Refine
Year of publication
Document Type
- Article (33)
- Doctoral Thesis (19)
Language
- English (52) (remove)
Is part of the Bibliography
- no (52)
Keywords
- - (26)
- Staphylococcus aureus (10)
- <i>Staphylococcus aureus</i> (4)
- IgE (4)
- JSNZ (3)
- allergy (3)
- vaccine (3)
- Antibody response (2)
- Antikörper (2)
- COVID-19 (2)
Institute
- Institut für Immunologie u. Transfusionsmedizin - Abteilung Immunologie (52) (remove)
Publisher
- MDPI (12)
- Frontiers Media S.A. (10)
- S. Karger AG (5)
- Wiley (3)
- AO Research Institute Davos (1)
- American Society for Microbiology (ASM) (1)
- BMJ Publishing Group (1)
Challenge of immunized mice with H. pylori induces protective gastric inflammation that is histologically indistinguishable from chronic H. pylori-associated gastritis in non-immune mice. To identify mechanisms of protective immunity gene expression in the gastric tissue from infected mice and mice vaccinated prior to challenge was compared by DNA array analysis. Message RNA was used to screen over 10,000 murine genes. Major Histocompatibility Complex antigens and IFN-γ dependent GTP binding proteins were strongly upregulated in both infected and immunized/challenged mice compared to naive controls. Differences in gene expression were also observed in novel T cell genes, which were exclusively upregulated in immunized/challenged mice. Both IFN I and II associated genes like the IFN-a/ßreceptor or IFN dependent transcription factors mIRF-1 and ISGF3 were also predominantly expressed in this group. These results were confirmed for several candidate genes by semi-quantitative RT-PCR. Additionally, H. pylori-stimulation of CD4+ T cells from immune mice induced significantly more IFN-γ production than stimulation of cells from infected mice. The present study provides evidence that the inflammatory infiltrate that arises in the gastric mucosa when immunized mice are challenged with H. pylori is associated with specific T cells sets and protein families that are distinct from those present in Helicobacter-associated chronic inflammation. Gene array profiles and in vitro assays indicate that immunized mice are more readily poised than infected mice to promote IFN-γ production and IFN related events and thus promote a strong proinflammatory THi response. This study supports recent findings that an immune response dominated by THi cytokines is essential for protection from H. pylori infection. This insight could facilitate the choice of the appropriate adjuvants for the development of vaccines against H. pylori, which are efficient and safe for use in humans. The mechanisms by which THi cells induce protective immunity or reduce Helicobacter colonization remain poorly understood and will be subject of future research.
Expression of the T cell regulatory molecule ICOS (CD278) and LICOS (CD275) on human blood cells
(2006)
Expression of the T cell regulatory molecule ICOS (CD278) and LICOS (CD275) on human blood cells Summary General bacterial infections, which can lead to the clinical picture of sepsis, are a major concern in intensive care units (ICU) and mortality remains high. Recent data have shown that, besides an overreaction of the immune system, also immunosuppression also plays a role in the pathogenesis of sepsis. Immunosuppression has been documented in patients with polytrauma, stroke and burn wounds, which all confer a high risk of severe bacterial infection. Moreover, it has been shown that T cells have an important role in sepsis. A shift of a Th1 dominated T cell response towards a Th2 response has been described as a potential mechanism of immune suppression in patients with sepsis. One of the molecules on the surface of T cells that is involved in the Th2-mediated immune response is the Inducible Costimulator of T cells (ICOS). Its ligand, LICOS, is expressed on the surface of B cells and monocytes. ICOS ligation induces the production of anti-inflammatory cytokines, especially of IL-10. However, nothing is known about the expression of ICOS on T cells and that of LICOS on APCs in patients with severe trauma and stroke. Therefore, in the present study, in a first step, a recombinant human LICOS-Ig fusion protein was generated, which was then used as an