Tumor Immunogenicity Unlocked: Multi-omics Models Predict Immunotherapy Response and Survival

DSpace Repositorium (Manakin basiert)

Zur Kurzanzeige

dc.contributor.advisor Ossowski, Stephan (Prof. Dr.)
dc.contributor.author Gschwind, Axel
dc.date.accessioned 2026-07-14T11:04:40Z
dc.date.available 2026-07-14T11:04:40Z
dc.date.issued 2026-07-14
dc.identifier.uri http://hdl.handle.net/10900/181535
dc.identifier.uri http://nbn-resolving.org/urn:nbn:de:bsz:21-dspace-1815353 de_DE
dc.identifier.uri http://dx.doi.org/10.15496/publikation-122857
dc.description.abstract Background: Immune Checkpoint Inhibitor (ICI) outcomes are highly heterogeneous among cancer patients. Some individuals experience remarkable treatment success and durable responses, whereas others do not show any benefit from ICI therapy. Concurrently, patients may experience severe or even potentially life-threatening adverse effects. Although currently available individual biomarkers, such as the gold-standards tumor mutation burden (TMB) or PDL1 expression, correlate with ICI outcomes, their predictive accuracy remains limited. More reliable models that predict ICI treatment outcomes with higher accuracy are urgently needed to identify patients who are likely to benefit from ICI therapy. Integrating distinct biomarkers from multiple omics layers into predictive models is a promising strategy for improving ICI outcome predictions. Methods: Various genomic and transcriptomic biomarkers that are predictive of ICI outcomes and that describe different aspects of tumor biology were derived from next-generation sequencing (NGS) data. These included tumor-intrinsic properties, such as TMB, PDL1 expression, immune cell infiltration, and known mechanisms of ICI response, as well as host factors such as HLA-related metrics. Subsequently, the biomarkers were combined into multiomics models using machine learning (ML) approaches and interpretable scoring methods to predict ICI outcomes with higher accuracy than individual biomarkers. The models were trained on cohorts of melanoma patients with annotated clinical ICI outcomes. Subsequent analyses were performed using additional datasets of various cancer types. Results: This cumulative dissertation resulted in two scientific, peer-reviewed publications. In the first study, we developed Least Absolute Shrinkage and Selection Operator (LASSO) models that integrate biomarkers derived form bulk RNA sequencing (RNA-seq) and whole exome sequencing (WES) to predict ICI outcomes. The predictions of these multiomic models outperformed those of the gold-standard ICI biomarker TMB. SHapley Additive exPlanations (SHAP) values were applied to provide explanations of the predictions. The second study focused on an interpretable multi-omics model, the Multi-Omics Tumor Immunogenicity score (MOTIscore), which extended the outcome prediction to survival analyses and investigated underlying molecular mechanics of the tumors. This MOTIscore accurately predicted ICI outcomes, and discriminated patient groups with survival benefits following ICI treatment. The MOTIscore revealed the predictive role of genes that are part of the C-X-C motif ligand pathway, which plays an important role in immune cell activation. Conclusion: This cumulative work demonstrated that integrating multi-omics data substantially improved the prediction of ICI outcomes compared to individual biomarkers. The multi-omics models developed in this study offer a promising tool for the selection of patients for treatment with ICIs. Using SHAP-based explanations and the interpretable MOTIscore model, we provided explanations for the predictions, which is a crucial prerequisite for a clinical decision-making tool. However, prospective studies are necessary to validate all the findings of our study for potential clinical applications, preferably with a larger patient cohort for which sequencing is performed. en
dc.language.iso en de_DE
dc.publisher Universität Tübingen de_DE
dc.rights cc_by de_DE
dc.rights ubt-podok de_DE
dc.rights.uri https://creativecommons.org/licenses/by/4.0/legalcode.de de_DE
dc.rights.uri https://creativecommons.org/licenses/by/4.0/legalcode.en en
dc.rights.uri http://tobias-lib.uni-tuebingen.de/doku/lic_mit_pod.php?la=de de_DE
dc.rights.uri http://tobias-lib.uni-tuebingen.de/doku/lic_mit_pod.php?la=en en
dc.subject.classification Maschinelles Lernen , Immuntherapie , Krebs <Medizin> , Bioinformatik de_DE
dc.subject.ddc 004 de_DE
dc.subject.ddc 570 de_DE
dc.subject.ddc 610 de_DE
dc.subject.other Immuncheckpointinhibitoren de_DE
dc.subject.other Künstliche Intelligenz de_DE
dc.subject.other Anti-PD1 de_DE
dc.subject.other Anti-PD1 en
dc.subject.other Artificial Intelligence en
dc.subject.other Genomics en
dc.subject.other Immune Checkpoint Inhibitors en
dc.subject.other Genomik de_DE
dc.subject.other Transkriptomik de_DE
dc.subject.other Transcriptomics en
dc.subject.other Multiomik de_DE
dc.subject.other Multiomics en
dc.subject.other Cancer en
dc.subject.other Bioinformatics en
dc.subject.other Machine Learning en
dc.title Tumor Immunogenicity Unlocked: Multi-omics Models Predict Immunotherapy Response and Survival en
dc.type PhDThesis de_DE
dcterms.dateAccepted 2026-06-24
utue.publikation.fachbereich Informatik de_DE
utue.publikation.fakultaet 7 Mathematisch-Naturwissenschaftliche Fakultät de_DE
utue.publikation.noppn yes de_DE

Dateien:

Das Dokument erscheint in:

Zur Kurzanzeige

cc_by Solange nicht anders angezeigt, wird die Lizenz wie folgt beschrieben: cc_by