Identification of a novel agrin-dependent pathway in cell signaling and adhesion within the erythroid niche.

Establishment of cell-cell adhesion is crucial in embryonic development as well as within the stem cell niches of an adult. Adhesion between macrophages and erythroblasts is required for the formation of erythroblastic islands, specialized niches where erythroblasts proliferate and differentiate to produce red blood cells throughout life. The Eph family is the largest known family of receptor tyrosine kinases (RTKs) and controls cell adhesion, migration, invasion and morphology by modulating integrin and adhesion molecule activity and by modifying the actin cytoskeleton. Here, we identify the proteoglycan agrin as a novel regulator of Eph receptor signaling and characterize a novel mechanism controlling cell-cell adhesion and red cell development within the erythroid niche. We demonstrate that agrin induces clustering and activation of EphB1 receptors on developing erythroblasts, leading to the activation of α5ß1 integrins. In agreement, agrin knockout mice display severe anemia owing to defective adhesion to macrophages and impaired maturation of erythroid cells. These results position agrin-EphB1 as a novel key signaling couple regulating cell adhesion and erythropoiesis.

Mouse mesenchymal stem cells inhibit high endothelial cell activation and lymphocyte homing to lymph nodes by releasing TIMP-1.

Mesenchymal stem cells (MSC) represent a promising therapeutic approach in many diseases in view of their potent immunomodulatory properties, which are only partially understood. Here, we show that the endothelium is a specific and key target of MSC during immunity and inflammation. In mice, MSC inhibit activation and proliferation of endothelial cells in remote inflamed lymph nodes (LNs), affect elongation and arborization of high endothelial venules (HEVs) and inhibit T-cell homing. The proteomic analysis of the MSC secretome identified the tissue inhibitor of metalloproteinase-1 (TIMP-1) as a potential effector molecule responsible for the anti-angiogenic properties of MSC. Both in vitro and in vivo, TIMP-1 activity is responsible for the anti-angiogenic effects of MSC, and increasing TIMP-1 concentrations delivered by an Adeno Associated Virus (AAV) vector recapitulates the effects of MSC transplantation on draining LNs. Thus, this study discovers a new and highly efficient general mechanism through which MSC tune down immunity and inflammation, identifies TIMP-1 as a novel biomarker of MSC-based therapy and opens the gate to new therapeutic approaches of inflammatory diseases.

Factors influencing cross-presentation of non-self antigens expressed from recombinant adeno-associated virus vectors.

BACKGROUND: We have previously demonstrated that recombinant adeno-associated virus vectors expressing the influenza virus hemagglutinin (rAAV-HA) in skeletal muscle results in T-cell priming and muscle fiber destruction due to cross-presentation of HA by dendritic cells (DC). Based on controversial observations concerning the stability of non-self proteins expressed from rAAV vectors it is important to understand the factors influencing cross-presentation of transgene products following rAAV mediated gene transfer, in order to be able to use this vector safely in the clinic. METHODS: In order to understand the factors influencing in vivo cross-presentation of non-self proteins, we have retargeted the immunogenic lacZ protein in the context of rAAV from the cytoplasm to the cell surface and studied the activation of LacZ specific immune responses following intramuscular mediated gene transfer. In addition, using tools available for studying in vitro HA-specific T-cell activation, our aim was to identify the cell types involved in class I and class II restricted cross-presentation as well as the nature of the cross-presented material. RESULTS: By retargeting the lacZ protein in the context of rAAV to the cell membrane, we found that one of the factors influencing the efficiency of cross-presentation of non-self antigens is the localization of the transgene product within the target cells. Following rAAV-LacZ mediated gene transfer to the muscle we demonstrated that the membrane-bound form of LacZ resulted in target cell destruction, which is in stark contrast to the stability observed with rAAV-LacZ vectors expressing the cytoplasmic form of LacZ. Using an in vitro assay, we were able to show that dendritic cells (DC) in addition to B-cells cross-presented HA to class II restricted T-cells whereas only the former were able to activate class I restricted CD8+ T-cells. High-dose antigens were needed for efficient class I restricted T-cell priming, whereas class II restricted T-cells were activated by less antigen. CONCLUSION: The present results indicate that immune responses to non-self antigens expressed from rAAV vectors depend on the accessibility of such antigens to different local antigen-presenting cells.

