Cancer immunotherapies utilizing immune checkpoint blockade (ICB) therapy targeting CTLA-4 and PD-1/PD-L1 relieve tumor-induced immune suppression and induce durable tumor regression. The use of... Show moreCancer immunotherapies utilizing immune checkpoint blockade (ICB) therapy targeting CTLA-4 and PD-1/PD-L1 relieve tumor-induced immune suppression and induce durable tumor regression. The use of ICB therapy have demonstrated remarkable therapeutic efficacy in a proportion of patients with melanoma. However, still a substantial percentage of patients does not respond (durable) to ICB treatment and many questions remain. Therefore, in this thesis, the aim is to improve our understanding of ICB efficacy. We demonstrate the promise of neoadjuvant ICB therapy (approach in which ICB therapy is applied before surgery) and analyze different cohorts of melanoma patients. This results in the identification of several markers that are associated with prognosis, including IFN-y related gene signature score, Batf3 dendritic cell associated gene signature score, tumor mutational burden and systemic LRG1 expression. These markers can potentially be targeted and might facilitate rational combination therapies that can boost the efficacy of ICB therapy. For this purpose, we perform a repurposing compound screen that targets antigen cross-presentation. Togethers, this work increases our understanding of factors that determine ICB therapy efficacy and toxicity, with the goal to identify novel strategies to improve outcome of melanoma patients in a rationale and personal manner. Show less
While immune checkpoint blockade (ICB) (CTLA4/ PD1) therapy has resulted in durable responses in patients with advanced stage cutaneous melanoma, some patients do not benefit from this, due to... Show moreWhile immune checkpoint blockade (ICB) (CTLA4/ PD1) therapy has resulted in durable responses in patients with advanced stage cutaneous melanoma, some patients do not benefit from this, due to resistance mechanisms. This thesis aims to improve response of a subset of melanoma patients to immunotherapy. Firstly, mouse melanoma tumor models are developed that closely resemble some of the resistance mechanisms occurring in patient tumors, which are useful for research. Thereafter, a prognostic biomarker is used to identify the subset of melanoma patients that are unlikely to benefit from ICB therapy. It is then evaluated whether this subset of patients would benefit from combining histone deacetylase inhibitor with ICB. Despite encouraging pre-clinical results showing enhanced anti-tumor immune responses using this combination, this did not result in improved responses in the clinic. Furthermore, this thesis focuses on an immune cell subset, namely regulatory T cells (Tregs), which are known to suppress anti-tumor immune responses. Thus, their presence in the tumor microenvironment (TME) is detrimental to tumor cell killing. This thesis provides an increased understanding of the metabolic adaptation of Tregs to conditions in the TME and propose that targeting these adaptations might overcome the suppression by Tregs and enhance responses to immunotherapy. Show less