antigen for the generation of anti-LICOS monoclonal antibodies. In three fusion experiments, 5,000 primay clones were screened and a single hybridoma was obtained, which produced monoclonal antibodies that specifically reacted with recombinant LICOS, both in form of the LICOS-Ig fusion protein and on the surface of a cell line transfected with a full-length LICOS transgene. Since, it turned out that the antibodies did not bind with high affinity to wild type LICOS, as it is expressed on primary human blood cells, phenotypic analyses were carried out with another anti-LICOS monoclonal antibody, which had become commercially available. Next, the expression of HLA-DR, CD86, LICOS, and ICOS, on the surface of monocytes (CD14+), B cells (CD19+) and T cells (CD3+, CD4+) in whole blood was measured by flow cytometry. Six patients with severe trauma and nine stroke patients were compared with 32 healthy donors. On CD14+ monocytes from healthy donors, the expression levels of HLA-DR and CD86 were over 90%, while the expression of LICOS was much lower (7,5%). In critically ill patients, HLA-DR, CD86 and LICOS expression were strongly reduced. CD86 and HLA-DR were co-regulated, while HLA-DR and LICOS were not. In healthy donors, virtually all B cells expressed HLA-DR and the majority of them co-expressed LICOS (72%), while only a small fraction were CD86+ (14%). After trauma and stroke, HLA-DR, as well as LICOS expression on these cells remained normal; CD86 had a tendency towards being downregulated in most of the trauma patients, while most of the stroke patients exhibited normal CD86+ levels. The levels of HLA-DR and LICOS on T cells in trauma and stroke patients were low and very similar to those of healthy donors. The fraction of CD3+ T lymphocytes or their CD4+ subpopulation, which expressed measurable levels of ICOS (64% and 48%, respectively), did not change after stoke or trauma. However, within the ICOS+ T cell population two subpopulations could be distinguished: ICOSbright and ICOSdim T cells. Interestingly, the ICOSbright subpopulation, but not the ICOSdim and ICOSnegative subpopulations, was markedly increased in all trauma patients and in most of the stroke patients. Given that CD86 was co-regulated with HLA-DR on monocytes it appears that, similar to HLA-DR, CD86 expression could discriminate between patients with a low and high risk of sepsis. In contrast, because of its low basal expression on monocytes and its low signal-noise ratio, LICOS expression levels are not informative. Since ICOS expression on T cells is tightly connected to IL-10 secretion, the high proportion of ICOS bright cells in critically ill patients might contribute to the high IL-10 serum concentrations, which have been reported to be linked to immunosuppression in these patients.
SUMMARY To date, Staphylococcus aureus is the most common cause of nosocomial infections and the species is becoming increasingly resistant to antibiotics. Beyond this, S. aureus colonises the nasal mucosa of circa 35% of the healthy population, so-called carriers. Importantly, S. aureus nasal carriage is a major risk factor for the development of S. aureus infections, which are commonly caused by the colonising strain. This underlines the importance of host factors for the outcome of S. aureus-host interactions. Despite the clinical importance of nasal carriage, little is known about humoral immune responses triggered by colonisation. Therefore, this thesis was focussed on the anti-staphylococcal antibody responses of S. aureus carriers and noncarriers. Staphylococcal superantigens (SAgs) served as indicator antigens for our studies. SAgs are virulence factors with extraordinary variability in the species S aureus and act as extremely potent T cell mitogens. To date, 19 different SAg gene loci are known in the species S. aureus, but molecular-epidemiological studies on the distribution of these genes are limited. Therefore, we established five multiplex PCRs for the detection of all known SAgs. With this robust and high-throughput technique we analysed the SAg gene patterns of more than 300 isolates, including 107 nasal isolates of S. aureus carriers and 88 blood culture isolates of hospital patients from Western