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The present investigation report a protocol to obtain dendritic cells (DC) that protects mice against fatal leishmaniasis. DC were generated from bone marrow precursors, pulsed with leishmanial antigen and activated with CpG oligodeoxinucleotides. Mice that were vaccinated with these cells were strongly protected against the clinical and parasitological manifestations of leishmaniasis and developed a Th1 immune response. protection was solid and long-lasting, and was also dependent of the via of administration. Whe the mechanism of protection was studied, it was observed that the availability of the cytokine interleukin-12 at the time of vaccination was a key requirement, but that the source of this cytokine is not the donor cells but unidentified cells from the recipients.
Cutaneous leishmaniasis is an infectious disease that is endemic especially in tropical and desert regions with an incidence of 1.5 million cases per year and a prevalence of 12 million people infected worldwide. The infection can be caused by the intracellular parasite Leishmania major. The disease has been studied extensively in the murine model. It has become apparent that the induction of a class of interferon (IFN)--producing CD4+ T helper cells (TH1 cells) that activate macrophages to kill the parasites they harbor is desicive for the establishment of immunity. The redirection of the host’s immune response towards a protective TH1 phenotype will also be the key to an effective vaccine. Dendritic cells (DC) loaded with leishmanial antigens ex vivo were lately described as vaccines against L. major infections. One single recombinant Leishmania antigen, LeIF (Leishmania homologue of eukaryotic ribosomal initiation factor 4a), which was identified as a protein that stimulates DC to secrete interleukin (IL)-12 and discussed as a pattern-associated molecular pattern (PAMP), was found to mediate a protective TH1-dependent effect when used for pulsing of DC. The application of recombinant proteins is tied to many disadvantages, which is why other methods of antigen administration have been developed. RNA electroporation of DC has recently emerged from tumor research as a safe and versatile method of antigen delivery, by which a large number of RNA molecules encoding a specific antigen gains access to the cytosol of DC by an electrical impulse. The present study describes, for the first time, transfection of DC with RNA encoding a molecularly defined parasite antigen. Initially, a standardized protocol for RNA transfection was established, using the enhanced green fluorescent protein (EGFP) as reporter antigen. EGFP-RNA was well translatable in an in vitro translation system, and both a DC cell line (fetal skin-derived DC; FSDC) and murine primary bone marrow-derived DC (BMDC) could be transfected efficiently, with a yield of up to 90% and 75%, respectively. In both cell types, maximal transfection efficiency was attained with 20 µg RNA and could not be further increased with larger amounts of RNA. The level of antigen expression, measured as the mean fluorescence intensity (MFI) by flow cytometry, was directly proportional to the amount of RNA used for transfection. In FSDC, transfection efficiency and MFI were generally higher than in BMDC when the same amounts of RNA were used. Furthermore, the kinetics was shown to be sensitive to treatment with lipopolysaccharide (LPS): the expression peak was higher and was reached sooner, followed by a more rapid decline. In transfection experiments with LeIF, two variants of LeIF-RNA were used: LeIF(fl)-RNA, encoding the complete LeIF sequence, and LeIF(226)-RNA, encoding only the aminoterminal half of the LeIF sequence (226 amino acids), the immunogenic part of LeIF. Only LeIF(fl) was detectable by Western Blot in whole cell lysates of BMDC after LeIF(fl)-RNA transfection, whereas LeIF(226) could never be detected in LeIF(226)-transfected BMDC. However, as both constructs were well translatable in a cell-free system, the failure to detect LeIF(226) in BMDC lysates did not represent a failure in RNA translation, but rather a rapid antigen degradation. It was therefore expected that LeIF(226)-transfected BMDC should nevertheless be able to present LeIF(226)-derived antigenic peptides to T cells from BALB/c mice primed with recombinant LeIF (rLeIF). This hypothesis was confirmed by measuring IFN- production in BMDC-T cell co-incubation assays, showing that rLeIF-pulsed, LeIF(226)- and LeIF(fl)-transfected day 7 BMDC did indeed activate T cells from LeIF-immunized mice in an antigen-specific manner. In