Open Access

Inducing cell death in tumor cells is a major goal of anti-cancer therapy. However, the preferable mode of cell death to induce is under debate. Apoptosis is known to be an anti-inflammatory and pro-resolving type of programmed cell death, whereas necroptosis results in the release of danger-associated molecular patterns (DAMPs) and is pro-inflammatory. Efferocytosis of apoptotic cells by macrophages results in a pro-resolving switch of macrophages polarization and is required to induce resolution of inflammation. This impact of apoptotic cells on macrophages is a non-desired consequence of cell death in tumors, which are often characterized by an overshooting wound healing response. Moreover, apoptosis resistance is frequently observed in cancer cells. To overcome apoptosis resistance in cancer cells, necroptosis can be induced as an alternative mechanism for cancer treatment. Interferons (IFNs) play an important role in tumor immune responses and act by inducing the expression of IFN-stiumlated genes (ISGs). Furthermore, IFNs were shown to be able to induce necroptosis together with Smac-mimetics when caspases are inhibited in different cancer cell lines. Necroptosis is induced by phosphorylation and activation of receptor-interacting serine/threonine-protein kinase 1 (RIPK1), RIPK3 and pseudokinase mixed lineage kinase domain-like (MLKL). In my thesis, we first identified MLKL as an ISG in various cancer cell lines. MLKL upregulation was found to be a general feature of IFN signaling since both type I and type II IFNs increase the expression of MLKL. IFNy was able to upregulate MLKL at messenger ribonucleic acid (mRNA) and protein level indicating that MLKL is elevated transcriptionally. Indeed, Actinomycin D chase experiments showed that inhibition of transcription abolished MLKL upregulation upon IFN treatment. Both, knockdown of the IFNy-activated transcription factors interferon regulatory factor 1 (IRF1) and signal transducer and activator of transcription 1 (STAT1) as well as knockout of IRF1 significantly dampened MLKL mRNA upregulation, demonstrating that STAT1 and especially IRF1 are necessary to induce MLKL expression. This first part of the study highlights the upregulation of MLKL by IFNy as valuable tool to sensitize cells towards necroptosis and by that overcome apoptosis resistance in cancers. When compared to apoptosis, the immune response to necroptotic cells and the polarization of macrophages phagocytosing necroptotic cells is not well studied. In most studies, cell death was induced by biological or chemical compounds, which may lead to artifacts by affecting the macrophages and triggering of unrelated signaling pathways. Therefore, in the second part of my thesis we used a pure cell death system of NIH 3T3 cells expressing either dimerizable caspase 8 or oligomerizable RIPK3 to induce cell death. Addition of B/B-Homodimerizer (dimerizer) to the cells resulted in apoptosis or necroptosis, which was confirmed by caspase 3/7 activation, phosphorylation of MLKL and inhibitor experiments, respectively. We analyzed the effect of dying cells on peritoneal macrophages by establishing a co-culture in a transwell system. The genetic profile of macrophages co-cultured with dying cells was evaluated by whole transcriptome RNA sequencing. In macrophages co-cultured with necroptotic cells genes corresponding to chemotaxis and hypoxia pathways were upregulated. A significant proportion of hypoxia-related pathways are mediated by hypoxia-inducible factor 1-alpha (HIF-1α), which also induces metabolic changes in polarized macrophages. We could show that macrophages co-cultured with necroptotic cells showed a decreased mitochondrial respiration, indicating an inflammatory (M1) polarization. Protein levels of chemokine C-X-C motif ligand 1 (CXCL1), which was increased in the RNA sequencing data, were also upregulated in supernatant of co-cultured macrophages and of necroptotic cells, demonstrating that necroptotic cells both secrete CXCL1 and induce gene expression of CXCL1 in peritoneal macrophages. This may influence the recruitment of neutrophils as inhibition of necroptosis during Zymosan-A-induced peritonits in mice decreased the levels of neutrophils at day 1 of this model of self-resolving inflammation. Furthermore, RNA sequencing revealed an unexpected impact of apoptotic cells on macrophage biology as cell cycle and cell division pathways were increased. Enhanced proliferation of macrophages was confirmed by two functional assay with peritoneal macrophages isolated from mice and IC-21 macrophages. Inhibition of apoptosis during Zymosan-A-induced peritonits in mice demonstrated decreased mRNA levels of cell cycle mediators in peritoneal macrophages. Simultaneously with cell cycle activation, gene sets of prostaglandin E2 (PGE2) signaling were upregulated during RNA sequencing. In the second part of my thesis we could demonstrate, that apoptotic cells induce transcription of cell cycle genes and proliferation of macrophages and necroptotic cells are able to influence the chemokine profile of macrophages and thereby the recruitment of neutrophils.

