Lineage fate alteration of thymocytes developing in an MHC environment containing MHC/peptide ligands with antagonist properties

A18 TCR transgenic thymocytes which are H-2E(k) restricted and normally selected into the CD4 lineage, are exclusively selected into the CD8 lineage in an H-2(q) MHC background. CD8 T cell selection in the H-2(q) background is far more efficient than default selection of A18 CD8 cells on a CD4(-/-) H-2E(k +) background. This suggests the involvement of special selecting ligands. Analogues of the cognate peptide for A18 with antagonist properties for the A18 TCR have previously been shown to effect a lineage diversion from CD4 to CD8 in fetal thymic organ cultures and intriguingly the MHC(q) background contains unidentified natural MHC class II ligands which similarly show antagonist properties for the A18 TCR. Despite the presence of these unidentified MHC class II ligands in the H-2(q) background and their potential influence on developing A18 thymocytes, however, MHC class I molecules were essential for thymic selection of A18 CD8 T cells.

Low CD4(+) T cell responses to the C-terminal region of the malaria merozoite surface protein-1 may be attributed to processing within distinct MHC class II pathways

The C-terminal fragment of merozoite surface protein-1 (MSP-1) of the mouse malaria parasite Plasmodium chabaudi chabaudi (AS) stimulates a weak CD4 T cell response when compared to the response to a more structurally simple region of the molecule. The tertiary structure of the C-terminal region of MSP-1 is maintained by five disulfide bonds. A peptide from this region could only be processed and loaded onto newly synthesized MHC class II molecules, whereas a peptide from the structurally simple region was available for loading onto recycling MHC class II. CD4(+) T cell hybridomas took longer to recognize an epitope derived from the disulfide-bonded region whether native parasite or recombinant MSP-1 antigen was used. Reduction of disulfide bonds in the C-terminal region subsequently allowed peptides to be loaded onto recycling MHC class II and greatly enhanced the rapidity of the T cell response. These data demonstrate that differential processing occurs intramolecularly in MSP-1, which may be responsible for the observed weak CD4 T cell responses against this region. The consequences of this in vivo may be that limited T cell help is available for protective antibody production which has important implications for designing vaccines based on MSP-1.

Differential survival of naive CD4 and CD8 T cells

In this paper we compare survival characteristics of transgenic and polyclonal CD4 and CD8 T cells. Transgenic CD4 T cells have an intrinsically lower capacity for survival, reflected in their gradual disappearance in thymectomized hosts, their increased sensitivity to apoptosis in vitro, and fewer divisions during homeostatic proliferation upon transfer into syngeneic lymphopenic hosts compared with CD8 T cells. Homeostatic proliferation, however, does not generally result in phenotypic conversion of activation markers unless cognate or cross-reactive Ag is present. T cells from the A18 TCR transgenic strain normally selected into the CD4 lineage are fragile as CD4 T cells, yet display the typical robust survival pattern of CD8 T cells when diverted into the CD8 lineage in a CD4-deficient host. Polyclonal CD4 and CD8 T cells also show distinctive patterns of survival, emphasizing that survival signals are relayed differently in the two lymphocyte subpopulations. However, expression levels of Bcl-2 in either transgenic or polyclonal naive CD4 and CD8 T cells are similar, excluding a role for this molecule as a key factor in differential survival of CD4 vs CD8 T cells.

The HSC73 molecular chaperone: involvement in MHC class II antigen presentation

Heat shock proteins (HSP) are conserved proteins, many of which share the ability for indiscriminate peptide binding and ATPase-coupled peptide release. In this paper, we show that heat shock cognate protein (HSC)73, a constitutively expressed member of the HSP70 family, could be a candidate for chaperone activity within the MHC class II presentation pathway. HSC73 expression in macrophages was shown to overlap with expression of MHC class II; overexpression of HSC73 in stable transfectants of a macrophage line markedly enhanced their presentation of exogenous Ag without affecting presentation of processing independent peptide. Ag from an exogenous source was demonstrated to associate with HSC73 in macrophages, and this association was sensitive to ATP treatment and inhibited by deoxyspergualin, an immunosuppressive agent that has previously been shown to bind specifically to HSC73. Furthermore, deoxyspergualin reduced Ag presentation by macrophages in relation to the amount of HSC73 expressed in these cells. The data are consistent with a potential role for HSC73 in binding and protecting peptides from extensive degradation and/or facilitating the kinetics of peptide transfer to MHC class II molecules.