contrast, IL-4 was not produced, which was consistent with the fact that T cells found in lymph nodes from LeIF-primed mice are primarily of the TH1 type. In the supernatants of LeIF-transfected BMDC cultures, in contrast to rLeIF-pulsed BMDC, the proinflammatory cytokines IL-1β, IL-6, IL-10 and IL-12 were not detected. This effect was not due to the electroporation procedure, as cytokine production by BMDC electroporated with rLeIF was only partially impaired. Also, the expression levels of CD86 were lower upon LeIF transfection than after pulsing with rLeIF. Thus, LeIF transfection did not induce maturation of DC. In conclusion, LeIF-transfected BMDC may have acted as semi-mature antigen-specific tolerance inducers, with regulatory T cells as responders. The effect of LeIF transfection on the immunostimulatory capacity of BMDC was not significantly increased when day 8 or 9 BMDC were used. However, day 8, and even more day 9 BMDC pulsed with rLeIF mounted a vigorous T cell response. Day 9 BMDC were able to activate naïve T cells. In conclusion, before a strong T cell response against LeIF can be induced, DC need to – besides presenting antigen and expressing co-stimulatory molecules – exhibit a susceptibility to the innate signaling molecule LeIF which is linked to their maturation age. This third signal is provided by extracellular rLeIF, but it is not conveyed – or is suppressed – by intracellular LeIF after LeIF-RNA transfection. Furthermore, electroporation of rLeIF abrogated IL-12 production by BMDC completely, the production of IL-1 was reduced with higher antigen doses, and the production of IL-10 was partially increased. The IL-6 production was unaffected. This altered cytokine profile suggests that LeIF as a PAMP might have a bipartite nature: besides exhibiting the capacity to stimulate IL-12 production upon extracellular presence, thereby enhancing host resistance against L. major, LeIF could also contribute to parasitic host evasion mechanisms from intracellular compartments of DC, possibly by interfering with mitogen-activated protein (MAP) kinase signaling pathways. Thus, the adjuvant properties of LeIF depend both on its mode of delivery (transfection with RNA vs. pulsing with the recombinant protein) and the targeted compartment (extra- vs. intracellular). From this work, it can be summarized that BMDC are well transfectable with a parasite antigen. The antigen is processed and presented, but it is not recognized as a PAMP by DC. Hence, transfection with antigen-encoding mRNA by itself does not convey all necessary signals for the elicitation of a potent immune response.
Investigations of Measles virus regulation on activation and function of antigen presenting cells
(2008)
Interaction with dendritic cells (DCs) is considered as central to immunosuppression induced by viruses, including measles virus (MV). Commonly, viral infection of DCs abrogates their ability to promote T cell expansion, yet underlying mechanisms at a cellular level are undefined. It appears that MV-WTF infection modulate DCs morphology and dynamic adhesion on extra cellular matrix proteins such as FN or ICAM-1. By morphological criteria, WTF-DCs resembled LPS-DCs, associated with their mature phenotype also adhered less efficiently to the FN or ICAM-1 support. Reduced adhesion could not be explained by a lack of 1-integrin expression or activation. Similarly, MV-DCs strongly resembled LPS-DCs in that levels of focal adhesion kinase phosphorylated at Y397 were high and not further enhanced upon FN ligation. Fascin, a downstream effector of integrin signaling was highly upregulated in LPS-DCs and moderately in WTF-DCs, and differences in its subcellular distribution were not observed between both cell cultures. Apparently, however, fascin associated less efficiently with PKC in WTF-DCs then in LPS-DCs. In line with findings for murine DCs, high motility of mature human DCs was found to require expression of Rac-GTPases. Human LPS-DCs and more so, DC transfected to express constitutively active Rac1 were the most motile DC-species analysed, confirming that migration of human DC also involved Rac activity. The velocity of WTF-DCs on FN is below that of LPS-DCs, indicating that maturation induced by WTF may be insufficient to completely promote integrin signaling which leads to Rac activation. The organisation of MV-DC/T cell interfaces was consistent with that of functional immune synapses with regard to CD3 clustering, MHC class II surface recruitment and MTOC location. These analyses are based in the selection of stable conjugates. Subsequently, however, neither contacts