Regulatory function of in vivo anergized CD4(+) T cells.

It has been suggested that anergic T cells may not be only inert cells but may rather play an active role, for example by regulating immune responses. We have previously reported the existence of "anergic" IL-10-producing CD4(+) T cells generated in vivo by continuous antigenic stimulation. Using a gene transfer system where the antigen recognized by such T cells is expressed in skeletal muscle by two different DNA viral vectors, we show that these cells not only remain tolerant toward their cognate antigen but also can suppress the immune response of naive T cells against the immunogenic adenoviral proteins. Furthermore, they can completely inhibit tissue destruction that takes place as a result of an immune response. The system presented here is unique in that the T cells have been anergized in vivo, their antigen specificity and functional status are known, and the amount, form, and timing of antigen expression can be manipulated. This model will therefore permit us to carefully dissect the mechanisms by which these anergic T cells regulate the priming and/or effector function of naive T cells.

Fingerprints of anergic T cells.

Peripheral T cell tolerance may result from activation-induced cell death [1], anergy [1], and/or immune response modulation by regulatory T cells [2]. In mice that express a transgenic receptor specific for peptide 111-119 of influenza hemagglutinin presented by E(d) class II MHC molecules as well as hemagglutinin under control of the immunoglobulin-kappa promoter, we have found that anergic T cells [3] can also have immunoregulatory function and secrete IL-10 [4]. In order to obtain information on molecular mechanisms involved in anergy and immunoregulation, we have compared expression levels of 1176 genes in anergic, naive, and recently activated CD4+ T cells of the same specificity by gene array analysis. The results provide a plausible explanation for the anergic phenotype in terms of proliferation, provide new information on the surface phenotype of in vivo-generated anergic CD4+ T cells, and yield clues with regard to new candidate genes that may be responsible for the restricted cytokine production of in vivo-anergized CD4+ T cells. The molecular fingerprints of such T cells should enable the tracking of this small population in the normal organism and the study of their role in immunoregulation.

Successful interference with cellular immune responses to immunogenic proteins encoded by recombinant viral vectors.

Vectors derived from the adeno-associated virus (AAV) have been successfully used for the long-term expression of therapeutic genes in animal models and patients. One of the major advantages of these vectors is the absence of deleterious immune responses following gene transfer. However, AAV vectors, when used in vaccination studies, can result in efficient humoral and cellular responses against the transgene product. It is therefore important to understand the factors which influence the establishment of these immune responses in order to design safe and efficient procedures for AAV-based gene therapies. We have compared T-cell activation against a strongly immunogenic protein, the influenza virus hemagglutinin (HA), which is synthesized in skeletal muscle following gene transfer with an adenovirus (Ad) or an AAV vector. In both cases, cellular immune responses resulted in the elimination of transduced muscle fibers within 4 weeks. However, the kinetics of CD4(+) T-cell activation were markedly delayed when AAV vectors were used. Upon recombinant Ad (rAd) gene transfer, T cells were activated both by direct transduction of dendritic cells and by cross-presentation of the transgene product, while upon rAAV gene transfer T cells were only activated by the latter mechanism. These results suggested that activation of the immune system by the transgene product following rAAV-mediated gene transfer might be easier to control than that following rAd-mediated gene transfer. Therefore, we tested protocols aimed at interfering with either antigen presentation by blocking the CD40/CD40L pathway or with the T-cell response by inducing transgene-specific tolerance. Long-term expression of the AAV-HA was achieved in both cases, whereas immune responses against Ad-HA could not be prevented. These data clearly underline the importance of understanding the mechanisms by which vector-encoded proteins are recognized by the immune system in order to specifically interfere with them and to achieve safe and stable gene transfer in clinical trials.