Following the development of a CD4 T cell response in vivo: from activation to memory formation

The in vivo differentiation of CD4 T cells from naive to memory cells was followed after their adoptive transfer together with syngeneic dendritic cells into MHC mismatched adoptive hosts lacking lymphocytes and NK cells. Functional and molecular changes were measured as the antigenic stimulus, provided by the cotransferred dendritic cells, disappeared. Memory cells as opposed to effector cells show an inversion in the relative expression of Bcl-2 family members in favor of antiapoptotic molecules, and compared with naive cells they have an increased ratio of bcl-xL to bcl-2. They differ qualitatively from naive T cells, suggesting that accelerated CD4 memory responses can occur without the need for increased frequencies of specific T cells.

DNA vaccination: transfection and activation of dendritic cells as key events for immunity

The mechanisms underlying initiation and maintenance of CD4 T cell responses after DNA vaccination were studied using a construct coding for nonsecreted fifth component of complement (C5) protein, thus restricting the availability of antigen. The only cell types to express C5 were keratinocytes at the site of DNA application and a small number of dendritic cells present in the draining lymph nodes. Antigen expression persisted for up to 12 wk in keratinocytes, but dendritic cells did not express C5 beyond 2 wk after vaccination. Cross-priming of dendritic cells by C5 expressed in keratinocytes did not occur unless keratinocyte death was induced by irradiation in vitro. CD4 T cells were activated in the draining lymph nodes only and subsequently migrated to the spleen, where memory T cells persisted for longer than 40 wk despite the absence of a source of persistent antigen. While DNA vaccination resulted in transfection of a small proportion of dendritic cells only, it led to general activation of all dendritic cells, thus providing optimal conditions for effective T cell activation and maintenance of memory.

The Ii41 isoform of invariant chain mediates both positive and negative selection events in T-cell receptor transgenic mice

The functional role of invariant chain in T-cell selection events and antigen presentation is well established. The invariant chain gene encodes differentially spliced isoforms, Ii31 and Ii41. The Ii41 isoform has been described to increase the efficiency of antigen presentation. We have analysed the effect of the Ii41 isoform on positive and negative selection of transgenic CD4 T cells with specificity for a natural self antigen (C5) which are crucially dependent on invariant chain for their development and functional antigen recognition. The data show that Ii41 fully substitutes for wild-type invariant chain in both positive and negative selection events during functional maturation of T cells with specificity for a natural, blood-borne self antigen.

Normal thymic selection of TCR transgenic CD4 T cells, but impaired survival in the periphery despite the presence of selecting MHC molecules

In this paper, we investigate selection in the thymus and survival in the periphery of CD4 T cells, which carry a major histocompatibility class II-restricted transgenic TCR (A18 TCRtg) specific for a natural self Ag, the fifth component of complement (C5). A18 TCRtg thymocytes develop normal numbers of CD4 single-positive (SP) thymocytes, but do not show pronounced overselection as do some other TCR transgenic strains. CD4 SP cells are mature as judged by termination of CD8 synthesis, resistance to cortisone, and functional competence. The kinetics of positive selection, determined by BrdU labeling, are very fast. CD4 SP thymocytes are demonstrable within 2 days of labeling, and within 8 days after labeling a large proportion (20%) of lymph node T cells are recent thymic emigrants. The high number of recent thymic emigrants suggests rapid turnover of CD4 T cells in the periphery, which was confirmed by thymectomy and determination of CD4 T cell life spans. A18 TCRtg T cells have a t(1/2) of approximately 6 wk, despite the presence of selecting MHC molecules. This explains the failure to accumulate high numbers of peripheral T cells and suggests that the MHC-bound ligand(s) responsible for initiating survival signals is limiting for the selection and maintenance of A18 transgenic CD4 T cells.