nor calcium flux can be stabilised and sustained in the majority of MV-DC/T cell conjugates and only promoted abortive T cell activation. Formation of spatially organised IS in T cells requites, prolonged contact durations. Therefore, aberrant distribution patterns of CD3 in these structures, if occurring, are not likely to contribute to the type of contacts predominating for WTF-DC/T cell interactions. It is also likely that transient interactions of less than 2 minutes may if at all, not efficiently support viral transmission to T cells. Transient interactions are typically observed with immature DCs in the absence of antigen, but this is not likely to be relevant in our allogenic system, which includes SA-loaded WTF-DCs. Thus, MV-infected DCs retain activities required for initiating, but not sustaining T cell conjugation and activation. This is partially rescued if surface expression of the MV glycoproteins on DCs is abolished by infection with a recombinant MV encoding VSV G protein instead, indicating that these contribute directly to synapse destabilisation and thereby act as effectors of T cell inhibition.
Semaphorin receptors in the immunological synapse: regulation and measles virus-driven modulation
(2010)
Measles virus (MV) infection causes approximately 164,000 deaths per year worldwide (WHO, 2008). The main cause of death is MV-induced immunosuppression but the underlying mechanisms are not fully understood. It has been suggested that MV renders T cells dysfunctional by disrupting the integrity of actin dynamics while MV infection of dendritic cells results in their inability to sustain T cell activation. During neuronal development, semaphorins (SEMAs), especially SEMA3A, induce a collapse of growing dendrites via the binding to plexin-A1 (plexA1) and its coreceptor neuropilin-1 (NP-1). The collapse results from a disruption of actin dynamics. In this study, the roles of these three molecules were investigated in human immune cells and their possible role in MV induced immunosuppression. The present data have shown that plexA1 is an important component of human immunological synapse (IS). It translocated transiently to the surface of T cells after CD3/28 ligation and accumulated at the stimulatory interface between T cells and DCs (or CD3/28 coated beads). When plexA1 expression was inhibited (RNAi) or its function was disrupted (exogenous blocking or dominant negative expression), T cell expansion was reduced. Upon MV exposure, translocation of plexA1 and NP-1, another important component of IS, towards the stimulatory interface in T cells was abrogated. Moreover, MV infection interfered with plexA1/NP-1 turnover in maturing DCs and promoted early and substantial release of SEMA3A from these cells, particularly in the presence of allogenic T cells. As revealed by scanning electron microscopy, the release of SEMA3A caused a transient loss of actin-based protrusions on T cells. SEMA3A affected chemotactic migration of T cells and DCs, and reduced formation of allogenic DC/T cell conjugates. In conclusion, MV targeted SEMA receptor function both by disrupting their recruitment to the IS and by promoting a premature release of their repulsive ligand, SEMA3A. Both of which could contribute to MV-induced immunosuppression.
Background: Dendritic cells (DC) can act tolerogenic at a semi-mature stage by induction of protective CD4+ T cell and NKT cell responses. Methodology/Principal Findings: Here we studied the role of the co-inhibitory molecule B7-H1 (PD-L1, CD274) on semimature DC that were generated from bone marrow (BM) cells of B7-H12/2 mice and applied to the model of Experimental Autoimmune Encephalomyelitis (EAE). Injections of B7-H1-deficient DC showed increased EAE protection as compared to wild type (WT)-DC. Injections of B7-H12/2 TNF-DC induced higher release of peptide-specific IL-10 and IL-13 after restimulation in vitro together with elevated serum cytokines IL-4 and IL-13 produced by NKT cells, and reduced IL-17 and IFN-c production in the CNS. Experiments in CD1d2/2 and Ja2812/2 mice as well as with type I and II NKT cell lines indicated that only type II NKT cells but not type I NKT cells (invariant NKT cells) could be stimulated by an endogenous CD1d-ligand on DC and were responsible for the increased serum cytokine production in the absence of B7-H1. Conclusions/Significance: Together, our data indicate that BM-DC express an endogenous CD1d ligand and B7-H1 to ihibit type II but not type I NKT cells. In the absence of B7-H1 on these DC their tolerogenic potential to stimulate tolerogenic CD4+ and NKT cell responses is enhanced.
