Deep Profiling and Custom Databases Improve Detection of Proteoforms Generated by Alternative Splicing

Overview

Journal Genome Res

Specialty Genetics

Date 2019 Nov 16

PMID 31727681

Citations 14

Authors

Laura M Agosto

Matthew R Gazzara

Caleb M Radens

Simone Sidoli

Josue Baeza

Benjamin A Garcia

Kristen W Lynch

Affiliations

Soon will be listed here.

Abstract

Alternative pre-mRNA splicing has long been proposed to contribute greatly to proteome complexity. However, the extent to which mature mRNA isoforms are successfully translated into protein remains controversial. Here, we used high-throughput RNA sequencing and mass spectrometry (MS)-based proteomics to better evaluate the translation of alternatively spliced mRNAs. To increase proteome coverage and improve protein quantitation, we optimized cell fractionation and sample processing steps at both the protein and peptide level. Furthermore, we generated a custom peptide database trained on analysis of RNA-seq data with MAJIQ, an algorithm optimized to detect and quantify differential and unannotated splice junction usage. We matched tandem mass spectra acquired by data-dependent acquisition (DDA) against our custom RNA-seq based database, as well as SWISS-PROT and RefSeq databases to improve identification of splicing-derived proteoforms by 28% compared with use of the SWISS-PROT database alone. Altogether, we identified peptide evidence for 554 alternate proteoforms corresponding to 274 genes. Our increased depth and detection of proteins also allowed us to track changes in the transcriptome and proteome induced by T-cell stimulation, as well as fluctuations in protein subcellular localization. In sum, our data here confirm that use of generic databases in proteomic studies underestimates the number of spliced mRNA isoforms that are translated into protein and provides a workflow that improves isoform detection in large-scale proteomic experiments.

Citing Articles

Toward a comprehensive profiling of alternative splicing proteoform structures, interactions and functions.

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APOER2 splicing repertoire in Alzheimer's disease: Insights from long-read RNA sequencing.

Gallo C, Kistler S, Natrakul A, Labadorf A, Beffert U, Ho A PLoS Genet. 2024; 20(7):e1011348.

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Systematic analysis of the effects of splicing on the diversity of post-translational modifications in protein isoforms using PTM-POSE.

Crowl S, Coleman M, Chaphiv A, Jordan B, Naegle K bioRxiv. 2024; .

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