The adaptive significance of unproductive alternative splicing in primates

Skandalis, Adonis; Frampton, Mark B.; Seger, Jon; Richards, Miriam H.

doi:10.1261/rna.2127910

Cited by 18 publications

(22 citation statements)

References 36 publications

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“…Our comparison of human and chimpanzee splicing expands previous knowledge of AS species specificity (Calarco et al 2007;Skandalis et al 2010). Although the sequences of the evaluated genes GNAS and WT1 were highly conserved between human and chimpanzee, we found significant interspecies differences in spliceisoform ratios.…”

Section: Discussionsupporting

confidence: 68%

“…However, for most alternative transcripts, and in particular for those of low abundance, it is not obvious. Moreover, their formation often lacks phylogenetic conservation (Skandalis et al 2010). Isolated cases indicate, however, that low abundance of an alternative transcript and seemingly missing conservation are not sufficient criteria to discard an identified alternative transcript as being nonfunctional.…”

Section: Discussionmentioning

confidence: 99%

“…Even in a comparative analysis of AS patterns in humans and chimpanzees, hominid species separated by a relatively short period of evolutionary time and having very similar genome sequences, it turned out that 4-6% of genes show differences in splicing of orthologous exons (Calarco et al 2007). This indicates that AS may contribute to phenotypic differences between humans and chimpanzees (and more generally between all species) by diverged regulation of the splicing process of primary transcripts from genes that are very similar in their sequences (Skandalis et al 2010). Moreover, aberrations in splicing are also found as a cause of the development or progression of various diseases (Barbaux et al 1997;Valentonyte et al 2005), and splice mutations are suspected of contributing significantly to a variety of diseased states (Krawczak et al 1992).…”

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confidence: 99%

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Constant Splice-Isoform Ratios in Human Lymphoblastoid Cells Support the Concept of a Splico-Stat

et al. 2011

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Splicing generates mature transcripts from genes in pieces in eukaryotic cells. Overwhelming evidence has accumulated that alternative routes in splicing are possible for most human and mammalian genes, thereby allowing formation of different transcripts from one gene. No function has been assigned to the majority of identified alternative splice forms, and it has been assumed that they compose inert or tolerated waste from aberrant or noisy splicing. Here we demonstrate that five human transcription units (WT1, NOD2, GNAS, RABL2A, RABL2B) have constant splice-isoform ratios in genetically diverse lymphoblastoid cell lines independent of the type of alternative splicing (exon skipping, alternative donor/acceptor, tandem splice sites) and gene expression level. Even splice events that create premature stop codons and potentially trigger nonsense-mediated mRNA decay are found at constant fractions. The analyzed alternative splicing events were qualitatively but not quantitatively conserved in corresponding chimpanzee cell lines. Additionally, subtle splicing at tandem acceptor splice sites (GNAS, RABL2A/B) was highly constrained and strongly depends on the upstream donor sequence content. These results also demonstrate that unusual and unproductive splice variants are produced in a regulated manner. . DNA-encoded genetic information is kept separately in the chromosomes of a eukaryotic nucleus and is decoded via RNA intermediates, which are processed and transmitted to their destinations, for example, to the sites of cytoplasmic protein synthesis. Genes in pieces (composed of exons spaced apart by introns) additionally depend on a splice apparatus (spliceosome) that uses splice signals in a primary transcript to recognize exon-intron boundaries (splice sites) and to accurately cut out introns and join exons. Often, splicing generates different mature transcripts from the same gene, a process called alternative splicing (AS). This is achieved by alternative usage of splice sites in precursor RNA transcripts. In this way, the complexity of transcriptomes and proteomes is increased in eukaryotic organisms. Obviously, AS events need control to ensure formation of proper splice forms and ratios.Sequence motifs matching the splice-site consensus are very common in primary transcripts, but only a minute fraction of them are used by the spliceosome. This specificity is achieved by further sequence and structural information within the premature transcript recognized by different proteins. A complex network of highly combinatorial molecular interactions ensures the tissue-, developmental-, and elicitor-specific formation of spliced transcripts and is regulated at multiple points (Hertel 2008;Smith et al. 2008).Millions of short, single-pass cDNA sequence reads have accumulated in databases as expressed sequence tags supplemented from next-generation transcriptome sequencing data, both of which indicate that AS affects almost any multi-exon gene of any mammalian genome (Mortazavi et al. 2008;Wang et al. 2008).Howev...