Antagonist peptide selects thymocytes expressing a class II major histocompatibility complex-restricted T cell receptor into the CD8 lineage

CD4/CD8 lineage decision is an important event during T cell maturation in the thymus. CD8 T cell differentiation usually requires corecognition of major histocompatibility complex (MHC) class I by the T cell receptor (TCR) and CD8, whereas CD4 T cells differentiate as a consequence of MHC class II recognition by the TCR and CD4. The involvement of specific peptides in the selection of T cells expressing a particular TCR could be demonstrated so far for the CD8 lineage only. We used mice transgenic for an MHC class II-restricted TCR to investigate the role of antagonistic peptides in CD4 T cell differentiation. Interestingly, antagonists blocked the development of CD4(+) cells that normally differentiate in thymus organ culture from those mice, and they induced the generation of CD8(+) cells in thymus organ culture from mice impaired in CD4(+) cell development (invariant chain-deficient mice). These results are in line with recent observations that antagonistic signals direct differentiation into the CD8 lineage, regardless of MHC specificity.

Rejection of H-Y disparate skin grafts by monospecific CD4+ Th1 and Th2 cells: no requirement for CD8+ T cells or B cells

We wished to determine whether CD4+ T cells could reject a skin graft that was discordant for a single minor transplantation Ag in the absence of CD8+ T cells or Ab. Transgenic A1(M) mice were constructed that express the rearranged V beta 8.2 and V alpha 10 TCR genes from a T cell clone that is specific for the male Ag (H-Y) in the context of H2-Ek. In addition, the RAG-1(-/-) background was bred onto these mice to eliminate any endogenous TCR rearrangements. As expected, clonal deletion was found to be complete in the thymus of male A1(M) x RAG-1(-/-) mice, while only CD4+ T cells were positively selected and found in the periphery of females. Female A1(M) x RAG-1(-/-) mice were able to rapidly reject (in <14 days) male (but not female) skin grafts in a CD4-dependent fashion. After multiple grafts, it was confirmed that no CD8+ T cells or surface Ig+ B cells were present. An immunofluorescent analysis of spleen cells after grafting showed that the majority of T cells expressed activation markers (CD44, CD25, and intracytoplasmic IL-2) and a significant proportion were making IFN-gamma and IL-4. Surprisingly, the transfer of either Th1 or Th2 CD4+ T cell lines from these mice into T cell-depleted recipients was sufficient to cause a specific rejection of male skin.

Antigen-specific T cell receptor antagonism by antigen-presenting cells treated with the hemolysin of Listeria monocytogenes: a novel type of immune escape

We have examined the influence of listeriolysin O (LLO), the hemolysin secreted by the pathogenic bacterium Listeria monocytogenes, on major histocompatibility complex class II-dependent T cell activation. Stimulation of T cells by native antigens but not by peptides is inhibited upon pretreatment of antigen-presenting cells (APC) with LLO. Experiments presented here reveal that this inhibition is not due to a lack in processing of antigen by APC but is the result of an irreversible inactivation of T cells that recognize antigen on LLO-treated APC. Incubation of mixtures of two different T cells where only one antigen was presented on LLO-treated APC suggested that T cell inactivation is antigen specific. The inactivation was dominant and could be observed even in the presence of amounts of synthetic peptides that normally lead to T cell responses. This condition is reminiscent of the T cell inhibition observed when antagonistic and stimulatory peptides are added to APC at the same time. Our results thus reveal a novel type of interference by pathogens with antigen presentation and T cell stimulation that could give the pathogen a decisive advantage in dissemination and disease.