Characterization of tolerogenic rat bone marrow-derived dendritic cells and regulatory T cells
(2010)
Tolerogenic dendritic cells (DC) and regulatory T (Treg) cells are able to prevent destructive immune responses. There is reason to hope that it may soon be possible to use DC and Treg cells to suppress immune responses antigen-specific, not only after transplantation, but also in the case of autoimmunity and allergy. At the moment, the generation of such cell types is very time-consuming and not suitable for clinical routine. In addition, it is not yet fully understood how these cells elicit a desired protective immune response in vivo and how the risks of an excessive immune suppression can be managed. The rat is one of the most important animal models in biomedical research. It is therefore surprising that tolerogenic DC and Treg cells in particular have not been more thoroughly investigated in this model. Thus, the aim of the present study was to systematically characterize these immune cells and investigate their impact on the immune system. Tolerogenic DC were generated from bone marrow precursors cultured with GM-CSF and IL-4 (= IL-4 DC). The proportion of naturally occurring Treg cells with a CD4posCD25posFoxp3pos phenotype comprises approximately 5-8% of the peripheral CD4pos T cells. The characterization of IL-4 DC revealed an up to 26-fold reduced expression of surface molecules such as MHC class II molecules, CD80, CD86, ICAM-1 and CD25 in comparison to mature splenic DC (S-DC). This low expression did not change when the cells where stimulated with different maturation-inducing signals such as replating, LPS, TNF- α and CD40L. Thus, these cells possess a robust phenotype resistant to maturation-inducing stimuli. IL-4 DC take up antigen via endocytosis and are not able to activate naïve T cells or to restimulate antigen-specific T cells. Furthermore, they are able to inhibit and prolongate mature S-DC induced T cell proliferation as well as mature S-DC induced restimulation of antigen-specific T cells, respectively. Thereby, the T cell proliferation was reduced up to 95%. This strong inhibitory effect was mediated within 24 hours in association with a reduced cytokine production (IL-2 about 49% and IFN-γ about 92%). The inhibitory properties of IL-4 DC don´t seem to be caused exclusively by the reduced expression of co-stimulatory molecules. In this study, the detection of the inhibitory molecules PD-L1 and PD-L2 on IL-4 DC suggests they have an impact on mediating inhibitory signals to the T cells. In addition, a suppressive effect of soluble factors was shown. The supernatant of one million IL-4 DC, collected after a 24 hour culture, suppressed mature S-DC induced proliferation of naïve T cells by about 90%. TGF-β, which was detected in the supernatant (up to 300 pg/ml), appears to be the causing soluble factor for this immune inhibition. By contrast, the supernatants of mature S-DC, which did not inhibit the activation of T cells, showed a TGF-β concentration of only about 100 pg/ml. The cytotoxic nitric oxide does not contribute to the IL-4 DC-mediated inhibition of T cell proliferation. The NO synthase inhibitor NMMA reduced the amount of NO by about 50%, but the decreased NO levels did not influence T cell proliferation. Indeed, IL-4 DC are not able to induce T cell proliferation, but this doesn´t mean that there is no change on the molecular level. For instance, T cells co-cultured with IL-4 DC during a first culture are not able to proliferate in the presence of mature S-DC during a second culture. This anergic-like state, however, could be abolished by adding exogenous IL-2. In addition, T cells co-cultured with IL-4 DC are able to inhibit the activation of naïve T cells. Naïve and activated T cells were not able to inhibit the mature S-DC induced T cell proliferation. This observation suggests the induction of Treg cells and was investigated in more detail. Indeed, flow cytometric analysis showed a 1.6-fold expansion of CD4posCD25posFoxp3pos T cells from naturally occurring Treg cells in the presence of IL-4 DC. Thereby, the expansion of CD4posCD25posFoxp3pos T cells occurs independently of the maturation state of DC. Both immature IL-4 DC as well as mature S-DC were able to expand the percentage of naturally occurring Treg cells. However, Treg