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Section: Discussionsupporting

confidence: 68%

Section: Discussionmentioning

confidence: 99%

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confidence: 99%

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Constant Splice-Isoform Ratios in Human Lymphoblastoid Cells Support the Concept of a Splico-Stat

et al. 2011

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“…This suggests that the process of intronic APA itself may play roles in gene expression, but that the specific outcomes (which tend to vary for orthologous genes in the two species) are not as important. A similar proposal has been made for alternative splicing outcomes in primates [36]. Thus, although the alternative splicing of transcripts from the DNA polymerase beta locus in primates shows little conservation in terms of specific events, there is nonetheless extensive alternative splicing leading to unproductive transcript isoforms throughout the primate lineage.…”

Section: Discussionmentioning

confidence: 59%

Genome-wide determination of poly(A) sites in Medicago truncatula: evolutionary conservation of alternative poly(A) site choice

Gaffney

Hunt

et al. 2014

BMC Genomics

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BackgroundAlternative polyadenylation (APA) plays an important role in the post-transcriptional regulation of gene expression. Little is known about how APA sites may evolve in homologous genes in different plant species. To this end, comparative studies of APA sites in different organisms are needed. In this study, a collection of poly(A) sites in Medicago truncatula, a model system for legume plants, has been generated and compared with APA sites in Arabidopsis thaliana.ResultsThe poly(A) tags from a deep-sequencing protocol were mapped to the annotated M. truncatula genome, and the identified poly(A) sites used to update the annotations of 14,203 genes. The results show that 64% of M. truncatula genes possess more than one poly(A) site, comparable to the percentages reported for Arabidopsis and rice. In addition, the poly(A) signals associated with M. truncatula genes were similar to those seen in Arabidopsis and other plants. The 3′-UTR lengths are correlated in pairs of orthologous genes between M. truncatula and Arabidopsis. Very little conservation of intronic poly(A) sites was found between Arabidopsis and M. truncatula, which suggests that such sites are likely to be species-specific in plants. In contrast, there is a greater conservation of CDS-localized poly(A) sites in these two species. A sizeable number of M. truncatula antisense poly(A) sites were found. A high percentage of the associated target genes possess Arabidopsis orthologs that are also associated with antisense sites. This is suggestive of important roles for antisense regulation of these target genes.ConclusionsOur results reveal some distinct patterns of sense and antisense poly(A) sites in Arabidopsis and M. truncatula. In so doing, this study lends insight into general evolutionary trends of alternative polyadenylation in plants.Electronic supplementary materialThe online version of this article (doi:10.1186/1471-2164-15-615) contains supplementary material, which is available to authorized users.

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“…Molecular analyses over subsequent decades have demonstrated that alternative splicing influences intracellular localization, protein stability, enzymatic activity, and posttranslational modification (27,28). However, alternative splicing variants are often divided into two classes: productive or functional, wherein splice variants have biological functions; and unproductive or aberrant, representing transcripts with no known functions (29)(30)(31). Studies also have shown that unproductive splicing events prevent mRNA translation (e.g., no-go, non-sense-mediated, and nonstop decay) (32)(33)(34).…”

Section: Discussionmentioning

confidence: 99%

α3-Deletion Isoform of HLA-A11 Modulates Cytotoxicity of NK Cells: Correlations with HIV-1 Infection of Cells

Zhang

Lian

Dai

et al. 2017

The Journal of Immunology

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Alternative splicing occurs frequently in many genes, especially those involved in immunity. Unfortunately, the functions of many alternatively spliced molecules from immunologically relevant genes remain unknown. Classical HLA-I molecules are expressed on almost all nucleated cells and play a pivotal role in both innate and adaptive immunity. Although splice variants of HLA-I genes have been reported, the details of their functions have not been reported. In the current study, we determined the characteristics, expression, and function of a novel splice variant of HLA-A11 named HLA-A11svE4. HLA-A11svE4 is located on the cell surface without b2-microglobulin (b2m). Additionally, HLA-A11svE4 forms homodimers as well as heterodimers with HLA-A open conformers, instead of combining with b2m. Moreover, HLA-A11svE4 inhibits the activation of NK cells to protect target cells. Compared with b2m and HLA-A11, the heterodimer of HLA-A11svE4 and HLA-A11 protected target cells from lysis by NK cells more effectively. Furthermore, HLA-AsvE4 expression was upregulated by HIV-1 in vivo and by HSV, CMV, and hepatitis B virus in vitro. In addition, our findings indicated that HLA-A11svE4 molecules were functional in activating CD8 + T cells through Ag presentation. Taken together, these results suggested that HLA-A11svE4 can homodimerize and form a novel heterodimeric complex with HLA-A11 open conformers. Furthermore, the data are consistent with HLA-A11svE4 playing a role in the immune escape of HIV-1.

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The adaptive significance of unproductive alternative splicing in primates

Cited by 18 publications

References 36 publications

Constant Splice-Isoform Ratios in Human Lymphoblastoid Cells Support the Concept of a Splico-Stat

Constant Splice-Isoform Ratios in Human Lymphoblastoid Cells Support the Concept of a Splico-Stat

Genome-wide determination of poly(A) sites in Medicago truncatula: evolutionary conservation of alternative poly(A) site choice

α3-Deletion Isoform of HLA-A11 Modulates Cytotoxicity of NK Cells: Correlations with HIV-1 Infection of Cells

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