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Malaria and HIV are among the most important global health problems of our time and together are responsible for approximately 3 million deaths annually. These two diseases overlap in many regions of the world including sub-Saharan Africa, Southeast Asia and South America, leading to a higher risk of co-infection. In this study, we generated and characterized hybrid molecules to target P. falciparum and HIV simultaneously for a potential HIV/malaria combination therapy. Hybrid molecules were synthesized by covalent fusion between azidothymidine (AZT) and dihydroartemisinin (DHA), tetraoxane or chloroquine (CQ); and a small library was generated and tested for antiviral and antimalarial activity. Our data suggest that dihyate is the most potent molecule in vitro, with antiplasmodial activity comparable to that of DHA (IC50 = 26 nM, SI > 3000), a moderate activity against HIV (IC50 = 2.9 µM; SI > 35) and safe to HeLa cells at concentrations used in the assay (CC50 > 100 µM). Pharmacokinetic studies further revealed that dihyate is metabolically unstable and is cleaved following an O-dealkylation once in contact with cytochrome P450 enzymes. The later further explains the uneffectiveness of dihyate against the CQ-sensitive P. berghei N strain in mice when administered by oral route at 20 mg/kg. Here, we report on a first approach to develop antimalarial/anti-HIV hybrid molecules and future optimization efforts will aim at producing second generation hybrid molecules to improve activity against HIV as well as compound bioavailability. With the emergence of resistant parasites against all the counterpart drugs of artemisinin derivatives used in artemisinin based combination therapies (ACTs), the introduction of antibiotics in the treatment of malaria has renewed interest on the identification of antibiotics with potent antimalarial properties. In this study we also investigated the antiplasmodial potential of thiostrepton and derivatives, synthesized using combinations of tail truncation, oxidation, and addition of lipophilic thiols to the terminal dehydroamino acid. We showed that derivatives SS231 and SS234 exhibit a better antiplasmodial activity (IC50 = 1 µM SI > 59 and SI > 77 respectively) than thiostrepton (IC50 = 8.95 µM, SI = 1.7). The antiplasmodial activity of these derivatives was observed at concentrations which are not hemolytic and non-toxic to human cell lines. Thiostrepton and derivatives appeared to exhibit transmission blocking properties when administered at their IC50 or IC90 concentrations and our data also showed that they attenuate proteasome activity of Plasmodium, which resulted in an accumulation of ubiquitinated proteins after incubation with their IC80 concentrations. Our results indicate that the parasite’s proteasome could be an attractive target for therapeutic intervention. In this regard, thiostrepton derivatives are promising candidates by dually acting on two independent targets, the proteasome and the apicoplast, with the capacity to eliminate both intraerythrocytic asexual and transmission stages of the parasite. To further support our findings, we evaluated the activity of a new class of antimalarial and proteasome inhibitors namely peptidyl sulfonyl fluorides on gametocyte maturation and analogues AJ34 and AJ38 were able to completely suppress gametocytogenesis at IC50 concentrations (0.23 µM and 0.17 µM respectively) suggesting a strong transmission blocking potential. The proteasome, a major proteolytic complex, responsible for the degradation and re-cycling of non-functional proteins has been studied only indirectly in P. falciparum. In addition, an apparent proteasome-like protein with similarity to bacterial ClpQ/hslV threonine-peptidases was predicted in the parasite. Antibodies were generated against the proteasome subunits alpha type 5 (α5-SU), beta type 5 (β5-SU) and pfhslV in mice and we showed that the proteasome is expressed in both sexual and asexual blood stages of P. falciparum, where they localize in the nucleus and in the cytoplasm. However, expression of PfhslV was only observed in trophozoites and shizonts. The trafficking of the studied proteasome subunits was further investigated by generating parasites expressing GFP tagged proteins. The expression of α5-SU-GFP in transgenic parasite appeared to localize abundantly in the cytoplasm of all blood stages, and no additional information was obtained from this parasite line. In conclusion, our data highlight two new tools towards combination therapy. Hybrid molecules represent promising tools for the cure of co-infected individuals, while very potent antibiotics with a wide scope of activities could be useful in ACTs by eliminating resistant parasites and limiting transmission of both, resistances and disease.