Pomerania. The SAg gene patterns were highly heterogeneous, which can be explained by their localisation on mobile genetic elements (MGE), such as genomic islands, pathogenicity islands, phages and plasmids. Most isolates (~80%) harboured SAg genes, on average five to six, and SAgs of the enterotoxin gene cluster (egc) were by far the most prevalent. Additionally, we observed a strict correlation between the presence of SAg genes and the T cell mitogenic potency of clinical isolates. SAg-encoding MGEs can be distributed by two distinct mechanisms: horizontal transfer by bacteriophages and vertical transmission to daughter cells. To investigate the distribution of SAg genes within the S. aureus population, we determined the clonal relationship of our isolates by spa genotyping. Interestingly, SAg-gene encoding MGEs were not randomly distributed, but rather closely linked to clonal lineages. Each clonal lineage was characterised by defined combinations of SAg genes. These data suggest that the simultaneous assessment of virulence gene profiles and the genetic background strongly enhances the discriminatory power of genetic investigations into the mechanisms of S. aureus virulence. Indeed, the comparison of virulence genes within each clonal complex indicated a role in invasiveness for some MGEs, e.g. the exfoliative toxin D-encoding pathogenicity island, while rendering it unlikely for SAgs. It is known that neutralising serum antibodies against the SAgs SEA, SEB, SEC, SED and TSST-1 are frequently present in healthy individuals. However, the neutralising antibody profiles against more recently described SAgs or complex SAg cocktails as secreted by clinical isolates had not been determined so far. Therefore, we screened more than 100 sera for their SAg neutralising capacity with a neutralisation assay. We observed a marked heterogeneity and surprisingly large “gaps” in the neutralising capacity. Interestingly, the egc SAgs were inhibited only rarely (5-10%), whereas between 32 and 86% of the tested sera neutralised “classical” SAgs. This “egc gap” in the SAg-neutralising antibody profiles of healthy individuals was unexpected, since egc SAgs are by far the most prevalent SAgs. We could demonstrate that the “egc gap” is probably not due to different T cell activating properties of egc SAgs compared to classical SAgs, but rather to a differential regulation of SAg gene expression. S. aureus carriers have an increased risk of developing an S. aureus bacteraemia, which is in most cases caused by the colonising strain. Intriguingly, a large prospective clinical trial revealed a considerably higher mortality in noncarriers with invasive S. aureus strains compared to carriers with invasive disease. To explain these paradoxical findings, we hypothesised that in carriers partial immunity against the colonising strain may contribute to their improved outcome. We used SAgs as strain-specific indicator antigens. Importantly, sera from persistent carriers neutralised SAgs of their colonising strain with significantly higher efficiency than sera from noncarriers. This antibody response was strain-specific, since the antibody response of carriers against other SAgs did not differ from that of noncarriers. Thus, colonisation with S. aureus confers a strong and strain-specific antibody response against staphylococcal SAgs. We suggest that in carriers neutralising antibodies directed against SAgs and other staphylococcal virulence factors confer partial protection during systemic infections. This could explain the better prognosis of carriers with S. aureus bacteraemia compared to noncarriers. Moreover, our data imply that the key to understanding the pathogenesis of S. aureus disease may lie in the identification of host factors rather than bacterial factors. Such host factors could be the immune status and gene polymorphisms that contribute to colonisation, susceptibility to infection and outcome of infection. Finally, while the treatment of S. aureus bacteraemia with pooled immunoglobulins was performed in the past without significant success, our findings on strain-specific antibody profiles suggest that therapies with customised cocktails of monoclonal antibodies could have a higher efficacy.
