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Tumor-associated macrophages (TAM) are a major supportive component within neoplasms and by their plasticity promote all phases of tumor development. Mechanisms of macrophage (M Phi) attraction and differentiation to a tumor-promoting phenotype, defined among others by distinct cytokine patterns such as pronounced immunosuppressive interleukin 10 (IL-10) production, are largely unknown. However, a high apoptosis index within tumors and strong M Phi infiltration correlate with poor prognosis. Thus, I aimed at identifying signaling pathways contributing to generation of TAM-like M Phi by using supernatant of apoptotic cancer cells (ACM) as stimulus.
To distinguish novel factors involved in generating TAM-like M Phi, I used an adenoviral RNAi-based approach. The primary read-out was production of IL-10. However, mediators modulating IL-10 were re-validated for their impact on regulation of the cytokines IL-6, IL-8 and IL-12. Following assay development, optimization and down-scaling to a 384-well format, primary human M Phi were transduced with 8495 constructs of the adenoviral shRNA SilenceSelect® library of Galapagos BV, followed by activation to a TAM-like phenotype using ACM. I identified 96 genes involved in IL-10 production in response to ACM and observed a pronounced cluster of 22 targets regulating IL-10 and IL-6. Principal validation of five targets of the IL-10/IL-6 cluster was performed using siRNA or pharmacological inhibitors. Among those, IL-4 receptor-alpha and cannabinoid receptor 2 were confirmed as regulators of IL-10 and IL-6 secretion.
One protein identified in the screen, the nerve growth factor (NGF) receptor TRKA was chosen for in-depth validation, based on its involvement in IL-10, IL-6 and IL-12 secretion from ACM-stimulated human M Phi. TRKA possesses a cardinal role in neuronal development, but compelling evidence emerges suggesting participation of TRKA in cancer development. First experiments using pharmacological inhibitors principally confirmed the involvement of TRKA in IL-10 secretion by ACM-stimulated M Phi and revealed PI3K/AKT and to a lesser extend MAPK p38 as important signaling molecules downstream of TRKA activation. Signaling through TRKA required the presence of its ligand NGF, as indicated by NGF neutralization experiments. NGF was not induced by or present in ACM, but was constitutively secreted by M Phi. Interestingly, M Phi responded to authentic NGF with neither AKT and p38 phosphorylation nor IL-10 production. TRKA is well known to be transactivated by other receptors and in neurons its cellular localization is decisive for its function. Inhibitors of common transactivation partners did not influence IL-10 production by human M Phi. Rather, ACM-treatment provoked pronounced translocation of TRKA to the plasma membrane within 10 minutes as observed by immunofluorescence staining. Consequently, I was intrigued to clarify mechanisms of TRKA trafficking in response to ACM.
The bioactive lipid sphingosine-1-phosphate (S1P) has been previously identified as important apoptotic cell-derived mediator involved in TAM-like M Phi polarization. Indeed, I observed S1P and src kinase involvement in ACM-mediated IL-10 induction. Furthermore, inhibition of S1P receptor (S1PR) signaling or src kinase activity prevented TRKA translocation, whereas a TRKA inhibitor or anti-NGF did not block TRKA trafficking to the plasma membrane in response to ACM. Thus, autocrine secreted NGF activated TRKA to promote IL-10 secretion, which required previous S1PR/src-dependent translocation of TRKA to the plasma membrane. Following the detailed analysis of IL-10 regulation, I was interested whether other TAM phenotype markers were influenced by ACM and whether their expression was regulated through TRKA-dependent signaling. Five of six markers were up-regulated on mRNA level by ACM, and secretion of IL-6, IL-8 and TNF-alpha was triggered. S1PR-signaling was essential for induction of all but one marker, whereas TRKA signaling was only required for cytokine secretion. Interestingly, none of the investigated TAM markers was regulated identically to IL-10, emphasizing a tight and exclusive regulation machinery of this potent immunosuppressive cytokine.
Finally, I aimed to validate the in vitro findings in human ACM-stimulated M Phi. Therefore, I isolated murine TAM as well as other major mononuclear phagocyte populations from primary oncogene-induced breast cancer tissue. Indeed, TRKA-dependent signaling was required for spontaneous cytokine production selectively by primary murine TAM. Besides IL-10, the TRKA pathway was decisive for secretion of IL-6, TNF-alpha and monocyte chemotactic protein-1, indicating its relevance in cancer-associated inflammation.
In summary, my findings highlight a fine-tuned regulatory system of S1P-dependent TRKA trafficking and autocrine NGF signaling in TAM biology. Both factors, S1P as well as NGF, might be interesting targets for future cancer therapy.
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.