Platelet activation and aggregation are essential to limit posttraumatic blood loss at sites of vascular injury, but also contribute to arterial thrombosis, leading to myocardial infarction and stroke. Thrombus formation is the result of well-defined molecular events, including agonist-induced elevation of intracellular calcium ([Ca2+]i) and series of cytoskeletal rearrangements. With the help of genetically modified mice, the work presented in this thesis identified novel mechanisms underlying the process of platelet activation in hemostasis and thrombosis. Store-operated calcium entry (SOCE) through Orai1 was previously shown to be the main Ca2+ influx pathway in murine platelets. The residual Ca2+ entry in the Orai1 deficient platelets suggested a role for additional non-store-operated Ca2+ (non-SOC) and receptor operated Ca2+ entry (ROCE) in maintaining platelet calcium homeostasis. Canonical transient receptor potential channel 6 (TRPC6), which is expressed in both human and murine platelets, has been attributed to be involved in SOCE as well as in diacylglycerol (DAG)-triggered ROCE. In the first part of the study, the function of TRPC6 in platelet Ca2+ signaling and activation was analyzed by using the TRPC6 knockout mice. In vitro agonist induced Ca2+ responses and in vivo platelet function were unaltered in Trpc6-/- mice. However, Trpc6-/- mice displayed a completely abolished DAG mediated Ca2+-influx but a normal SOCE. These findings identified TRPC6 as the major DAG operated ROC channel in murine platelets, but DAG mediated ROCE has no major functional relevance for hemostasis and thrombosis. In the second part of the thesis, the involvement of the PDLIM family member CLP36 in the signaling pathway of the major platelet collagen receptor glycoprotein (GP) VI was investigated. The GPVI/FcR-chain complex initiates platelet activation through a series of tyrosine phosphorylation events downstream of the FcR-chain-associated immunoreceptor tyrosine-based activation motif (ITAM). GPVI signaling has to be tightly regulated to prevent uncontrolled intravascular platelet activation, but the underlying mechanisms are not fully understood. The present study reports the adaptor protein CLP36 as a major inhibitor of GPVI-ITAM signaling in platelets. Platelets from mice expressing a truncated form of CLP36, (Clp36ΔLIM) and platelets from mice lacking the entire protein (Clp36-/-) displayed profound hyper-activation in response to GPVI-specific agonists, whereas GPCR signaling pathways remained unaffected. These alterations translated into accelerated thrombus formation and enhanced pro-coagulant activity of Clp36ΔLIM platelets and a pro-thrombotic phenotype in vivo. These studies revealed an unexpected inhibitory function of CLP36 in GPVI-ITAM signaling and established it as a key regulator of arterial thrombosis.
During the past years, the internal transcribed spacer 2 (ITS2) was established as a commonly used molecular phylogenetic marker for the eukaryotes. Its fast evolving sequence is predestinated for the use in low-level phylogenetics. However, the ITS2 also consists of a very conserved secondary structure. This enables the discrimination between more distantly related species. The combination of both in a sequence-structure based analysis increases the resolution of the marker and enables even more robust tree reconstructions on a broader taxonomic range. But, performing such an analysis required the application of different programs and databases making the use of the ITS2 non trivial for the typical biologist. To overcome this hindrance, I have developed the ITS2 Workbench, a completely web-based tool for automated phylogenetic sequence-structure analyses using the ITS2 (http://its2.bioapps.biozentrum.uni-wuerzburg.de). The development started with an optimization of length modelling topologies for Hidden Markov Models (HMMs), which were successfully applied on a secondary structure prediction model of the ITS2 marker. Here, structure is predicted by considering the sequences' composition in combination with the length distribution of different helical regions. Next, I integrated HMMs into the sequence-structure generation process for the delineation of the ITS2 within a given sequence. This re-implemented pipeline could more than double the number of structure predictions and reduce the runtime to a few days. Together with further optimizations of the homology modelling process I can now exhaustively predict secondary structures in several iterations. These modifications currently provide 380,000 annotated sequences including 288,000 structure predictions. To include these structures in the calculation of alignments and phylogenetic trees, I developed the R-package "treeforge". It generates sequence-structure alignments on up to four different coding alphabets. For the first time also structural bonds were considered in alignments, which required the estimation of new scoring matrices. Now, the reconstruction of Maximum Parsimony, Maximum Likelihood as well as Neighbour Joining trees on all four alphabets requires just a few lines of code. The package was used to resolve the controversial chlorophyceaen dataset and could be integrated into future versions of the ITS2 workbench. The platform is based on a modern, feature-rich Web 2.0 user interface equipped with the latest AJAX and Web-service technologies. It performs HMM-based sequence annotation, structure prediction by energy minimization or homology modelling, alignment calculation and tree reconstruction on a flexible data pool that repeats calculations according to data changes. Further, it provides sequence motif detection to control annotation and structure prediction and a sequence-structure based BLAST search, which facilitates the taxon sampling process. All features and the usage of the ITS2 workbench are explained in a video tutorial. However, the workbench bears some limitations regarding the size of datasets. This is caused mainly due to the immense computational power needed for such extensive calculations. To demonstrate the validity of the approach also for large-scale analyses, a fully automated reconstruction of the Chlorophyta (Green Algal) Tree of Life was performed. The successful application of the marker even on large datasets underlines the capabilities of ITS2 sequence-structure analysis and suggests its utilization on further datasets. The ITS2 workbench provides an excellent starting point for such endeavours.