cells pre-incubated with mature S-DC demonstrated a diminished inhibitory effect compared to Treg cells pre-incubated with IL-4 DC. Treg cells pre-incubated with IL-4 DC were able to inhibit the activation of naïve T cells. In this study it was shown that the regulatory potential of DC cannot be deduced solely by their phenotype or maturation state. Other factors, such as functional properties, need to taken into consideration, too. The induction of Treg cells with suppressive properties induced by in vitro generated tolerogenic IL-4 DC might provide an important mechanism for the maintenance of peripheral tolerance. However, for clinical application further investigation is necessary, not only to understand the interactions between tolerogenic DC and Treg cells, but also to investigate the impact of the transfer of a larger quantity of regulatory cells on the immune system of the recipient.
Polarity and migration are essential for T cell activation, homeostasis, recirculation and effector function. To address how T cells coordinate polarization and migration when interacting with dendritic cells (DC) during homeostatic and activating conditions, a low density collagen model was used for confocal live-cell imaging and high-resolution 3D reconstruction of fixed samples. During short-lived (5 to 15 min) and migratory homeostatic interactions, recently activated T cells simultaneously maintained their amoeboid polarization and polarized towards the DC. The resulting fully dynamic and asymmetrical interaction plane comprised all compartments of the migrating T cell: the actin-rich leading edge drove migration but displayed only moderate signaling activity; the mid-zone mediated TCR/MHC induced signals associated with homeostatic proliferation; and the rear uropod mediated predominantly MHC independent signals possibly connected to contact-dependent T cell survival. This “dynamic immunological synapse” with distinct signaling sectors enables moving T cells to serially sample antigen-presenting cells and resident tissue cells and thus to collect information along the way. In contrast to homeostatic contacts, recognition of the cognate antigen led to long-lasting T cell/DC interaction with T cell rounding, disintegration of the uropod, T cell polarization towards the DC, and the formation of a symmetrical contact plane. However, the polarity of the continuously migrating DC remained intact and T cells aggregated within the DC uropod, an interesting cellular compartment potentially involved in T cell activation and regulation of the immune response. Taken together, 3D collagen facilitates high resolution morphological studies of T cell function under realistic, in vivo-like conditions.
Background: Parkinson’s disease (PD) is characterized at the cellular level by a destruction of neuromelanin (NM)-containing dopaminergic cells and a profound reduction in striatal dopamine. It has been shown recently that antimelanin antibodies are increased in sera of Parkinson patients, suggesting that NM may act as an autoantigen. In this study we tested whether NM is being recognized by dendritic cells (DCs), the major cell type for inducing Tand B-cell responses in vivo. This recognition of NM by DCs is a prerequisite to trigger an adaptive autoimmune response directed against NM-associated structures. Results: Murine DCs were treated with NM of substantia nigra (SN) from human subjects or with synthetic dopamine melanin (DAM). DCs effectively phagocytized NM and subsequently developed a mature phenotype (CD86high/MHCIIhigh). NM-activated DCs secreted the proinflammatory cytokines IL-6 and TNF-a. In addition, they potently triggered T cell proliferation in a mixed lymphocyte reaction, showing that DC activation was functional to induce a primary T cell response. In contrast, DAM, which lacks the protein and lipid components of NM but mimics the dopamine-melanin backbone of NM, had only very little effect on DC phenotype and function. Conclusions: NM is recognized by DCs in vitro and triggers their maturation. If operative in vivo, this would allow the DC-mediated transport and presentation of SN antigens to the adaptive immune system, leading to autoimmmunity in susceptible individuals. Our data provide a rationale for an autoimmune-based pathomechanism of PD with NM as the initial trigger.