Modulation of Basophil Histamine Release and T Cell Reactivity by Chemically Modified Allergen

Modification of a model allergen ovalbumin (OA) with succinylation (Suc-OA) led to inhibition of allergen histamine releasing activity as it was tested on basophils of OA-sensitive patients. A whole blood leukocyte histamine release was performed by glass fibre based histamine assay. IgE-binding activity of Suc-OA was significantly reduced as it was shown by RAST inhibition technique. Suc-OA stimulated OA-specific T cell hybrid 3DO-548 and ACP:LK35 to produce cytokine release at the same level as in the case of non-modified OA. Succinylation of OA was concluded to result in selective blockade of B cell and preservation of T cell epitopes of the allergen suggesting a new approach for allergen specific immunotherapy.

T-cell anergy induced by antigen presenting cells treated with the hemolysin of Listeria monocytogenes

Antigen presenting cells (APC) that are infected with listeriolysin (LLO) secreting Listeria lack the ability to stimulate MHC class II restricted T-cells by conventional antigens. Similarly, T-cell activation by native proteins but not by peptides was inhibited upon pretreatment of APC with purified listeriolysin. The inhibition is due to an irreversible inactivation of T-cells that recognize antigen on infected or LLO treated APC. Inhibition was found to dominate over stimulation by peptides. This condition is reminiscent of T-cells inactivation by antagonistic peptides and represents a novel type of immune escape.

Excessive degradation of intracellular protein in macrophages prevents presentation in the context of major histocompatibility complex class II molecules

The endogenous major histocompatibility complex (MHC) class II presentation pathway allows biosynthesized, intracellular antigens access for presentation to MHC class II-restricted T cells. This pathway has been well documented in B cells and fibroblasts, but may not be universally available in all antigen-presenting cell types. This study compares the ability of different antigen-presenting cells, expressing endogenous C5 protein (fifth component of mouse complement) as a result of transfection, to present their biosynthesized C5 to MHC class II-restricted T cells. B cells and fibroblasts expressing C5 were able to present several epitopes of this protein with MHC class II molecules, whereas macrophages were unable to do so, but readily presented C5 from an extracellular source. However, macrophage presentation of endogenous C5 could be achieved when they were treated with low doses of the lysosomotropic agent ammonium chloride. In the presence of an inhibitor of autophagy, presentation of endogenous C5 was abrogated, indicating that biosynthesized C5 is shuttled into lysosomal compartments for degradation before making contact with MHC class II molecules. Taken together, this suggests that proteolytic activity in lysosomes of macrophages may be excessive, compared with fibroblasts and B cells, and destroys epitopes of the C5 protein before they can gain access to MHC class II molecules. Thus, there are inherent differences in presentation pathways between antigen-presenting cell types; this could reflect their specialized functions within the immune system with macrophages focussing preferentially on internalization, degradation, and presentation of extracellular material.

Bone marrow-derived dendritic cells can process bacteria for MHC-I and MHC-II presentation to T cells

Dendritic cells can engulf particulate Ags and induce T cell proliferative responses after pulsing with particulate Ag. However, their capacity to process viable Gram-negative bacteria for presentation by MHC-I and MHC-II has not been shown. We therefore characterized the ability of murine bone marrow-derived dendritic cells to process Escherichia coli and Salmonella typhimurium, expressing defined epitopes for presentation by MHC-I and MHC-II molecules. The I-Ak-restricted 46-61 epitope from hen egg white lysozyme (HEL(46-61)) or the Kb-restricted 257-264 epitope from chicken egg OVA (OVA(257-264)) was expressed as fusion proteins in the bacterial cytoplasm as the Crl-HEL and Crl-OVA fusion proteins, respectively. Bacteria expressing Crl-HEL or Crl-OVA, or beads coated with HEL or OVA, were coincubated with murine bone marrow-derived dendritic cells, and Ag processing and presentation were quantitated using T cell hybridomas. The data show that granulocyte-macrophage CSF-stimulated dendritic cells can process live intact Gram-negative bacteria for peptide presentation by MHC-I and MHC-II. Cytochalasin D inhibition studies revealed that processing for both MHC-I and MHC-II presentation required cytoskeletal rearrangements. Processing for MHC-I and MHC-II presentation was inhibited by ammonium chloride, suggesting that acidic compartments were required. Thus, granulocyte-macrophage CSF-stimulated murine bone marrow dendritic cells are capable of processing exogenous particulate Ags, including bacteria with no known mechanism for phagosomal escape, for peptide presentation by both MHC-I and MHC-II. These data suggest that dendritic cells may be important in priming both CD4+ and CD8+ T cells to bacterial Ags.