Based on genetic association and functional imaging studies, reduced function of tryptophan hydroxylase-2 (TPH2) has been shown to be critically involved in the pathophysiology of anxiety-disorders and depression. In order to elucidate the impact of a complete neuronal 5-HT deficiency, mice with a targeted inactivation of the gene encoding Tph2 were generated. Interestingly, survival of Tph2-/- mice, the formation of serotonergic neurons and the pathfinding of their projections was not impaired. Within this thesis, I investigated the influence of 5-HT deficiency on the γ-amino butyric acid (GABA) system. The GABAergic system is implicated in the pathophysiology of anxiety disorders. Therefore, measurement of GABA concentrations in different limbic brain regions was carried out. These measurements were combined with immunohistochemical estimation of GABAergic cell subpopulations in the dorsal hippocampus and amygdala. In Tph2-/- mice GABA concentrations were increased exclusively in the dorsal hippocampus. In heterozygous Tph2+/- mice concentrations of GABA were increased in the amygdala compared to Tph2-/- and wt control mice, while the reverse was found in the prefrontal cortex. The changes in GABA concentrations were accompanied by altered cell density of GABAergic neurons within the basolateral complex of the amygdala and parvalbumin (PV) neurons of the dorsal hippocampus and by adaptational changes of 5-HT receptors. Thus, adaptive changes during the development on the GABA system may reflect altered anxiety-like and depressive-like behavior in adulthood. Moreover, chronic mild stress (CMS) rescues the depressive-like effects induced by 5-HT deficiency. In contrast, 5-HT is important in mediating an increased innate anxiety-like behavior under CMS conditions. This is in line with a proposed dual role of 5-HT acting through different mechanisms on anxiety and depressive-like behavior, which is influenced by gene-environment interaction effects. Further research is needed to disentangle these complex networks in the future.