Monitoring gene expression of TNFR family members by beta-cells during development of autoimmune diabetes.

Autoimmune diabetes results from destruction of pancreatic beta-cells by islet-infiltrating leukocytes. Different molecular mechanisms seem to be involved in this destruction but the results from many studies have not provided a clear picture so far. Therefore, we have developed a multiplex single-cell reverse transcription polymerase chain reaction to analyze the expression of genes of the tumor necrosis factor receptor (TNFR) family in pancreatic beta-cells during the development of autoimmune diabetes in a TCR-HA x INS-HA double transgenic as well as a non-obese diabetic (NOD) animal model. To this end we have followed the expression of cell surface receptors of the TNFR family in NOD mice as well as in double transgenic mice that express in their T cells class II MHC-restricted TCR specific for peptide 111 - 119 from influenza hemagglutinin (TCR-HA) as well as hemagglutinin under the control of the rat insulin promoter (INS-HA). Both types of mice develop insulitis and diabetes spontaneously. The data show a significant increase in the expression of Fas and TNFR2 (p75) during the development of insulitis, whereas TNFR1 (p55) is already expressed in beta-cells before the onset of insulitis. As ligands for these receptors are already expressed at high levels during the phase of insulitis, it is possible that beta-cell death is regulated by intracellular inhibitors of apoptosis pathways.

Autoimmune insulitis and diabetes in the absence of antigen-specific contact between T cells and islet beta-cells.

Autoimmune diabetes develops following recognition of organ-specific antigens by T cells. The disease begins with peri-islet infiltration by mononuclear cells, proceeds with insulitis and becomes manifest with destruction of insulin-producing islet beta-cells. T cells are necessary to induce insulitis and diabetes, but it is not clear by what mechanisms they can do so, i. e. whether the T cells need to make antigen-specific contact with the beta-cell or whether other interactions are sufficient to induce beta-cell death. In the present study we have constructed chimeric mice in which the bone marrow-derived antigen-presenting cells, but not the islet beta-cells, are capable of presenting antigen to monospecific T cells. We show that both insulitis as well as beta-cell destruction can proceed in the absence of islet beta-cell surface antigen recognition by T cells. Our results support the notion that diabetes can be caused by distinct effector mechanisms.

Allelic inclusion of T cell receptor alpha genes poses an autoimmune hazard due to low-level expression of autospecific receptors.

Organ-specific autoimmune disease can be caused by alphabeta T cells that have escaped self-tolerance induction. Here we show that one of the causes of escape from self-tolerance is the coexpression of two different T cell receptors by the same cell, which can occur in up to 30% of all T cells in normal mice and can lead to low-level surface expression of an autospecific TCR. We found that double receptor-expressing T cells can escape tolerance even to ubiquitously expressed antigens but can nevertheless induce autoimmune diabetes when the relevant protein is expressed in pancreatic tissue. Such diabetogenic T cells are absent, however, among T cells expressing the autospecific TCR as the sole receptor.

Modifications of CD8+ T cell function during in vivo memory or tolerance induction.

Naive monoclonal T cells specific for the male antigen can be stimulated in vivo to eliminate male cells and become memory cells or to permit survival of male cells and become tolerant. Memory cells responded to TCR ligation by cyclic oscillations of calcium levels and immediate secretion of very high levels of IL-2 and interferon-gamma. Tolerant cells did not proliferate in response to ionomycin and phorbol myristate acetate, failing to mobilize calcium to produce IL-2 or express IL-2R, but survived for long time periods in vivo and secreted IL-10. These results emphasize that tolerance is not an absence of all functional activity and may be associated with modifications of behavior conferring important regulatory functions on tolerant T cells.

Involvement of the Fas (CD95) system in peripheral cell death and lymphoid organ development.