Bone marrow-derived dendritic cells can process bacteria for MHC-I and MHC-II presentation to T cells

Dendritic cells can engulf particulate Ags and induce T cell proliferative responses after pulsing with particulate Ag. However, their capacity to process viable Gram-negative bacteria for presentation by MHC-I and MHC-II has not been shown. We therefore characterized the ability of murine bone marrow-derived dendritic cells to process Escherichia coli and Salmonella typhimurium, expressing defined epitopes for presentation by MHC-I and MHC-II molecules. The I-Ak-restricted 46-61 epitope from hen egg white lysozyme (HEL(46-61)) or the Kb-restricted 257-264 epitope from chicken egg OVA (OVA(257-264)) was expressed as fusion proteins in the bacterial cytoplasm as the Crl-HEL and Crl-OVA fusion proteins, respectively. Bacteria expressing Crl-HEL or Crl-OVA, or beads coated with HEL or OVA, were coincubated with murine bone marrow-derived dendritic cells, and Ag processing and presentation were quantitated using T cell hybridomas. The data show that granulocyte-macrophage CSF-stimulated dendritic cells can process live intact Gram-negative bacteria for peptide presentation by MHC-I and MHC-II. Cytochalasin D inhibition studies revealed that processing for both MHC-I and MHC-II presentation required cytoskeletal rearrangements. Processing for MHC-I and MHC-II presentation was inhibited by ammonium chloride, suggesting that acidic compartments were required. Thus, granulocyte-macrophage CSF-stimulated murine bone marrow dendritic cells are capable of processing exogenous particulate Ags, including bacteria with no known mechanism for phagosomal escape, for peptide presentation by both MHC-I and MHC-II. These data suggest that dendritic cells may be important in priming both CD4+ and CD8+ T cells to bacterial Ags.

Bacterial antigen delivery systems: phagocytic processing of bacterial antigens for MHC-I and MHC-II presentation to T cells

Using an in vitro model system we have studied parameters of both bacteria and antigen presenting cells that influence peptide presentation by murine major histocompatibility complex class II (MHC-II) and class I (MHC-I) molecules. To study MHC-II presentation, the HEL (52-61) epitope, which binds the murine MHC-II molecule I-Ak, was expressed as the cytoplasmic Crl-HEL fusion protein in S. typhimurium. When murine peritoneal macrophages mediated phagocytic processing of S. typhimurium expressing Crl-HEL, HEL (52-61) was processed and presented on I-Ak more efficiently from heat-killed S. typhimurium than from viable bacteria, and from a rough LPS strain compared to its isogenic smooth LPS counterpart, most likely due to enhanced phagocytosis of the rough LPS strain. Macrophages also processed phoP S. typhimurium strains with greater efficiency for peptide presentation by I-Ak than wild type bacteria while Salmonella constitutively expressing phoP were processed for peptide presentation by I-Ak less efficiently than wild type Salmonella. We have also shown that macrophage phagocytosis of E. coli or S. typhimurium results in presentation of bacterial antigens by MHC-I molecules. To investigate the role of post-Golgi MHC-I molecules in this presentation pathway, peritoneal macrophages from TAP1-/- mice, which are deficient in presenting endogenous antigens on MHC-I and lack significant surface MHC-I expression, were co-incubated with bacteria containing the 257-264 epitope from ovalbumin [OVA(257-264)], which binds the murine class I molecule Kb. Peritoneal macrophages from TAP1-/-/ mice could process bacteria expressing the OVA epitope for recognition by epitope-specific T hybridoma cells. This processing and presentation was reduced in efficiency between three to 100 fold compared to C57BL/6 macrophages, depending on the protein harbouring the OVA (257-264) epitope (Crl-OVA or native OVA). This suggests that the protein context of the OVA (257-264) epitope influences the extent of TAP-independent processing for MHC-I presentation. In addition, we show that murine bone marrow-derived dendritic cells can phagocytose and process viable gram negative bacteria for peptide presentation on MHC-I and MHC-II; inhibition studies showed that acidic compartments in dendritic cells are required for this presentation. These results suggest that dendritic cells may be potential antigen presenting cells used in eliciting specific immune responses against bacteria.