Autoimmune diseases, unwanted overshooting immune responses against self antigens, are due to an imbalance in immunity and tolerance. Although negatively impacting cancer prognosis, myeloid derived suppressor cells (MDSC), with their potent suppressive capabilities, might be applicable in a more beneficial light when applied in to autoimmunity. As previous shown MDSC have protective roles in Experimental Autoimmune Encephalomyelitis (EAE) (Zhu et al., 2007), the established inducible mouse model for the autoimmune disease multiple sclerosis (MS). This decrease in disease severity indicates in vitro generated immature myeloid cells (IMC) from bone marrow (BM) as precursors of MDSC are promising candidates for cellular therapy. Important to any cellular therapy by adoptive transfer, the major questions regarding IMC efficacy was addressed within the thesis. This thesis attempts to elucidate how IMC operate in EAE. This thesis defines the factors within the autoimmune microenvironment that lead to the activation of MDSC, where IMC home once delivered in vivo, and the protective mechanisms BMIMC employ. To emulate BM cells when they first enter circulation through the blood, IMC were injected intravenously (i.v.). IMC are protective with no regard to the various routes delivered (i.v., i.p.). They protect to a lesser extent when pre-activated before injection. IMC suppress by causing a delay and/or by decreasing the severity of the disease via a mechanism yet determined. To understand the migration pattern of IMC after i.v. injection, in vivo kinetics experiments employing bioluminescence imaging were performed. This techinique allows for whole in vivo mouse imaging daily, allowing the tracking of cell migration over days within a single mouse. During steady-state, BMIMC circulate and appear to accumulate in the spleen by day 4 after injection, whereas they alternatively home to inflammatory sites (immunization site), draining lymph nodes, and the spleen within mice with low grade EAE. Visualization of CMDiI-labelled BMIMC by fluorescence microscopy could locate IMC injected cells outside the white pulp, as they were colocalizing in the regions stained with CD169 or outside, but not within the follicles of spleens on day 4. Consistant with these findings, the attempt to analyze the phenotype of these cells by flow cytometry was problematic as these cells seem to adhere strongly to collagen also indicating the cells are located in the collagenous area of the marginal zone and the red pulp.To determine factors influencing MDSC activation, we utilized different stimuli through a high throughput method detecting release of nitric oxide (NO). Extracts from yeast, fungi, and bacteria were observed to activate MDSC to produce nitric oxide. Surprisingly, material mimicking viral DNA (CpG) and RNA (poly I:C), and several self glycolipids, could not activate the MDSC to produce NO. Upon attempts to understand synergistic effects between microbial pathogens and host cytokines, IFNg was determined to boost the signal of pathogen stimuli, whereas IL17, another cytokine which causes pathology during EAE, and IFNb, a drug used in therapy to treat MS, did not cause any additional effects. Activation of MDSC was determined by the microbial pathogens components LPS, curdlan, and zymosan, to induce upregulation of B7H1 on the cell surface. MDSC did not increase any co-stimulatory markers, such as CD40, CD80, CD86, CD70, or the co-inhibitory marker, PDL2. On day 1 after EAE induction, endogenous MDSC populations when stimulated showed an increase in B7H1 expression and a downregulation of CD80. After further analysis, these cells were concluded to be mostly granulocytic cells (Ly6G+). As the B7H1 ligand PD1 is upregulated in chronic diseases and correlates to an exhausted phenotype, the PD1 : B7H1 interaction was a good candidate for the mechanism our cells may employ for their suppressive capacity. To investigate this interaction, fixed BM-IMC deficient in B7H1 were incubated with restimulated memory T cells. IMC deficient in B7H1 resulted in a significant loss of T cell suppression, as compared to the wildtype control BMIMC. To assess this interaction in vivo, we injected wildtype (WT) and B7H1-/- IMC into mice followed by induction of EAE to assess whether B7H1 mediated this suppression. The lack of B7H1 did not alter their suppressive capacity under these conditions, contrary to other findings which have described this interaction to be important in their suppressive capacity when administered post EAE induction (Ioannou et al., 2012). Interestingly, EAE mice pre-treated with IMC had similar amounts of cytokine production in the CNS after restimulation. Spleens from IMC injected mice had increased amounts of Arg-1 suggesting suppression is via oxidation or recruitment by soluble mediators may lead to this protection. We speculate this may inhibit T cell reactivation in the CNS.