Pretransplant Tolerance Induction Reduces the Islet Mass Required to Reverse Diabetes in NOD Mice
(2007)
Islet transplantation can restore normoglycemia in diabetic patients. However, its application is limited by the high number of islets required to reverse diabetes. As the mass and potency of most human islet preparations are marginal, a large impact on the applicability of islet transplantation is expected from the implementation of strategies that improve engraftment of these islet preparations. The roles of adaptive immunity and immunosuppression on islet engraftment are not well studied. Therefore, the effects of currently used immunosuppression with antilymphocyte serum, tacrolimus and sirolimus on islet engraftment were separated from their impact on immunity and diabetes reversal rates were compared after islet allotransplantation in immunosuppressed and chimeric, non-immunosuppressed NOD mice. Both strategies prevented rejection of islet allografts and reduced the frequency of donor-specific, IFN-gamma-secreting T cells. However, in order to achieve stable diabetes reversal with a probability of about 80% after islet allotransplantation in diabetic NOD mice, a fourfold higher islet mass (400 islets) was required in immunosuppressed recipients, compared with non-immunosuppressed recipients made tolerant pretransplant by induction of mixed hematopoietic chimerism (100 islets). The failure of immunosuppressed mice to become normoglycemic after low-dose islet transplantation primarily resulted from the inhibitory effects of tacrolimus combined with sirolimus on islet engraftment and not from the inhibitory effects of this combination on islet graft function. These data suggest that immunotherapeutic strategies that control adaptive immunity without interfering with islet neovascularization or other processes critical to islet engraftment are likely to improve the success rate of marginal mass human islet allografts.
The human antibody response to experimental colonization with Staphylococcus aureus NCTC8325-4
(2008)
The four main work packages and their most important results are briefly described as following. 1. Characterization of the extracellular proteome of S. aureus NCTC8325-4 Reference maps of the extracellular proteins of S. aureus NCTC8325-4 were produced at pH ranges 6-11 and 4-7. In total, 119 (pH 6-11) and 177 (pH 4-7) protein spots were identified, corresponding to 48 and 114 proteins, respectively. Among them were many well-known virulence factors such as alpha-hemolysin (Hla), beta-hemolysin Hlb, gamma-hemolysin subunits (HlgA-C), hyaluronate lyase (HysA) and staphylococcal superantigen-like protein 11 (Ssl11). We also detected various extracellular enzymes, which can cause tissue degradation and are involved in nutrient acquisition, for example, autolysin (Atl), glycerol ester hydrolase (Geh), lipase (Lip), thermonuclease (Nuc), several serine proteases SplA-F (SplA-F), V8 protease (SspA), cysteine protease (SspB), staphopain thiol proteinase (88195808, SspP). Many of these proteins probably also contribute to the virulence of S. aureus. 2. Optimization of a 2-D immunoblot (IB) method for the comprehensive investigation of IgG binding to S. aureus extracellular proteins (strain NCTC8325-4) The immune proteome of S. aureus NCTC8325-4 was revealed by probing 2-D blots of S. aureus extracellular proteins at the two pH ranges 6-11 and 4-7 with a pool of sera from 16 volunteers. IgG binding was detected with high sensitivity using a peroxidase-coupled secondary Ab in combination with an ECL-substrate. With application of the software package Delta2D, we could clearly define 66 immune reactive spots on the immunoblots (IBs) of pH range 6-11 and 38 spots on IBs of pH range 4-7. 72 of these 104 immune reactive spots could be identified by matching the IBs with the protein reference maps. These spots represented 36 identified proteins, many of which are known virulence factors, or they are involved in bacterial cell wall biosynthesis and degradation. Generally, the most abundant proteins were also highly immune reactive, but there was no strict correlation between protein abundance and immune reactivity. Some low abundance proteins, especially basic proteins, showed high immune reactivity on 2-D IBs, for example, Atl, 88195808 (SspP) and iron-regulated surface determinant protein A (IsdA). On the other hand, we observed proteins, which were present in large amounts but did not bind IgG such as peptidoglycan hydrolase (LytM) and a hypothetical protein 88193909 (SAOUHSC_00094). 