Definition of the transcriptional units of inherited retinal disease genes by meta-analysis of human retinal transcriptome data

Ruiz-Ceja, Karla Alejandra; Capasso, Dalila; Pinelli, Michele; Prete, Eugenio Del; Carrella, Diego; Bernardo, Diego di; Banfi, Sandro

doi:10.1186/s12864-023-09300-w

“…Several retinal transcriptome studies have been published (Farkas et al, 2013;Pinelli et al, 2016;Ratnapriya et al, 2019;Ruiz-Ceja et al, 2023;Schumacker et al, 2020). However, the existing literature provides limited evidence on the transcript isoforms expressed in the retina for two main reasons.…”

Section: Introductionmentioning

confidence: 99%

A proteogenomic atlas of the human neural retina

Riepe,

Stemerdink,

Salz

et al. 2024

Preprint

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The human neural retina is a complex tissue with abundant alternative splicing and more than 10% of genetic variants linked to inherited retinal diseases (IRDs) alter splicing. Traditional short-read RNA-sequencing methods have been used for understanding retina-specific splicing but have limitations in detailing transcript isoforms. To address this, we generated a proteogenomic atlas that combines PacBio long-read RNA-sequencing data with mass spectrometry and whole genome sequencing data of three healthy human neural retina samples. We identified nearly 60,000 transcript isoforms, of which approximately one-third are novel. Additionally, ten novel peptides confirmed novel transcript isoforms. For instance, we identified a novel IMPDH1 isoform with a novel combination of known exons that is supported by peptide evidence. Our research underscores the potential of in-depth tissue-specific transcriptomic analysis to enhance our grasp of tissue-specific alternative splicing. The data underlying the proteogenomic atlas are available via EGA with identifier EGAD50000000101, via ProteomeXchange with identifier PXD045187, and accessible through the UCSC genome browser.

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Pushing the limits of single molecule transcript sequencing to uncover the largest disease-associated transcript isoforms in the human neural retina

Stemerdink,

Riepe,

Zomer

et al. 2024

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Sequencing technologies have long limited the comprehensive investigation of large transcripts associated with inherited retinal diseases (IRDs) like Usher syndrome, which involves 11 associated genes with transcripts up to 19.6 kb. To address this, we used PacBio long-read mRNA isoform sequencing (Iso-Seq) following standard library preparation and an optimized workflow to enrich for long transcripts in the human neural retina. While our workflow achieved sequencing of transcripts up to 15 kb, this was insufficient for Usher syndrome-associated genesUSH2AandADGRV1, with transcripts of 18.9 kb and 19.6 kb, respectively. To overcome this, we employed the Samplix Xdrop System for indirect target enrichment of cDNA, a technique typically used for genomic DNA capture. This method facilitated the successful capture and sequencing ofADGRV1transcripts as well as the full-length 18.9 kbUSH2Atranscripts. By combining algorithmic analysis with detailed manual curation of sequenced reads, we identified novel isoforms and alternative splicing events across the 11 Usher syndrome-associated genes, with implications for diagnostics and therapy development. Our findings demonstrate the Xdrop system’s adaptability for cDNA capture and the advantages of integrating computational and manual transcript analyses. The full neural retina sequencing dataset is available via EGA under identifier EGAD50000000720.

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A proteogenomic atlas of the human neural retina

Riepe,

Stemerdink,

Salz

et al. 2024

Front. Genet.

0

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The human neural retina is a complex tissue with abundant alternative splicing and more than 10% of genetic variants linked to inherited retinal diseases (IRDs) alter splicing. Traditional short-read RNA-sequencing methods have been used for understanding retina-specific splicing but have limitations in detailing transcript isoforms. To address this, we generated a proteogenomic atlas that combines PacBio long-read RNA-sequencing data with mass spectrometry and whole genome sequencing data of three healthy human neural retina samples. We identified nearly 60,000 transcript isoforms, of which approximately one-third are novel. Additionally, ten novel peptides confirmed novel transcript isoforms. For instance, we identified a novel IMPDH1 isoform with a novel combination of known exons that is supported by peptide evidence. Our research underscores the potential of in-depth tissue-specific transcriptomic analysis to enhance our grasp of tissue-specific alternative splicing. The data underlying the proteogenomic atlas are available via EGA with identifier EGAD50000000101, via ProteomeXchange with identifier PXD045187, and accessible through the UCSC genome browser.

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Definition of the transcriptional units of inherited retinal disease genes by meta-analysis of human retinal transcriptome data

Cited by 3 publications

References 60 publications

A proteogenomic atlas of the human neural retina

A proteogenomic atlas of the human neural retina

Pushing the limits of single molecule transcript sequencing to uncover the largest disease-associated transcript isoforms in the human neural retina

A proteogenomic atlas of the human neural retina

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