The interleukin (IL)-1 family has been described for its numerous involvement in the regulation of inflammatory processes. Certain members are able to induce inflammation, whereas others have the capacity to inhibit inflammation. The newly discovered IL-1 family member IL-38 shows interesting and innovative properties. While most of these cytokines are pro-inflammatory mediators, IL-38 appears to enter the smaller circle of anti-inflammatory mediators. As a pattern, IL-38 appears to suppress IL-17-driven chronic or auto-inflammation by working as receptor antagonist. These properties, as well as its beneficial effects in models of inflammatory and autoimmune diseases suggest the possibility of IL-38-based therapies. Nevertheless, its role in the resolution of acute inflammation, thereby preventing chronic inflammation, remains unclear. The first part of my thesis elucidated the role of IL-38 in the resolution of inflammation. I found that the complete absence of IL-38 in IL-38 KO mice leads to a delayed resolution of inflammation in the zymosan-induced peritonitis mouse model, compared to WT mice. This was marked by a persistent neutrophilia and a lower production of pro-resolving mediators during the resolution phase, such as TGFβ1 production from macrophages following efferocytosis of apoptotic cells. Reduced TGFβ1 production from macrophages coincided with reduced levels of regulatory T cells (Tregs), which are known to promote the resolution of inflammation. Unexpectedly, the TGFβ1 production capacity of macrophages did not influence the induction of Tregs from naïve T cells. Rather, IL-38 KO mice had an accumulation of Tregs in the thymus compared to WT mice. This was caused by an impairment of CD62L expression at the surface of Tregs, which is required for Tregs migration outside of the thymus. Higher Treg numbers in the thymus correlated with lower level of Tregs in peripheral lymphoid organs. Importantly, CD62L expression at the surface of IL-38 KO Tregs in the thymus was restored by injecting IL-38 i.p. for 24h. These data indicate a potential key function of IL-38 in the regulation of Treg migration, which is triggered in many cases of autoimmunity. The second part of my thesis was to study the role of IL-38 in experimental autoimmune encephalomyelitis (EAE) development, given that EAE is IL-17-dependent. Unexpectedly, IL-38-deficient mice showed strongly reduced clinical scores and histological markers of EAE. This came with reduced inflammatory cell infiltrates, as well as reduced expression of inflammatory markers in the spinal cord. IL-38 mRNA was detected in the spinal cord, mainly by resident and infiltrated phagocytes, but also by other cells, such as ependymal cells. IL-38 was upregulated upon pro-inflammatory stimulation of bone marrow-derived macrophages, and its presence was necessary for a complete activation of inflammatory macrophages. My data suggest an alternative cell-intrinsic role of IL-38 in macrophages to promote inflammation in the central nervous system. In the last part of my thesis, I initiated a project on the function of IL-38 in B cell physiology and antibody production, given the fact that IL-38 is expressed by B cells. I generated preliminary data showing that the absence of IL-38 in mice decreased antibody production. Furthermore, I showed that IL-38 is particularly expressed by plasma cells in human tonsils. This project remains open and further studies will be conducted to investigate how IL-38 regulates antibody production, both in physiological and autoimmune settings. Understanding the role of IL-38 in autoantibody production could lead to original and innovative therapy for patients suffering from auto-inflammatory disease. In summary, the different projects of my thesis provide evidence that the pro-resolving function of IL-38 may be indirectly linked to the retention of Tregs in the thymus. Moreover, a possible intracellular role of IL-38 within macrophages was described showing opposite properties in the regulation of inflammation. This function could be causatively involved in EAE development. However, further studies remain to be done to find the mechanism of action by which IL-38 regulates Tregs egression and how it influences the EAE development. Complete understanding of the IL-38 biology and differentiation between its extra- vs potential intracellular functions could make it a promising therapeutic target for chronic inflammatory or autoimmune diseases.