Antigen-presenting cells in the thymus that can negatively select MHC class II-restricted T cells recognizing a circulating self antigen

We investigated Ag presentation of an extracellular self Ag (C5), which only reaches the thymus via the blood circulation, for negative selection of MHC class II-restricted, C5-specific T cells. Thymic APC were introduced into fetal thymic reaggregation culture with thymocytes from C5-specific TCR transgenic mice to follow the development of C5-specific T cells in the presence or the absence of self Ag presented by various APC. To mimic the physiologic distribution of C5 peptide/MHC class II complexes on thymic APC as closely as possible, they were isolated from thymi of C5+ mice, so that the amount of C5 peptide bound to MHC class II on their surface would reflect the amount of self Ag they have access to and process normally in vivo. This circumvented the problems related to artificially high doses of Ag or peptide in vivo or in vitro, that might obscure physiologic differences such as the capacity to internalize and process Ag. The results show that not only thymic dendritic cells, but also cortical and medullary epithelial cells were able to induce negative selection of C5-specific thymocytes with similar efficiency. In contrast, thymic macrophages were unable to influence the development of C5-specific T cells. Their failure to present exogenous self Ag for negative selection suggests that macrophages concentrate on their primary function in the thymus, the disposal of dying thymocytes.

Antigen-presenting cells in the thymus that can negatively select MHC class II-restricted T cells recognizing a circulating self antigen

We investigated Ag presentation of an extracellular self Ag (C5), which only reaches the thymus via the blood circulation, for negative selection of MHC class II-restricted, C5-specific T cells. Thymic APC were introduced into fetal thymic reaggregation culture with thymocytes from C5-specific TCR transgenic mice to follow the development of C5-specific T cells in the presence or the absence of self Ag presented by various APC. To mimic the physiologic distribution of C5 peptide/MHC class II complexes on thymic APC as closely as possible, they were isolated from thymi of C5+ mice, so that the amount of C5 peptide bound to MHC class II on their surface would reflect the amount of self Ag they have access to and process normally in vivo. This circumvented the problems related to artificially high doses of Ag or peptide in vivo or in vitro, that might obscure physiologic differences such as the capacity to internalize and process Ag. The results show that not only thymic dendritic cells, but also cortical and medullary epithelial cells were able to induce negative selection of C5-specific thymocytes with similar efficiency. In contrast, thymic macrophages were unable to influence the development of C5-specific T cells. Their failure to present exogenous self Ag for negative selection suggests that macrophages concentrate on their primary function in the thymus, the disposal of dying thymocytes.

A conditionally immortalized dendritic cell line which differentiates in contact with T cells or T cell-derived cytokines

A conditionally immortalized dendritic cell line was established from bone marrow of mice transgenic for a thermolabile mutant of the SV40 large T antigen under the control of the class I Kb promoter. At the permissive temperature of 33 degrees-37 degrees C, the line divides in the absence of granulocyte/macrophage colony stimulating factor. It shares a number of cell surface markers with bone marrow macrophages, but unlike macrophages, is constitutively major histocompatibility complex (MHC) class II+, negative for nonspecific esterase and unable to phagocytose sheep red blood cells. The cells show characteristic dendrites, an abundance of acidic vesicles and are highly active in endocytosis. If maintained at 33 degrees C, the dendritic cell line processes and presents exogenous protein to MHC class II-restricted T cell hybrids and acts as potent mixed lymphocyte reaction stimulator, but fails to activate naive, resting T cells. Transfer to 39 degrees C arrests growth and results in up-regulation of surface markers such as B7.1, CD40 and intercellular adhesion molecule-1. Further up-regulation of cell surface markers and acquisition of functional maturity occur following contact with T cells and their cognate antigen or in culture with a cytokine mixture derived from activated T cells.

