Genome-Wide Functional Annotation of Human Protein-Coding Splice Variants Using Multiple Instance Learning

Panwar, Bharat; Menon, Rajasree; Eksi, Ridvan; Li, Hong Dong; Omenn, Gilbert S.; Guan, Yuanfang

doi:10.1021/acs.jproteome.5b00883

Cited by 33 publications

(41 citation statements)

References 47 publications

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“…It is feasible to predict functional differences between and among splice variants from the same gene using I-TASSER and other protein folding and ligand-binding algorithms. 31 It is also feasible to predict isoform-level functional networks for the different splice isoforms of a given gene such as Her2/neu (ERBB2) using Hisonet 32,33 and IsoFunc 34 from http://guanlab.ccmb.med.umich.edu/.…”

Section: Discussionmentioning

confidence: 99%

Metrics for the Human Proteome Project 2016: Progress on Identifying and Characterizing the Human Proteome, Including Post-Translational Modifications

et al. 2016

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The HUPO Human Proteome Project (HPP) has two overall goals: (1) stepwise completion of the protein parts list—the draft human proteome including confidently identifying and characterizing at least one protein product from each protein-coding gene, with increasing emphasis on sequence variants, post-translational modifications (PTMs), and splice isoforms of those proteins; and (2) making proteomics an integrated counterpart to genomics throughout the biomedical and life sciences community. PeptideAtlas and GPMDB reanalyze all major human mass spectrometry data sets available through ProteomeXchange with standardized protocols and stringent quality filters; neXtProt curates and integrates mass spectrometry and other findings to present the most up to date authorative compendium of the human proteome. The HPP Guidelines for Mass Spectrometry Data Interpretation version 2.1 were applied to manuscripts submitted for this 2016 C-HPP-led special issue [www.thehpp.org/guidelines]. The Human Proteome presented as neXtProt version 2016-02 has 16,518 confident protein identifications (Protein Existence [PE] Level 1), up from 13,664 at 2012-12, 15,646 at 2013-09, and 16,491 at 2014-10. There are 485 proteins that would have been PE1 under the Guidelines v1.0 from 2012 but now have insufficient evidence due to the agreed-upon more stringent Guidelines v2.0 to reduce false positives. neXtProt and PeptideAtlas now both require two non-nested, uniquely mapping (proteotypic) peptides of at least 9 aa in length. There are 2,949 missing proteins (PE2+3+4) as the baseline for submissions for this fourth annual C-HPP special issue of Journal of Proteome Research. PeptideAtlas has 14,629 canonical (plus 1187 uncertain and 1755 redundant) entries. GPMDB has 16,190 EC4 entries, and the Human Protein Atlas has 10,475 entries with supportive evidence. neXtProt, PeptideAtlas, and GPMDB are rich resources of information about post-translational modifications (PTMs), single amino acid variants (SAAVSs), and splice isoforms. Meanwhile, the Biology- and Disease-driven (B/D)-HPP has created comprehensive SRM resources, generated popular protein lists to guide targeted proteomics assays for specific diseases, and launched an Early Career Researchers initiative.

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Section: Discussionmentioning

confidence: 99%

Metrics for the Human Proteome Project 2016: Progress on Identifying and Characterizing the Human Proteome, Including Post-Translational Modifications

et al. 2016

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“…Panwar et al predicted functions for splice isoforms in humans [57]. The approach mainly consists of the following steps:

Download the human RNA-Seq data from the ENCODE study [58]; 127 samples were used.

…”

Section: Methodsmentioning

confidence: 99%

“…For example, the predictions of human isoform functions [57] and networks [60] are based on RefSeq (version 37.2) and Ensembl (version 74) gene annotations, respectively, so preliminary interpretation of comparative results should be viewed with caution. RefSeq annotation is of high quality but is much less complete compared to Ensembl, which contains many more (predicted) genes and isoforms.…”

Section: Notesmentioning

confidence: 99%

Annotation of Alternatively Spliced Proteins and Transcripts with Protein-Folding Algorithms and Isoform-Level Functional Networks

Zhang

Guan

et al. 2017

Protein Bioinformatics

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Tens of thousands of splice isoforms of proteins have been catalogued as predicted sequences from transcripts in humans and other species. Relatively few have been characterized biochemically or structurally. With the extensive development of protein bioinformatics, the characterization and modeling of isoform features, isoform functions, and isoform-level networks have advanced notably. Here we present applications of the I-TASSER family of algorithms for folding and functional predictions and the IsoFunc, MIsoMine, and Hisonet data resources for isoform-level analyses of network and pathway-based functional predictions and protein-protein interactions. Hopefully, predictions and insights from protein bioinformatics will stimulate many experimental validation studies.

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“…They demonstrate that the simultaneous integration of collision-induced dissociation (CID) and high-energy collisional dissociation (HCD) fragmentation facilitates rapid identification of both glycans and N-glycopeptide backbones in tandem MS data, resulting in the identification of missing proteins having glycans (e.g., Q8N9B8) present in liver cancer (http://gFinder.proteomix.org/). Panwar et al 30 from the Chr 17 team presented a proteome-wide analysis of predicted splice isoform-level functional networks. The accumulation of a large amount of RNA-seq data in the public domain greatly increases our ability to examine the functional annotation of genes at isoform level.…”

Section: Bioinformatics Studiesmentioning

confidence: 99%

Progress in the Chromosome-Centric Human Proteome Project as Highlighted in the Annual Special Issue IV

et al. 2016

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Genome-Wide Functional Annotation of Human Protein-Coding Splice Variants Using Multiple Instance Learning

Cited by 33 publications

References 47 publications

Metrics for the Human Proteome Project 2016: Progress on Identifying and Characterizing the Human Proteome, Including Post-Translational Modifications

Metrics for the Human Proteome Project 2016: Progress on Identifying and Characterizing the Human Proteome, Including Post-Translational Modifications

Annotation of Alternatively Spliced Proteins and Transcripts with Protein-Folding Algorithms and Isoform-Level Functional Networks

Progress in the Chromosome-Centric Human Proteome Project as Highlighted in the Annual Special Issue IV

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