Cancer microenvironment is now recognized as a critical regulator of all stages of cancer development. Beside the tumor vasculature and tumor-infiltrating immune cells, other stromal cells such as cancer-associated fibroblasts (CAFs) regulate tumor growth. Fibroblasts are ubiquitous cells in connective tissue, where they shape the extracellular matrix (ECM). Fibroblasts are usually quiescent but get activated when tissue homeostasis is disturbed. Then, activated fibroblasts rebuild the ECM and communicate with local cells to participate in wound repair. These repair properties can go awry when being unchecked, which can lead to fibrosis and subsequently cancer development. CAFs can promote cancer development by fostering tumor cell growth, polarizing immune cells to an immunosuppressive phenotype, and crosslinking collagen to enable tumor cell invasion. Molecular mechanisms of CAF activation, thus, need to be understood to target these cells in tumors. Prostanoid prostaglandin E2 (PGE2) is viewed as a pro-tumor lipid mediator as suggested by studies pharmacologically or genetically targeting the enzymes producing PGE2, such as microsomal PGE synthase-1 (mPGES-1) in tumor models. Similar to CAFs, PGE2 drives tumor cell growth and tumor-associated immune suppression. Therefore, I hypothesized that PGE2 may play a role in CAF activation. This hypothesis was tested in two mouse models of breast cancer (orthotopic grafting model, and polyoma middle T oncogene transgenic model), besides using isolated mammary gland (MG) fibroblasts in vitro. As expected, given the pro-tumor function of PGE2, knocking out mPGES-1 reduced the growth of oncogene-driven and transplanted mammary tumors. Surprisingly, CAF density was markedly increased when mPGES-1 was depleted. Importantly, despite reduced primary tumor growth, I observed enhanced lung metastasis upon mPGES-1depletion. Using MG-derived fibroblasts in vitro furthermore revealed that treatment with PGE2 reduced a TGFβtriggered CAF-like activation state. Importantly, bioinformatics analysis of a human breast cancer patient dataset revealed a negative correlation of a PGE2 production signature with fibroblast marker genes. In a next step I investigated if the increased CAF infiltrate was connected to the reduced tumor growth upon depletion of PGE2. To unravel this, I first asked through which E prostanoid (EP) receptor PGE2 signals in fibroblasts. MG fibroblasts mainly expressed EP3, and EP3 KO fibroblasts showed a hyper-proliferative and activated phenotype, indicating EP3 as the main PGE2 receptor in MG fibroblasts. Co-injecting of EP3 KO MG fibroblasts and tumor cells in WT mice suppressed tumor growth, whereas co-injection of WT fibroblasts with tumor cell in mPGES-1 KO mice increased tumor growth. These data indicate that PGE2 restricts CAF levels through EP3, which supports tumor growth. Whole transcriptome mRNAsequencing of WT and mPGES-1 KO FACS-sorted CAFs combined with immunohistochemical data suggested a role of p38 mitogen-activated protein kinase (MAPK) in the modulation of fibroblast activation by PGE2. In summary, I showed in two breast cancer models that mPGES-1 depletion delays breast cancer progression, which is probably driven by the EP3-PGE2 signaling axis in host stroma. PGE2 appears to be a potent anti-fibroblast activation agent in tumors via EP3 and downstream p38 MAPK signaling. This study therefore hits the dogmatic perception of the general pro-tumor nature of PGE2; showing that PGE2 might be a double-edged mediator that can promote tumor growth at the primary site by restricting CAF expansion, which may in turn hinder infiltration of tumor cells to a secondary site.