Expression of a second receptor rescues self-specific T cells from thymic deletion and allows activation of autoreactive effector function

Allelic exclusion at the T-cell receptor alpha chain locus is incomplete resulting in the generation of T cells that express two T-cell receptors. The potential involvement of such T cells in autoimmunity has been suggested [Padovan, E., Casorati, G., Dellabona, P., Meyer, S., Brockhaus, M. & Lanzavecchia, A. (1993) Science 262, 422-424; Heath, W. R. & Miller, J. F. A. P. (1993) J. Exp. Med. 178, 1807-1811]. Here we show that expression of a second T-cell receptor can rescue T cells with autospecific receptors from thymic deletion and allow their exit into the periphery. Dual receptor T cells, created by constitutive expression of two transgenic T-cell receptors on a Rag1-/- background, are tolerant to self by maintaining low levels of autospecific receptor, but selfreactive effector function (killing) can be induced through activation via the second receptor. This opens the possibility that T cells carrying two receptors in the periphery of normal individuals contain putatively autoreactive cells that could engage in autoimmune effector functions after recognition of an unrelated environmental antigen.

B cells solicit their own help from T cells

We have made use of T cell receptor (TCR)-transgenic mice with CD4+ T cells expressing a receptor specific for the self-antigen C5 (fifth component of complement) to study the role of different antigen-presenting cells in the determination of CD4+ T cell effector type. Contact of T cells from C5 TCR-transgenic mice with C5 protein or C5 peptide in vivo or in vitro induces biased T helper cell (Th) 1 type responses resulting in exclusive production of high levels of interferon gamma and interleukin (IL) 2. Transgenic mice, in contrast to nontransgenic littermates, do not generate an antibody response to C5. We show in this paper that B cell presentation in vitro induces a switch to the Th2 subset indicated by production of IL-4, and targetting C5 to B cells in vivo results in the generation of C5-specific antibodies.

Macrophage presentation of endogenous self-protein: the MHC class II presentation pathway is not accessible to intracellular C5 or alpha 1-antitrypsin

This paper addresses the question of whether macrophages can present biosynthesized protein in a class II-restricted manner using the endogenous rather than the exogenous pathway of presentation. Two distinct self-antigens, the fifth component of complement (C5) and alpha 1-antitrypsin, were studied. Both antigens are serum proteins synthesized by hepatocytes and macrophages. To direct synthesis exclusively to macrophages chimeras were constructed by transfer of bone marrow from donors expressing the self-antigen into irradiated hosts deficient for the respective self-antigen. Macrophages from such mice were unable to present biosynthesized C5 to class II-restricted T cells, even when preactivated in vivo. While C5 production by macrophages is low and may not reach critical levels of intracellular protein required to access the class II presentation pathway, human alpha 1-antitrypsin, expressed as a transgene in mice, was synthesized at 600-fold higher levels than C5. Nevertheless, macrophage-synthesized alpha 1-antitrypsin in bone marrow chimeras was not presented in the context of class II--even in a mutant form which is sequestered in high amounts in the endoplasmic reticulum. We conclude that macrophages are unable to use the endogenous class II presentation pathway for these two model self-antigens. As a consequence MHC class II-restricted T cells specific for C5 and alpha 1-antitrypsin remain ignorant of the presence of self-antigen within macrophages and are neither tolerized nor rendered autoimmune.