In cultured motoneurons of a mouse model for the motoneuron disease spinal muscular atrophy (SMA), reduced levels of the protein SMN (survival of motoneurons) cause defects in axonal growth. This correlates with reduced β-actin mRNA and protein in growth cones, indicating that anterograde transport and local translation of β-actin mRNA are crucial for motoneuron function. However, direct evidence that indeed local translation is a physiological phenomenon in growth cones of motoneurons was missing. Here, a lentiviral GFP-based reporter construct was established to monitor local protein synthesis of β-actin mRNA. Time-lapse imaging of fluorescence recovery after photobleaching (FRAP) in living motoneurons revealed that β-actin is locally translated in the growth cones of embryonic motoneurons. Interestingly, local translation of the β-actin reporter construct was differentially regulated by different laminin isoforms, indicating that laminins provide extracellular cues for the regulation of local translation in growth cones. Notably, local translation of β-actin mRNA was deregulated when motoneurons of a mouse model for type I SMA (Smn-/-; SMN2) were analyzed. In situ hybridization revealed reduced levels of β-actin mRNA in the axons of Smn-/-; SMN2 motoneurons. The distribution of the β-actin mRNA was not modified by different laminin isoforms as revealed by in situ hybridization against the mRNA of the eGFP encoding element of the β-actin reporter. In case of the mRNA of α-actin and γ-actin isoforms, the endogenous mRNA did not localize to the axons and the localization pattern was not affected by the SMN levels expressed in the cell. Taken together our findings suggest that regulation of local translation of β-actin in growth cones of motoneurons critically depends on laminin signaling and the amount of SMN protein. Embryonic stem cell (ESC)-derived motoneurons are an excellent in vitro system to sort out biochemical and cellular pathways which are defective in neurodegenerative diseases like SMA. Here, a protocol for the differentiation and antibody-mediated enrichment of ESC-derived motoneurons is presented, which was optimized during the course of this study. Notably, this study contributes the production and purification of highly active recombinant sonic hedgehog (Shh), which was needed for the efficient differentiation of mouse ESCs to motoneurons. ESC-derived motoneurons will now offer high amounts of cellular material to allow the biochemical identification of disease-relevant molecular components involved in regulated local protein synthesis in axons and growth cones of motoneurons.
Escherichia coli Nissle 1917 (EcN) gehört zu den am besten untersuchten und charakterisierten probiotischen Bakterienstämmen. Seit Beginn des letzten Jahrhunderts wird er als Medikament eingesetzt, um verschiedene Darmerkrankungen wie z.B. Diarrhöe, entzündliche Darmerkrankungen und Verstopfung zu behandeln. Die Flagelle des EcN vermittelt Beweglichkeit und kann die Produktion von humanem β-Defensin 2 (hBD2) durch Epithelzellen induzieren. Somit ist dieses Organell direkt in die probiotische Funktion des EcN involviert. Es konnte gezeigt werden, dass die Flagellen anderer Bakterien, wie z.B. dem probiotischen Stamm Bacillus cereus CH oder den pathogenen Stämmen Pseudomonas aeruginosa und Clostridium difficile, die Adhäsion an intestinalen Mucus, welcher von Epithelzellen sekretiert wird, vermitteln. Allerdings blieb unklar, welcher Teil der Flagelle an welche Mucuskomponente bindet. Die Fähigkeit effizient an Wirtgewebe zu adhärieren wird als wichtiges Attribut eines probiotischen Stammes angesehen. Ex vivo Adhäsionsstudien mit Kryoschnitten humaner Darmbiopsien haben gezeigt, dass die Flagelle des EcN in die effiziente Adhäsion an humanes Darmgewebe involviert sein muss. Aus diesem Grund wurde in dieser Arbeit die Funktion der Flagelle des EcN als Adhäsin untersucht. Zunächst wurde die hyperflagellierte Variante EcN ATHF isoliert und durch verschiedene Experimente, z.B. Schwärmagartests und Elektronenmikroskopie, charakterisiert. Weitere ex vivo Adhäsionsstudien mit EcN ATHF zeigten eine höhere Adhäsionseffizienz dieser hyperflagellierten Variante und bestätigten damit die Rolle der Flagelle bei der effizienten Adhäsion von EcN an die Kryoschnitte der humanen Darmbiopsien. Interessanterweise fungierte die Flagelle in in vitro Studien mit den humanen Epithelzellen Caco-2 und T24 nicht als Adhäsin. Diese Unterschiede zwischen den in vitro und ex vivo Studien führten zu der Annahme, dass die Flagelle des EcN in vivo die Adhäsion an Mucus vermittelt, welcher von den Caco-2- und T24-Zellen nicht produziert wird, aber in den Kryoschnitten der Darmbiopsien