MiasDB: A Database of Molecular Interactions Associated with Alternative Splicing of Human Pre-mRNAs

Xing, Yongzhong; Zhao, Xingbo; Yu, Tao; Liang, Dong; Li, Jun; Wei, Guanyun; Liu, Guoqing; Cui, Xiangjun; Zhao, Hongyu; Cai, Liang

doi:10.1371/journal.pone.0155443

Cited by 12 publications

(13 citation statements)

References 41 publications

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“…Predictors describe the potential impact of sSNVs on splicing by relying on the identified putative ESE and ESS motifs. Identification of these motifs and the corresponding splicing regulatory proteins has been an ongoing experimental and computational effort (Wang and Burge, 2008; Shepard and Hertel, 2009); identified motifs and regulatory proteins are available via public repositories (Desmet et al, 2009; Giulietti et al, 2013; Xing et al, 2016). Tools such as SPANR (Splicing-based Analysis of Variants) (Xiong et al, 2015), have also been developed to predict the splicing effects of SNVs.…”

Section: Methodology Of the Predictorsmentioning

confidence: 99%

Predicting Functional Effects of Synonymous Variants: A Systematic Review and Perspectives

Zeng

Bromberg

2019

Front. Genet.

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Recent advances in high-throughput experimentation have put the exploration of genome sequences at the forefront of precision medicine. In an effort to interpret the sequencing data, numerous computational methods have been developed for evaluating the effects of genome variants. Interestingly, despite the fact that every person has as many synonymous (sSNV) as non-synonymous single nucleotide variants, our ability to predict their effects is limited. The paucity of experimentally tested sSNV effects appears to be the limiting factor in development of such methods. Here, we summarize the details and evaluate the performance of nine existing computational methods capable of predicting sSNV effects. We used a set of observed and artificially generated variants to approximate large scale performance expectations of these tools. We note that the distribution of these variants across amino acid and codon types suggests purifying evolutionary selection retaining generated variants out of the observed set; i.e., we expect the generated set to be enriched for deleterious variants. Closer inspection of the relationship between the observed variant frequencies and the associated prediction scores identifies predictor-specific scoring thresholds of reliable effect predictions. Notably, across all predictors, the variants scoring above these thresholds were significantly more often generated than observed. which confirms our assumption that the generated set is enriched for deleterious variants. Finally, we find that while the methods differ in their ability to identify severe sSNV effects, no predictor appears capable of definitively recognizing subtle effects of such variants on a large scale.

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Section: Methodology Of the Predictorsmentioning

confidence: 99%

Predicting Functional Effects of Synonymous Variants: A Systematic Review and Perspectives

Zeng

Bromberg

2019

Front. Genet.

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“…SASD [ 18 ] was developed for proteomics studies to detect consequences of alternative splicing. In MiasDB there are data for interactions of molecules involved in alternative splicing [ 19 ].…”

Section: Databases For Rna Variationsmentioning

confidence: 99%

Systematics for types and effects of RNA variations

Vihinen

2020

RNA Biology

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Systematics is described for annotation of variations in RNA molecules. The conceptual framework is part of Variation Ontology (VariO) and facilitates depiction of types of variations, their functional and structural effects and other consequences in any RNA molecule in any organism. There are more than 150 RNA related VariO terms in seven levels, which can be further combined to generate even more complicated and detailed annotations. The terms are described together with examples, usually for variations and effects in human and in diseases. RNA variation type has two subcategories: variation classification and origin with subterms. Altogether six terms are available for function description. Several terms are available for affected RNA properties. The ontology contains also terms for structural description for affected RNA type, post-transcriptional RNA modifications, secondary and tertiary structure effects and RNA sugar variations. Together with the DNA and protein concepts and annotations, RNA terms allow comprehensive description of variations of genetic and non-genetic origin at all possible levels. The VariO annotations are readable both for humans and computer programs for advanced data integration and mining.

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“…MiasDB contains interactions between splicing factors, epigenetic marks and cis -regulatory elements as well as the interaction between trans -acting proteins. This resource is currently available only for human interactions and coverage is still incomplete [ 81 ]. In future work, there are plans to integrate MiasDB with established signalling pathway database KEGG [ 82 ].…”

Section: Splicing Regulation Networkmentioning

confidence: 99%

“…This restricts the experimental conditions under which epigenetics and splicing can be analysed [ 76 , 85 ]. Furthermore, the annotation of results requires prior knowledge [ 59 , 79 ] but databases on prior knowledge are not complete and exist only for specific organisms [ 80 , 81 ].…”

Section: Current Limitations and Challengesmentioning

confidence: 99%

Bioinformatics challenges and perspectives when studying the effect of epigenetic modifications on alternative splicing

Pacini

Koziol

2018

Phil. Trans. R. Soc. B

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It is widely known that epigenetic modifications are important in regulating transcription, but several have also been reported in alternative splicing. The regulation of pre-mRNA splicing is important to explain proteomic diversity and the misregulation of splicing has been implicated in many diseases. Here, we give a brief overview of the role of epigenetics in alternative splicing and disease. We then discuss the bioinformatics methods that can be used to model interactions between epigenetic marks and regulators of splicing. These models can be used to identify alternative splicing and epigenetic changes across different phenotypes.This article is part of a discussion meeting issue ‘Frontiers in epigenetic chemical biology’.

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MiasDB: A Database of Molecular Interactions Associated with Alternative Splicing of Human Pre-mRNAs

Cited by 12 publications

References 41 publications

Predicting Functional Effects of Synonymous Variants: A Systematic Review and Perspectives

Predicting Functional Effects of Synonymous Variants: A Systematic Review and Perspectives

Systematics for types and effects of RNA variations

Bioinformatics challenges and perspectives when studying the effect of epigenetic modifications on alternative splicing

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