3. Determination of the anti-staphylococcal Ab profiles of S. aureus carriers and noncarriers Comparing the serum IgG binding patterns of sera from the 16 individual volunteers, we observed pronounced heterogeneity in total IgG binding, spot patterns and spot intensities. Five spots were stronger in carriers than in noncarriers (P< 0.05, Mann-Whitney U test). These spots represent IgG binding to SspA, SspB, IsaA, and two hypothetical proteins. A principal component analysis based on differential IgG binding to these spots showed that the carriers were more closely related to each other than the noncarriers, but that they could not be clearly separated from the noncarriers. 4. Does experimental colonization induce changes of the anti-staphylococcal Ab profiles? Finally, we tested whether symptom-free experimental colonization of the 16 volunteers with S. aureus NCTC8325-4 elicited an IgG response. When we compared sera obtained before colonization with those taken 4 weeks after the inoculation with the laboratory S. aureus strain, we did not observe major changes in the Ab patterns. We conclude that short- term colonization with a strain of low virulence does not suffice to induce an Ab production, which is comparable to that present already before the colonization. Thus, either long term high density colonization is required, or as we consider most likely, the adaptive immune response is primarily triggered by (minor) S. aureus infections. Taken together, in this work we have separated the soluble proteins from complex extracellular S. aureus protein extracts with good reproducibility, large coverage (pH 6-11 and 4-7) and high resolution. With application of an ECL substrate, our 2-D immunoblotting procedure resulted in the highly sensitive detection of IgG binding over a wide range of signal intensities. The most important finding with this technique was the pronounced variability of anti-staphylococcal Ab profiles in healthy adults. This could well explain differences in susceptibility to S. aureus infection and its complications. The Ab responses are presumably triggered by long-term colonization or, more likely, by minor infections with S. aureus, since experimental nasal colonization of healthy volunteers with a bacterial strain of low virulence did not induce impressive changes in the Ab profiles.
Effect of surgical intervention on the activation status of circulating monocytes and T-cells
(2009)
Major surgery causes alterations in immune function which results in immune suppression in post surgical patients. Deactivation of monocytes in these patients is characterised by the reduced ability of these cells to produce pro-inflammatory cytokines on stimulation with LPS in vitro and by markedly reduced HLA-DR expression. Immune suppression in patients with systemic inflammation has also been associated with a high level of apoptosis in both the circulating T and B cell populations. In addition post surgical T cells have a reduced capacity to proliferate ex vivo in response to co-ligation of the T cell receptor and CD-28. Considering these impairments of immune system, this study aimed to define the extent of immune modulation in both innate and adaptive system in a cohort of surgical patients. Measurment of the level of HLA-DR expression of monocytes in these patients showed a considerable change in monocyte phenotype in the immediate post operative period. In line with previous work, all patients showed a considerable reduction in monocytic surface HLA-DR expression which persisted for many hours and those who had post surgical septic complications showed the most severe reduction. Importantly, patients with minor surgical intervention also exhibited decreased HLA-DR expression. Gene expression analysis of monocyte in these patients showed the up-regulated transcripts of genes involved in extravasation and realignment of the cytoskeleton. Analysis of periperal T cell demonstrated a significant reduction in their number in the circulation and a sharp raise in the number of apoptotic T –cells in the immediate post surgical period. Microarray analysis of T cells from patients who developed sepsis and patients with an uneventful recovery within the post-operative period (3 days) showed a substantial reduction in the transcriptional activity of many genes in both groups. However, this down regulation of T cell transcriptional activity appears to be a rather broad and non specific effect since it is not restricted to particular functional pathways. Real time PCR analysis of both the CD4+ and CD8+ populations using selected down-regulated genes showed that the change in transcriptional profile is equally evident both in CD4+ and CD8+ T-cells. The cause of this transient immune depression following surgery remains to be established and it may represent an important enabling factor which contributes to the development of post surgical infections and inflammatory complications.