nachgewiesen wurde. Diese Vermutung wurde durch in vitro Adhäsionsstudien mit der Mucin-produzierenden Epithelzelllinie LS174-T bestätigt, da die Flagellen für eine effektive Adhäsion an diese Zellen essentiell waren. Zudem reduzierte die Präinkubation flagellierter EcN-Stämme mit Mucin2 ihre Adhäsionseffizienz an Kryoschnitte humaner Darmbiopsien. Um die direkte Interaktion zwischen Flagellen des EcN Wildtyps und Mucus zu zeigen, wurde ein ELISA etabliert. Es konnte eine direkte konzentrationsabhängige Interaktion zwischen isolierten Flagellen des EcN Wildtyps und Mucin2, bzw. humanem Mucus (Kolon) beobachtet werden. Interessanterweise konnte keine Interaktion zwischen isolierten Flagellen des EcN Wildtyps und murinem Mucus (Duodenum, Ileum, Caecum, Colon) festgestellt werden. Dies weist darauf hin, dass die Mucuszusammensetzung zwischen verschiedenen Spezies variiert. Verschiedene Kohlenhydrate, welche bekannte Mucusbestandteile sind, wurden auf ihre Interaktion mit der Flagelle von EcN getestet und Gluconat wurde als ein Rezeptor identifiziert. Die Präinkubation isolierter Flagellen mit Gluconat reduzierte ihre Interaktion mit Mucin2, bzw. humanem Mucus signifikant. Zudem wurde die oberflächenexponierte Domäne D3 des Flagellins, der Hauptuntereinheit der Flagelle, als möglicher Interaktionspartner von Mucin2, bzw. humanem Mucus ausgeschlossen. Flagellen, die aus einer Domäne D3 Deletionsmutante isoliert wurden, zeigten sogar eine effizientere Bindung an Mucin2, bzw. humanen Mucus. Weiterhin konnte gezeigt werden, dass Änderungen des pH-Wertes signifikante Effekte auf die Interaktion zwischen Mucus und isolierten Flagellen hatten, vermutlich aufgrund von Konformationsänderungen. Zusammenfassend wurde in dieser Arbeit die Flagelle als neues und scheinbar wichtigstes Adhäsin in vivo für den probiotischen Stamm EcN identifiziert. Hierfür wurden sowohl eine hyperflagellierte Variante, eine ΔfliC Mutante, sowie der dazugehörige komplementierte Stamm verwendet. EcN ist zudem der erste probiotische Stamm für den eine direkte Bindung der Flagellen an humanen Mucus nachgewiesen werden konnte. Die Mucuskomponente Gluconat konnte dabei als wichtiger Rezeptor identifiziert werden. Da einige pathogene Bakterien ihre Flagelle zur Adhäsion an Wirtsgewebe nutzen, könnte dieses Organell EcN dazu befähigen, mit Pathogenen um die erfolgreiche Kolonisierung des Darms zu konkurrieren, was als wichtige Eigenschaft eines Probiotikums betrachtet wird.
Spreading drug resistances among Gram-negative pathogens and the paucity of new agents on the antibacterial drug market against these tenacious bacteria create a pressing need for the development of new antibiotics. The bacterial fatty acid biosynthesis pathway FAS-II, especially the enoyl-ACP reductase catalyzing the last step of the elongation cycle, is an established drug target against tuberculosis but has not been extensively exploited for drug design against other bacterial pathogens. In this thesis the enoyl-ACP reductases of the Gram-negative biothreat organisms Burkholderia pseudomallei and Yersinia pestis were targeted in a structure-based drug design approach. The structure of the most recently identified enoyl-ACP isoenzyme FabV was characterized by X-ray crystallography and could be determined in three different states. FabV from B. pseudomallei was obtained in the apo-form of the enzyme, whereas FabV from Y. pestis was characterized in a binary complex with the cofactor NADH as well as in a ternary complex with NADH and the triclosan-based 2-pyridone inhibitors PT172 and PT173. Analysis of the FabV structure revealed the typical fold of the short chain dehydrogenase/reductase superfamily with the NADH-binding Rossmann fold and a substrate-binding pocket with a conserved active site geometry compared to the related isoenzyme FabI. Additional structural elements of FabV are located around the active site. The monomeric form of the enzyme is thereby stabilized and the substrate-binding loop is kept in a closed, helical conformation. The ternary complexes of FabV exhibited a similar inhibitor-binding mode as observed for triclosan inhibition in FabI and point to a potential substrate-binding mechanism. B. pseudomallei possesses FabI as an additional enoyl-ACP reductase isoenzyme, which was structurally characterized in the apo form and in ternary complexes with NAD+ and the diphenyl ether inhibitors triclosan, PT02, PT12 or PT404 as well as the 4-pyridone inhibitor PT155. The structural data of the ternary enoyl-ACP reductases complexes of B. pseudomallei and Y. pestis hold the promise for the possibility to develop antibacterials targeting FabV or even both isoenzymes, FabI and FabV, based on the triclosan scaffold.