Fas-mediated apoptosis is a form of cell death that operates through a Fas-Fas ligand (FasL) interaction. In this study we investigated the role of the Fas system during development of normal and Fas-mutated lymphocytes. Irradiated RAG2-/-recipients were reconstituted with bone marrow cells from B6 and lpr mice (Fas defective) or from B6 and gld mice (FasL defective), and analyzed for long-term development. The results showed a primary role of the Fas system in peripheral cell death and thymic colonization. In the periphery, the interaction in vivo between Fas+ and Fas-T cell populations indicated that cellular homeostasis was defective. Indeed, we observed a FasL-mediated cytotoxic effect on normal-derived T cells, explaining the dominance of lpr T cells in the mixed chimeras. The Fas mutation affected neither cell activation nor cell proliferation, as the effector (Fas-) and target (Fas+) cells behaved similarly with regard to activation marker expression and cell cycle status. However, Fas-T cells failed to seed the periphery and the thymus in the long term. We suggest that this could be due to the fact that FasL is involved in the structural organization of the lymphoid compartment.

Changes in function of antigen-specific lymphocytes correlating with progression towards diabetes in a transgenic model.

Mice that express influenza hemagglutinin under control of the rat insulin promoter (INS-HA) as well as a class II major histocompatibility complex (MHC)-restricted HA-specific transgenic TCR (TCR-HA), develop early insulitis with huge infiltrates, but progress late and irregularly to diabetes. Initially, in these mice, INS-HA modulates the reactivity of antigen-specific lymphocytes, such that outside the pancreas they do not cause lethal shock like their naive counterparts in single transgenic TCR-HA mice, when stimulated with high doses of antigen. Inside the pancreas, the antigen-specific cells do not initially attack the islet cells, and produce some IFN-gamma as well as IL-10 and IL-4. Spontaneous progression to diabetes, which can be accelerated by cyclophosphamide injection, is accompanied by a 10-fold increase in IFN-gamma and a 3-fold decrease in IL-10 and IL-4 production by the locally residing antigen-specific T cells. Also, total islets from non-diabetic mice contain more TNF-alpha, compared with diabetic mice. This scenario is consistent with the view that beta cell destruction depends upon the increased production of certain pro-inflammatory cytokines by infiltrating T cells. Our inability to detect Fas expression on beta cells, but not on lymphoid cells, in diabetic and non-diabetic mice, puts some constraints on the role of Fas in beta cell destruction.

Interleukin 10 secretion and impaired effector function of major histocompatibility complex class II-restricted T cells anergized in vivo.

Continuous antigenic stimulation in vivo can result in the generation of so-called "anergic" CD4(+) or CD8(+) T cells that fail to proliferate upon antigenic stimulation and fail to develop cytolytic effector functions. Here we show that class II major histocompatibility complex-restricted T cells specific for influenza hemagglutinin (HA) that become anergic in mice expressing HA under control of the immunoglobulin kappa promoter exhibit an impaired effector function in causing diabetes in vivo, as compared to their naive counterparts, when transferred into immunodeficient recipients expressing HA under the control of the insulin promoter. Furthermore, HA-specific T cells anergized in vivo contain higher levels of interleukin (IL)-4 messenger RNA (mRNA) than naive and recently activated T cells with the same specificity and more than a 100-fold higher levels of IL-10 mRNA. The higher expression of the IL-10 gene is also evident at the protein level. These findings raise the interesting possibility that T cells rendered anergic in vivo have in fact become regulatory T cells that may influence neighboring immune responses through the release of IL-10.

Conditions that induce tolerance in mature CD4+ T cells.