Effective T cell immunity was believed to occur by mature DC, whereas tolerogenicity was attributed strictly to immature DC phenotypes. However, intermediate DC maturation stages were identified conditioned by inflammatory mediators like TNF. Furthermore, the T cell tolerance mechanisms are dependent on distinct modes and intensities of co-stimulation. Therefore, in this study it was addressed how distinct DC maturation signatures instruct CD4+ T cell tolerance mechanisms. DC acquire antigens from apoptotic cells for self-peptide-MHC presentation and functionally adapt presumed tolerogenic DC phenotypes. Here, immature murine bone-marrow derived DC representing both inflammatory and conventional DC subsets adapted a maturationresistant DC signature upon apoptotic cell recognition but no additional tolerogenic features. Immature DC instruct CD4+ FoxP3+ regulatory T cells in a TGF-β prone micro-environment or generate anergic CD4+ T cells hampered in the TCR-induced proliferation and IL-2 secretion. Secondary stimulation of such anergic CD4+ T cells by immature DC increased primarily IL-10 production and conferred regulatory function. These IL-10+ regulatory T cells expressed high levels of CTLA-4, which is potently induced by immature DC in particular. Data in this work showed that anergic T cells can be re-programmed to become IL-10+ regulatory T cells upon ligation of CTLA-4 and CD28 signalling cascades by B7 costimulatory ligands on immature DC. In contrast, semi-mature DC phenotypes conditioned by the inflammatory mediator TNF prevented autoimmune disorders by induction of IL-10+ Th2 responses as demonstrated previously. Here, it was shown that TNF as an endogenous maturation stimulus and pathogenic Trypanosoma brucei variant-specific surface glycoproteins (VSG) induced highly similar DC gene expression signatures which instructed default effector Th2 responses. Repetitive administration of the differentially conditioned semi-mature DC effectively skewed T cell immunity to IL-10+ Th2 cells, mediating immune deviation and suppression. Collectively, the data presented in this work provide novel insights how immature and partially mature DC phenotypes generate T cell tolerance mechanisms in vitro, which has important implications for the design of effective DC-targeted vaccines. Unravelling the DC maturation signatures is central to the long-standing quest to break tolerance mimicked by malignant tumours or re-establish immune homeostasis in allergic or autoimmune disorders.
No abstract avDendritic cells (DC) are the most important antigen presenting cells and play a pivotal role in host immunity to infectious agents by acting as a bridge between the innate and adaptive immune systems. Monocyte-derived immature DCs (iDC) were infected with viable resting conidia of Aspergillus fumigatus (Af293) for 12 hours at an MOI of 5; cells were sampled every three hours. RNA was extracted from both organisms at each time point and hybridised to microarrays. iDC cell death increased at 6 h in the presence of A. fumigatus which coincided with fungal germ tube emergence; .80% of conidia were associated with iDC. Over the time course A. fumigatus differentially regulated 210 genes, FunCat analysis indicated significant up-regulation of genes involved in fermentation, drug transport, pathogenesis and response to oxidative stress. Genes related to cytotoxicity were differentially regulated but the gliotoxin biosynthesis genes were down regulated over the time course, while Aspf1 was up-regulated at 9 h and 12 h. There was an up-regulation of genes in the subtelomeric regions of the genome as the interaction progressed. The genes up-regulated by iDC in the presence of A. fumigatus indicated that they were producing a pro-inflammatory response which was consistent with previous transcriptome studies of iDC interacting with A. fumigatus germ tubes. This study shows that A. fumigatus adapts to phagocytosis by iDCs by utilising genes that allow it to survive the interaction rather than just up-regulation of specific virulence genes.