Multiple instance learning to predict immune checkpoint blockade efficacy using neoantigen candidates

Lang, Franziska; Sorn, Patrick; Schrörs, Barbara; Weber, D. F.; Krämer, Stefan; Şahin, Uğur; Löwer, Martin

doi:10.1101/2022.05.06.490587

Cited by 1 publication

(2 citation statements)

References 61 publications

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“…(strong: MHC-I binding rank < 0.5, MHC-II binding rank < 2, weak: 0.5 ≤ MHC-I binding rank < 2, 2 ≤ MHC-II binding rank < 10, no: MHC-I binding rank ≥ 2, MHC-II binding rank ≥ 10) (F-G) (F) MHC-I and (G) MHC-II binding rank of the best predicted neoepitope per neoantigen candidate for those from alternative splicing (AS) and SNVs. SNV-derived neoantigen candidates were retrieved as described in [69] (H) Self-similarity [41] of the best predicted neoepitope per neoantigen candidate for those from alternative splicing and those from SNVs.…”

Section: Resultsmentioning

confidence: 99%

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Prediction of tumor-specific splicing from somatic mutations as a source of neoantigen candidates

Lang,

Sorn,

Suchan

et al. 2023

Preprint

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Splicing is dysregulated in many tumors and may result in tumor-specific transcripts that can encode neoantigens, which are promising targets for cancer immunotherapy. Detecting tumor-specific splicing is challenging because many non-canonical splice junctions identified in tumor transcriptomes also appear in healthy tissues. However, somatic mutations can disrupt canonical splicing motifs or create novel ones leading to true tumor-specific targets. Here, we developed splice2neo to integrate the predicted splice effects from somatic mutations with splice junctions detected in tumor RNA-seq for individual cancer patients. Using splice2neo, we excluded canonical splice junctions and splice junctions from healthy tissue samples, annotated resulting transcript and peptide sequences, and integrated targeted re-quantification of supporting RNA-seq reads. By analyzing melanoma patient cohorts, we established a stringent detection rule to predict splice junctions as mutation-derived and tumor-specific targets. In an independent melanoma cohort, we identified 1.7 target splice junctions per tumor with an estimated false discovery rate of less than 5% and established tumor-specificity using additional healthy tissue samples. For individual examples of exon skipping events, we confirmed the expression in tumor-derived RNA by quantitative real-time PCR experiments. Most target splice junctions encoded at least one neoepitope candidate with predicted MHC-I or MHC-II binding. Compared to neoepitope candidates derived from non-synonymous point mutations, the splicing-derived neoepitope candidates had a lower self-similarity to corresponding wild-type peptides. In conclusion, identifying mutation-derived and tumor-specific splice junctions can lead to additional neoantigen candidates to expand the target repertoire for cancer immunotherapies.

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Section: Resultsmentioning

confidence: 99%

“…neoantigen candidate for those from alternative splicing (AS) and SNVs. SNV-derived neoantigen candidates were retrieved as described in [67] (H) Self-similarity [41] of the best predicted neoepitope per neoantigen candidate for those from alternative splicing and those from SNVs.…”

Section: Read Support Visualization With Sashimi Plotsmentioning

confidence: 99%

Prediction of tumor-specific splicing from somatic mutations as a source of neoantigen candidates

Lang,

Sorn,

Suchan

et al. 2023

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

Multiple instance learning to predict immune checkpoint blockade efficacy using neoantigen candidates

Cited by 1 publication

References 61 publications

Prediction of tumor-specific splicing from somatic mutations as a source of neoantigen candidates

Prediction of tumor-specific splicing from somatic mutations as a source of neoantigen candidates

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