Establishment of antigen-specific tolerance among mature T cells has been a long debated, yet poorly understood issue. In this study we have used transgenic mice bearing a class II--restricted TCR specific for the hemmagglutinin of the influenza virus in order to test the behavior of CD4+ T cells upon exposure to antigen in different forms and doses. We first studied the fate of T cells expressing the transgenic TCR (6.5) in double transgenic mice where HA was expressed as a self antigen by hemapoietic cells. In these mice, we found some mature T cells in periphery that had escaped thymic deletion and that showed signs of activation but which were anergic. Mature CD4+6.5+ cells that were transferred into antigen-containing recipients went through an initial phase of expansion after which most cells were deleted and those remaining became unresponsive, as previously described for CD8+ cells. Inducing tolerance in CD4+6.5+ cells in situ in single transgenic mice proved a difficult task: classical protocols using single doses of soluble or deaggregated antigen as well as feeding antigen all failed to induce antigen-specific unresponsiveness. It was only after decreasing cell numbers by CD4 antibody treatment and by repeatedly reintroducing antigen thereafter that unresponsiveness of 6.5+ cells was achieved and maintained. In no case could we observe the appearance of antigen-specific T cells with a Th2 cytokine profile among the remaining cells and therefore conclude that deletion and anergy represent the major mechanisms of tolerance in our studies.

Molecular analysis of TCR junctional variability in individual infiltrated islets of non-obese diabetic mice: evidence for the constitution of largely autonomous T cell foci within the same pancreas.

Insulitis develops in non-obese diabetic (NOD) mice as a multicentric and asynchronous process. In an effort to understand how this T cell mediated process expands within each islet and propagates between the islets of the same pancreas, we have analyzed the junctional diversity of TCR V beta 6 and V beta 8.2 transcripts cloned from infiltrated islets. The material examined was obtained from individual islets of 8 and 12 week old NOD mice or from pooled islets of 4 week old individual mice. Compared with spleen transcripts, where every V beta 6 or V beta 8.2 clone displays a different junction, islet transcripts are considerably less diverse. Each islet harbors from one to a maximum of six independent CDR3 sequences out of 10 or more analyzed colonies. On the other hand, there is an overall diversity of sequences when comparing the islets of the same pancreas or individual mice at 4 weeks. Altogether, these results support the idea that TCR repertoires are already divergent at the very early onset of insulitis and that each islet-centered infiltrate develops rather autonomously from the oligoclonal expansion of a limited set of precursors. Recirculation between islets is limited and does not seem to be the main mode of propagation of insulitis. Finally, a close analysis of J beta usage and N additions in beta chain transcripts from infiltrating cells reveals definite biases suggestive of an ongoing selective process imposed upon intra-pancreatic T lymphocytes.

Anchored polymerase chain reaction based analysis of the V beta repertoire in the non-obese diabetic (NOD) mouse.

We have performed extensive analyses of T cell receptor V beta usage in the thymus, the spleen and the infiltrated islets of preclinical non-obese diabetic (NOD) mice. A semiquantitative anchored polymerase chain reaction (An-PCR) protocol has been developed for this purpose. The validity of the method has been first assessed by antibody staining with a panel of anti-V beta monoclonal antibodies (mAb). The results obtained by An-PCR are accurate, reproducible, and in good agreement with cell surface protein staining. A strict comparison between thymus and spleen repertoires reveals no major V beta-specific deletion except the already reported V beta 3 deletion due to Mtv-3. Certain V beta such as V beta 15, 18, 20 are found with a low frequency in the spleen, but the fact that they are also scarce in the thymus probably reflects a poor availability of these genetic elements during beta chain rearrangement rather than negative selection. Other V beta, such as V beta 2, V beta 12 and V beta 14 are significantly more abundant in the spleen than in the thymus. This finding was confirmed by mAb staining for V beta 2 and V beta 14. The expansion asymmetrically affects the CD4+ subset and can be traced back to the mature, single-positive thymocyte subset, suggesting an intrathymic positive selection event. V beta repertoires in infiltrated islets of 13- and 18-week-old, non-diabetic mice are polymorphic. Practically all the V beta found in the peripheral lymphoid tissues are present in the islets, in similar proportions. The major exception is V beta 12, one of the V beta which is subject to expansion during intrathymic differentiation and which is further augmented in the islets, both at 13 and 18 weeks. This increase probably reflects further peripheral amplification of the V beta 12-bearing subset due to encounter with the same ligand as in the thymus or with a cross-reactive motif. Finally, the nucleotide sequencing of all the V beta segments in usage in the NOD strain confirms the absence of allelic polymorphism of V beta-coding regions.