Staphylococcus (S.) aureus is the most common cause of nosocomial infections and the species is becoming increasingly resistant to antibiotics. In contrast, about 35% of the healthy population are colonized with S. aureus in the anterior nares. The genetic make-up of this species is highly diverse. Mobile genetic elements comprise about 15% of the S. aureus genome. They encode many virulence factors like the 21 different known staphylococcal superantigens (SAgs), highly potent activators of T lymphocytes. Besides their well known causative role in food poisoning and toxic shock syndrome, information about SAg involvement in pathogenesis is limited. On the other hand, the human host and its immune response are also highly diverse. This study focuses on SAgs, because they are potent virulence factors that are highly diverse and therefore mirror of the variability of the species S. aureus. The goals of this work were (i) to identify virulence determinants by comparing the prevalence of SAg genes and phages among colonizing and invasive S. aureus isolates and to correlate it with the clonal background, (ii) to determine the prevalence and the development of anti-SAg antibodies in healthy S. aureus carriers and noncarriers as well as in bacteremia patients, and (iii) to elucidate the reasons for the selective lack of neutralizing serum antibodies specific for a subgroup of SAgs, the egc SAgs. In search for a molecular-epidemiological associations between SAgs and different diseases caused by S. aureus we investigated the distribution of SAg genes and/ or bacteriophages and correlated this with the clonal background, determined by spa genotyping. The analysis of more than 700 S. aureus isolates from nasal colonization, bacteremia or furunculosis revealed that SAg-encoding mobile genetic elements and bacteriophages were strongly associated with the clonal background. As a consequence, each clonal lineage was characterized by a typical SAg gene and phage repertoire. Therefore, we suggest that the simultaneous assessment of virulence gene profiles and the genetic background strongly increases the discriminatory power of genetic investigations into the mechanisms of S. aureus pathogenesis. However, we found no association of SAg genes with bacteremia or furunculosis. While functional neutralization assays closely mimic the protective action of anti-SAg antibodies in vivo, they are labor-intensive and time-consuming. A fast and easy method for the simultaneous quantification of antibody binding to multiple staphylococcal antigens is the Luminex® technology. Using serum samples from persistent carriers and noncarriers we showed a strong correlation between antibody binding and neutralizing capacity against the SAg TSST-1. This assay confirmed the astonishing lack of antibodies against egc SAgs in healthy carriers and noncarriers, which was previously described by Holtfreter and coworkers. Since colonization is probably not sufficient to induce a robust antibody response as revealed by experimental colonization with S. aureus, we propose that (minor) infections are required to induce the high titers of non-egc SAg-neutralizing antibodies in healthy adults. To test this, we investigated whether SAgs elicit a neutralizing antibody response during S. aureus bacteremia. At the acute phase of the disease most patients already had neutralizing antibodies against non-egc SAgs, and antibody titers frequently increased during infection. Notably, egc SAgs did not elicit a boost or de novo generation of specific antibodies. The “egc gap” in the antibody response, which has now been shown in healthy adults, as well as following systemic infection with S. aureus, is astonishing. After all, egc SAgs are by far the most prevalent SAgs. In search for an explanation, the intrinsic properties of three recombinant egc (SEI, SElM, SElO) and non-egc SAgs (SEB, SElQ, TSST-1) were compared in depth. Egc and non-egc SAgs were very similar with regard to induced T cell proliferation, cytokine profiles, and gene expression of human immune cells. However, there was a striking difference in the regulation of the two groups of SAgs by S. aureus in bacterial culture. We conclude that the differential regulation of egc and non-egc SAg has an impact on the immune response. But how are SAgs regulated by S. aureus during its interaction with the host? Up until now most research on regulation of virulence factors has been performed in vitro. The immune response can help to shed light on this problem, because it is an exquisitely specific sensor for the exposure to different antigens. The high prevalence of neutralizing serum antibodies against non-egc SAgs indicates that most healthy adults have been exposed to these toxins during their encounters with S. aureus. For egc SAgs this remains an open question. However, initial data indicate that the egc SAg genes are transcribed during nasal colonization.
Postoperative Immune Suppression in Visceral Surgery: Characterisation of an Intestinal Mouse Model
(2011)
Background: Postoperatively acquired immune dysfunction is associated with a higher mortality rate in case of septic complications. As details of this severe clinical problem are still unknown, animal models are essential to characterise the mechanisms involved. Methods: Mice were laparotomised and the small intestine was pressed smoothly in antegrade direction. For extension of trauma, the intestine was manipulated three times consecutively. Following this, the ex vivo cytokine release of splenocytes was determined. The degree of surgical trauma was analysed by detection of HMGB1 and IL-6 in serum and by neutrophil staining in the muscularis mucosae. Results: We adapted the previously described animal model of intestinal manipulation to provide a model of surgically induced immune dysfunction. Following intestinal manipulation, the mice showed elevated serum levels of HMGB1 and IL-6 and increased infiltration of granulocytes into the muscularis mucosae. Ex vivo cytokine release by splenocytes was suppressed in the postoperative period. The degree of suppression correlated with the extent of surgical trauma. Conclusions: In this study, we describe a surgically induced immune dysfunction animal model, in which a significant surgical trauma is followed by an immune dysfunction. This model may be ideal for the characterisation of the postoperative immune dysfunction syndrome.