Cutaneous leishmaniasis is endemic in tropical and subtropical regions of the world. Effective vaccination strategies are urgently needed because of the emergence of drug-resistant parasites and severe side effects of chemotherapy. The research group of Heidrun Moll previously established a DC-based vaccination strategy to induce complete and long-lasting immunity to experimental leishmaniasis using LmAg-loaded and CpG ODN-activated DC as a vaccine carrier. Prevention of tissue damages at the site of L. major inoculation can be achieved if the BALB/c mice were systemically given LmAg-loaded BMDC that had been exposed to CpG ODN. The interest in further exploring the role of IL-4 aroused as previous studies allowed establishing that IL-4 was involved in the redirection of the immune response towards a type 1 profile. Thus, wt BALB/c mice or DC-specific CD11ccreIL-4Rα-/lox BALB/c mice were given either wt or IL-4Rα-deficient LmAg-loaded BMDC exposed or not to CpG ODN prior to inoculation of 2 x 105 stationary phase L. major promastigotes into the BALB/c footpad. The results provide evidence that IL4/IL-4Rα-mediated signaling in the vaccinating DC is required to prevent tissue damages at the site of L. major inoculation, as properly conditioned wt DC but not IL-4Rα-deficient DC were able to confer resistance. Furthermore, uncontrolled L. major population size expansion was observed in the footpad and the footpad draining LN in CD11ccreIL-4Rα-/lox mice immunized with CpG ODN-exposed LmAg-loaded IL-4Rα-deficient DC, indicating the influence of IL-4R-mediated signaling in host DC to control parasite replication. In addition, no footpad damage was observed in BALB/c mice that were systemically immunized with LmAg-loaded wt DC doubly exposed to CpG ODN and recombinant IL-4. Discussing these findings allow the assumption that triggering the IL4/IL4Rα signaling pathway could be a precondition when designing vaccines aimed to prevent damaging processes in tissues hosting intracellular microorganisms.
Stimulatory or superagonistic (SA) CD28-specific monoclonal antibodies (mAbs) are potent polyclonal activators of regulatory T cells and have proven highly effective as treatment in a wide range of rodent models for autoimmune and inflammatory diseases. In these models, a preferential activation of regulatory T cells was observed by in vivo administration of CD28SA. In stark contrast, human volunteers receiving TGN1412, a humanized CD28-specific mAb, experienced a life-threatening cytokine release syndrome during the first-in-man trial. Preclinical tests employing human peripheral blood mononuclear cells (PBMC) failed to announce the rapid cytokine release measured in the human volunteers in response to TGN1412. The aim of this thesis project was to find an explanation of why standard PBMC assays failed to predict the unexpected TGN1412-induced "cytokine storm" observed in human volunteers. CD28 superagonists can activate T cells without T cell receptor (TCR) ligation. They do depend, however, on “tonic” TCR signals received by MHC scanning, signals that they amplify. PBMC do not receive these signals in the circulation. Short-term in vitro preculture of human PBMC at a high cell density (HDC) resulted in massive cytokine release during subsequent TGN1412 stimulation. Restoration of reactivity was cell-contact dependent, associated with TCR polarization and tyrosine-phosphorylation, and blocked by HLA-specific mAb. In HDC, both CD4 T cells and monocytes functionally mature in a mutually dependent fashion. However, only CD4 memory T-cells proliferate upon TGN1412 stimulation, and were identified as the main source of pro-inflammatory cytokines. Importantly, responses to other T-cell activating agents were also enhanced if PBMC were first allowed to interact under tissue-like conditions. A new in vitro protocol is provided that returns circulating T-cells to a tissue-like status where they respond to TGN1412 stimulation, and it might represent a more reliable preclinical in vitro test for both activating and inhibitory immunomodulatory drugs. Finally, the surprising observation was made that the IgG1 “sibling” of TGN1412, which is of the poorly Fc receptor-binding IgG4 isotype, has a much lower stimulatory activity. We could exclude steric hindrance as an explanation and provide evidence for removal of TGN1112 from the T-cell surface by trans-endocytosis.