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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.
Although immune checkpoint inhibitors such as anti-PD-1 antibodies have shown remarkable clinical success in many different tumor types, the proportion of patients benefiting from this treatment option remains low. Therefore, there is a need to sensitize tumors for immune checkpoint blockade. In this study two approaches were tested, a chemoimmunotherapy approach combining PD-1 checkpoint blockade with doxorubicin (DOX) chemotherapy, and ablation of the sphingosine-1-phosphate (S1P) receptor (S1PR4) based on the following rationale. Chemotherapy was shown to induce immune paralysis which contributes to tumor relapse, while PD-1 signaling was shown to facilitate the acquisition of chemoresistance. Thus, combinatorial chemoimmunotherapy is expected to be beneficial by maintaining or even activating anti-tumor immunity during chemotherapy. S1PR4 is an immune cell specific receptor, whose ablation slowed tumor progression by activating anti-tumor immunity in a mouse model that was previously insensitive to anti-PD-1 monotherapy. This suggested that S1PR4 ablation might pre-activate immunity to sensitize for anti-PD-1 therapy.
To test these combinatorial approaches, two tumor mouse models were employed, namely the MC38 murine adenocarcinoma model as well as the transgenic polyoma middle T oncogene (PyMT) breast cancer model. In the MC38 model, a mild synergistic effect of PD-1 immune checkpoint blockade and S1PR4 ablation was observed, indicated by improved tumor progression and survival as compared to the WT control, and an increased number of tumor-free mice compared to anti-PD-1 therapy alone in WT mice. These observations correlated with an enhanced natural killer (NK) cell infiltrate and increased CXCL9 and CXCL10 production in anti-PD-1 treated S1PR4 KO tumors. As noted before, the PyMT model was largely resistant to anti-PD-1 monotherapy in a therapeutic setting. S1PR4 ablation alone showed significant tumor reduction that was not further enhanced by anti-PD-1 treatment. The same was observed when chemotherapy with DOX was added, where WT tumors relapsed, while S1PR4 KO tumor did not. Addition of anti-PD-1 did only mildly increase tumor control in S1PR4 KO mice, indicating that S1PR4 KO per se very efficiently re-activated anti-tumor immunity. Since S1PR4 KO induces type I 12 interferon (IFN-1) over-production in S1PR4 KO PyMT tumors, a link between high IFN-1 levels and tumor immunity was tested by using mice deficient in the IFN-1 receptor (IFNAR1). Unexpectedly, DOX chemotherapy was most efficient in mice with IFNAR ablation only as compared to WT, S1PR4 KO or S1PR4 and IFNAR1 double KO mice, although deficiency in IFNAR signaling is predominantly regarded as tumor promoting. The underlying mechanisms need to be tested in future studies. Interestingly, chemoimmunotherapy in WT mice prevented tumor relapse to a similar extent than S1PR4 KO and was superior to chemotherapy or immune checkpoint blockade alone. To investigate mechanisms of chemoimmunotherapy success compared to monotherapy, whole transcriptome analysis was used, which identified a set of genes that were upregulated specifically upon chemoimmunotherapy. This gene signature and, more specifically, a condensed four-gene signature predicted favorable survival of human mammary carcinoma patients in the METABRIC cohort.
Moreover, PyMT tumors treated with chemoimmunotherapy contained higher levels of cytotoxic lymphocytes, particularly NK cells. Gene set enrichment analysis and ELISA measurements revealed increased IL-27 production and signaling in PyMT tumors upon chemoimmunotherapy. Moreover, IL-27 improved NK cell cytotoxicity against PyMT cells in vitro. These data supported recent clinical observations indicating a benefit of chemoimmunotherapy compared to monotherapy in breast cancer and suggested potential underlying mechanisms.
Taken together the present work revealed new strategies to reactivate tumor immunity leading to improved chemotherapy response, namely a combination with immune checkpoint blockade and ablation of S1PR4, which activated different lymphocyte compartments within tumors.