IL-10 drives the re-establishment of peritoneal macrophage populations in bacterial peritonitis
(2011)
The aim of this thesis work was to explore the physiological and functional properties of peritoneal macrophage populations in both the steady state and in inflammatory conditions. In the steady state there are two populations of macrophages in the peritoneum which I refer to as the R1 and R2 populations. The R1 cells are a rapidly turning over population which constitute around 20% of the peritoneal macrophages. I show that these cells have the capacity to efficiently present peptides on MHC-II to CD4+ T cells but that they are poor at phagocytosis. Monocytes transferred into the un-infected peritoneum give rise almost exclusively to this R1 population, suggesting that the R1 fate is the default pathway of monocyte development under steady state conditions. In contrast, the R2 population in the peritoneum turns over very slowly in the steady state and is composed of cells which are poor at the presentation of peptide to T cells but which are efficient at phagocytosis. Both of these populations are lost from the peritoneum within an hour of the induction of a poly-microbial peritonitis. A large fraction of the R2 population relocates from the peritoneal wash fraction to the omentum, the fate of the R1 population is less clear. Over the course of the next three days, the macrophage populations in the peritoneum are re-established. Transfer experiments using genetically marked cell populations demonstrated that neither the R1 nor the R2 populations which “disappeared” one hour after infection contributes to the re-established peritoneal wash fraction macrophage pool at day 3. While the re-established R1 population retains the functional properties and the FACS phenotype of the steady state R1 cells, the re-established R2-like population is clearly not identical to the R2 cells present in the pre-infection environment. In particular, this R2-like population can be split into two sub-populations which have non-identical functional properties. In this inflammatory situation monocytes transferred into the peritoneum now acquire the capacity to differentiate not only into R1-like cells but also into R2-like macrophages. I looked for the molecular basis driving this change of monocyte differentiation in the infected peritoneum by using a solid phase cytometry based ELISA procedure to examine the spectrum of cytokines produced in the peritoneum in response to poly-microbial infection. One of the most prominent cytokines produced early in infection is IL-10. To determine whether IL-10 is directly involved in assigning monocyte fate in the peritoneum I looked at the ability of mice carrying a targeted deficiency of either the IL-10 gene or of the IL-10 receptor gene to form the R2-like cells after infection. Neither mouse strain efficiently generates the R2-like population after infection. Adoptive transfer of genetically marked wild type or mutant monocytes into appropriate hosts demonstrated that the effect of IL-10 is not direct. Rather, the IL-10 responding cell produces a mediator which then directs monocyte fate. Thus, the bystander IL-10R deficient monocytes are driven by the mediator produced by wild type monocytes to generate R2 cells with high efficiency. The crucial role of this IL-10 dependent pathway was underscored by supplementation experiments. Mice carrying a targeted deficiency of the IL-10 gene fail to generate the R2 population during peritonitis. However, injection of IL-10 into these animals rescues the capacity to form the R2 population. In addition the normal default pathway of monocyte development in un-infected animals which leads to the R1 population is modulated by injection of IL-10 so that the monocytes can now differentiate into the R2 population. The work presented in this thesis describes the steady state populations of phagocytes in the un-infected peritoneum and the dynamics of these populations during the induction of peritonitis. It also uncovers an IL-10 dependent pathway which regulates the choice of monocyte developmental fate within the peritoneum.