To determine the effects of inhaled IL-10 at different doses and different time points on the pulmonary and systemic inflammatory response during endotoxemia, 48 ventilated, anaesthetized rats (mean body weight ± standard deviation, 500 ± 33g) were randomly assigned to six groups (n = 8, each). Interleukin-10 was nebulised either prior to or following the intravenous injection of LPS (5mg/kg) at two doses (5.0 mycro-g or 0.5 mycro-g) in our groups. Eight rats received the same insult with no further treatment (LPS-only group). Another eight rats served as controls without endotoxemia but with aerosolized phosphate-buffered saline, the solvent of IL-10 (Sham group). Concentrations of TNF-alpha, IL-1beta, IL-6, and IFN-gamma were analyzed in plasma and bronchoalveolar lavage fluid (BALF). In addition, the nitrite release from ex-vivo cultured alveolar macrophages was determined. As compared to the LPS-only group, the concentrations of the proinflammatory cytokines TNF-alpha, IL-1beta, IL-6, and IFN-gamma in plasma were significantly reduced in the group, which inhaled 5 mycro-g IL-10 before LPS injection (p< 0.0125). Spontaneous nitrite release from exvivo cultured alveolar macrophages was suppressed in this group (p< 0.0125). Inhalation of 0.5 mycro-g IL-10 before LPS injection and both dosages of IL-10 inhalation (5 mycro-g or 0.5 mycro-g) after LPS injection did not significantly influence either inflammatory cytokine concentrations in BALF, in plasma or the nitrite release from ex-vivo cultured alveolar macrophages. In this study, inhaled IL-10 only demonstrated anti-inflammatory effects when it was administered at 5 mycro-g prior to the induction of experimental endotoxemia. Interleukin-10 aerosol had no effect when it was given either following induction of endotoxemia or given at a lower dosage (which here was 0.5 mycro-g) either before or following injection of lipopolysaccharide.
IL-38 is the latest discovered cytokine of the IL-1 family and has been added to the IL-36 subfamily. Since its discovery in 2001, increasing evidence suggests predominantly anti-inflammatory properties of IL-38, which are most likely exerted through three potential receptors, the IL-1 Receptor 1 (IL-1R1), IL-36 Receptor (IL-36R) and the IL-1 Receptor Accessory Protein Like 1 (IL-1RAPL1). However, to this date detailed knowledge of IL-38 functioning remains to be examined. Importantly, how IL-38 is processed, secreted from cells and the exact mechanisms of target receptor binding and intracellular signaling are not fully understood. Further, IL-38 has been associated with regulatory functions in autoimmune diseases like systemic lupus erythematosus (SLE) and psoriasis. At the same time however, connections between B cells as indispensable part of immunity and IL-38 remain rare.
In this study we examined the influence of IL-38 in peripheral human blood B cells differentiating into antibody secreting cells using a three-step in vitro differentiation process. We first show that all potential IL-38 binding receptors are present on peripheral blood B cells on a gene expression level and remain detectable throughout B cell differentiation. Next, while B cells treated with exogenous IL-38 depict no differences in early B cell activation markers, the process of B cell differentiation revealed significant alterations in B cell phenotype created by IL-38 treatment. Predominantly on day 7 of the differentiation process, IL-38 treated B cells showed significantly reduced CD38 expression which depicts an important step in development towards plasma cells. We hypothesize that IL-38 acts antagonistically on the IL-1R1 pathway reducing Nuclear factor kappa B (NFκB) expression and consequently decreasing CD38 expression. Further IL-38 reduced early antibody production while increasing IgM secretion at the end stages of differentiation. Next, we repeated the differentiation assays under the influence of additional IL-21 stimulation to further enhance plasma cell development. In these experiments, the impact of IL-38 on B cell differentiation and immunoglobulin production were reduced, indicating a comparatively moderate relevance of IL-38 for B cell differentiation. We then examined how proliferation and cell death were impacted by exogenous IL-38 during B cell differentiation. IL-38 treatment alone significantly reduced B cell survival which was further augmented by IL-21 stimulation. We conclude that IL-38 and IL-21 act synergistically in promoting B cell apoptosis, also depicting an anti-inflammatory property of IL-38. Finally, using a siRNA we successfully performed an IL-38 knockdown experiment of human blood B cells reducing IL-38 expression to 44% measured on day 4 of B cell differentiation. In these experiments we observed reversed tendencies of CD38 expression compared to exogenous IL-38 treatment. Here, IL-38 knockdown cells showed increased CD38 expression indicating endogenous regulatory properties of IL-38 in B cell differentiation.
Our project, for the first time proves direct effects of IL-38 on human B cells. The results support previous research of IL-38 to act anti-inflammatory as it seems to modulate B cell differentiation, survival, and immunoglobulin production in a down-regulatory manner. These findings pave way for more detailed research on the connection between B cell homoeostasis and IL-38 function.