102(6):1986-91. · 9.68 Impact Factor
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ABSTRACT: We studied intron loss in 684 groups of orthologous genes from seven fully sequenced eukaryotic genomes. We found that introns closer to the 3' ends of genes are preferentially lost, as predicted if introns are lost through gene conversion with a reverse transcriptase product of a spliced mRNA. Adjacent introns tend to be lost in concert, as expected if such events span multiple intron positions. Directly contrary to the expectations of some, introns that do not interrupt codons (phase zero) are more, not less, likely to be lost, an intriguing and previously unappreciated result. Adjacent introns with matching phases are not more likely to be retained, as would be expected if they enjoyed a relative selective advantage. The findings of 3' and phase zero intron loss biases are in direct contradiction to an extremely recent study of fungi intron evolution. All patterns are less pronounced in the lineage leading to Caenorhabditis elegans, suggesting that the process of intron loss may be qualitatively different in nematodes. Our results support a reverse transcriptase-mediated model of intron loss.
Proceedings of the National Academy of Sciences 02/2005; 102(3):713-8. · 9.68 Impact Factor
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Scott W Roy
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ABSTRACT: The long-standing question of how genes acquire introns has provoked much debate. A recent study makes considerable progress by identifying numerous recently gained introns in nematodes - although it remains difficult to distinguish definitively between models of intron gain.
Genome biology 02/2004; 5(12):251. · 6.63 Impact Factor
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ABSTRACT: We compared intron-exon structures in 1,560 human-mouse orthologs and 360 mouse-rat orthologs. The origin of differences in intron positions between species was inferred by comparison with an outgroup, Fugu for human-mouse and human for mouse-rat. Among 10,020 intron positions in the human-mouse comparison, we found unequivocal evidence for five independent intron losses in the mouse lineage but no evidence for intron loss in humans or for intron gain in either lineage. Among 1,459 positions in rat-mouse comparisons, we found evidence for one loss in rat but neither loss in mouse nor gain in either lineage. In each case, the intron losses were exact, without change in the surrounding coding sequence, and involved introns that are extremely short, with an average of 200 bp, an order of magnitude shorter than the mammalian average. These results favor a model whereby introns are lost through gene conversion with intronless copies of the gene. In addition, the finding of widespread conservation of intron-exon structure, even over large evolutionary distances, suggests that comparative methods employing information about gene structures should be very successful in correctly predicting exon boundaries in genomic sequences.
Proceedings of the National Academy of Sciences 07/2003; 100(12):7158-62. · 9.68 Impact Factor