Inflammation is an adaptive response that is triggered by noxious stimuli and conditions, such as infection and tissue injury. Neutrophils, eosinophils, monocytes, tissue macrophages and dendritic cells can all ingest bacteria, tissues debris and apoptotic cells after injury or infection. These cells derived from bone marrow progenitors, circulate in the blood and migrate to peripheral tissues. Macrophages produce and secrete a cascade of pro-inflammatory and anti-inflammatory cytokines, such as interleukin-6 (IL-6), IL-10, and IL-12 that are trafficked and secreted by constitutive exocytosis. IL-10 and IL-6 are known to be rapidly induced during infection and / or injury, which make them possible mediators of early phagocyte recruitment. This thesis work aimed at detailed investigation of role of these cytokines in peritoneal inflammation. Under normal physiological conditions peritoneal cavity of normal BALB/c mice contains mainly CD45+ lymphocytes and CD11b+ myeloid cells with typical macrophage phenotype. The resident peritoneal cells play an important role in organismal homeostasis by taking part in innate and adaptive immunity. To explore this in detail, the physiological properties of peritoneal resident macrophage populations were studied under steady state and during inflammation conditions. Upon rapid induction of sterile inflammation by thioglycollate or lipopolysaccharide, the resident peritoneal cells could no longer be recovered in a peritoneal wash 6h after treatment. During ceacal content (CC) peritonitis, these cells were lost even more rapidly. Neutrophils, monocytes and lymphocytes replace the resident peritoneal phagocyte populations. During sepsis the absence of peritoneal macrophages decreases neutrophils recruitment to the inflammatory site and subsequently increases sepsis. Upon peritoneal wash cell transfer, total peritoneal cells could be recovered from the peritoneum of non infected mice, whereas these cells disappeared after CC infection in mice. The fate of resident peritoneal cells and their migration into lymphoid organs such as omentum and parathymic lymph nodes was further studied following induction of peritoneal infection. The CC infection induced lost cells from peritoneum were emigrated into omentum and parathymic lymph nodes but not in mesenteric lymph nodes. R1 cells were mostly observed in parathymic lymph nodes after 72h of infection but not after 1h, whereas, R2 cells were selectively observed in omentum just 1h after infection and 72h as well. These results were further confirmed by adoptive transfer showing emigration of R2 cells into omentum 1h after infection. Additionally, analysis of cytokine production after CC peritonitis showed early production of IL-10 and IL-6, which is in agreement with earlier findings and further supports the importance of these cytokines in phagocyte recruitment. The role of IL-10, IL-6 and other cytokines as possible mediators of early inflammation and in the recruitment of monocytes, neutrophils or eosinophils to the peritoneum during inflammation was determined by cytokine application. The intraperitoneal application of IL-10 recruited monocytes, neutrophils, T cells, B cells and eosinophils to the peritoneum. However, IL-10 knockout mice showed even increased recruitment of leucocytes to the peritoneal cavity in CC infection suggesting their IL-10 independent recruitment with the exception of eosinophils. Even though eosinophils are effector cells which are recruited to the site of inflammation; during homeostasis eosinophils constitute an abundant leukocyte population in the gastrointestinal tract. Therefore, possible role of eosinophils in bacterial infection was further studied using Δdbl GATA mice which lack mature eosinophils. In the absence of eosinophils, the monocyte and neutrophil recruitment was unaffected after CC infection, while there was increased T and B cell recruitment at the same time. The Δdbl GATA mice also showed reduced production of IL-4, 18h after infection. The eosinophils secrete IL 4 which may induce alternative macrophage activation. These results together with cytokine administration and IL-10 ko mouse data suggest a novel and major role of IL-10 in attracting and in recruiting eosinophils after peritoneal infection. Altogether, present thesis work demonstrates a new aspect of IL-10 interaction with eosinophils in mouse peritoneal environment during peritonitis. It gives a new insight for understanding the possible role of eosinophils in modulating the peritoneal environment in resolution of bacterial infection and can be useful in designing new approaches for therapeutic strategies in combating sepsis and peritoneal inflammation.