Immunological properties of allergen chemically modified with synthetic copolymer of N-vinylpyrrolidone and maleic anhydride

Several conjugates of model allergen ovalbumin (OA) and the copolymer of N-vinyl pyrrolidone and maleic anhydride (VMA) modified with epsilon-aminocaproic acid (Acp) were prepared in different OA/Acp-VMA ratios. All conjugates were separated by ultrafiltration and analyzed by HPLC. Their compositions were determined by amino acid analysis and UV spectrometry. To detect immunogenicity, all conjugates were injected intraperitoneally into (CBAxC57BL/6)F1 mice three times in 3-week intervals in OA doses equivalent to 0.5, 10, and 100 micrograms/mouse. Only the conjugate containing 20%OA (OA(20%)-Acp-VMA) did not induce significant quantities of anti-OA IgE, but did induce anti-OA IgG antibodies in dose-dependent manner comparable to that of unmodified OA. Mixtures of OA and Acp-VMA or OA modified only with VMA without Acp activation with Acp induced dose-dependent anti-OA IgE and IgG antibody formation comparable to that of OA. Using passive cutaneous anaphylaxis, RAST inhibition and leukocyte histamine release, a significant reduction of allergenicity was noted using OA(20%)-Acp-VMA. This conjugate stimulated activation of the OA-specific T-cell hybrid 3DO-548 comparable to that of unconjugated OA. During experimental allergen-specific hyposensitization with OA(20%)-Acp-VMA, suppression of anti-OA IgE response and elevation of anti-OA IgG responses were noted when compared with unmodified OA. Selective blockade of B-cell epitopes of allergen may occur using the carrier Acp-VMA to reduce allergenicity while not affecting T-cell epitopes, thereby preserving immunogenicity. This approach of chemical modification of allergen suggests new opportunities in the creation of preparations for allergen-specific immunotherapy.

Mechanisms of tolerance induction in major histocompatibility complex class II-restricted T cells specific for a blood-borne self-antigen

Transgenic mice expressing a major histocompatibility complex class II-restricted T cell receptor with specificity for a natural self-antigen, the fifth component of complement, were generated to analyze the mechanism of tolerance induction to a blood-borne self-protein. In the absence of C5 protein thymocytes from T cell receptor transgenic mice develop into mature CD4 single positive cells which emigrate into the periphery and mount C5-specific T cell responses upon immunization with C5. In the presence of circulating C5 protein, CD4 single positive thymocytes do not develop. Negative selection occurs late in thymic ontogeny leaving the bulk of CD4+8+ thymocytes unaffected. This phenotype may be due to a delay in contact with self-antigen presentation which, under physiological conditions, is inefficient in the cortex of C5+ mice, and therefore does not affect most immature double positive thymocytes. In contrast, in vitro exposure to C5(-)-presenting dendritic cells or in vivo injection of C5 peptide results in deletion of double positive thymocytes. C5+ transgenic mice are tolerant in vivo, but contain T cells in spleen and lymph nodes that secrete interleukin 2 and interferon gamma in response to C5 activation in vitro. When crossed onto a Rag1-/- background to prevent endogenous T cell receptor rearrangements, these peripheral potentially autoreactive cells do not appear. This indicates that endogenous T cell receptor rearrangements possibly leading to the expression of two receptors might be a prerequisite for their survival and export into the periphery.

Functional recognition of in vivo processed self antigen

C5, the fifth component of complement, is a circulating self protein which induces complete tolerance in MHC class II restricted, CD4+ T cells due to the presentation of C5 taken up from plasma. Functional recognition of in vivo processed C5 was monitored by activation of C5 specific T cell hybrids cultured with antigen presenting cells (APC) from C5 expressing mice. Dendritic cells isolated from various tissues (spleen, thymus, skin) proved to be the most efficient APC, since 10- to 50-fold more macrophages and at least 100- to 500-fold more B cells were needed to achieve similar T cell activation. Stimulatory C5 peptide--class II complexes generated in vivo were retained on the surface of dendritic cells but not on macrophages and B cells upon prolonged culture. Dendritic cells but not macrophages from thymus presented in vivo processed C5. Taken together these findings emphasize the crucial role dendritic cells play for recognition of soluble self proteins by MHC class II restricted T cells.

In vitro negative selection of alpha beta T cell receptor transgenic thymocytes by conditionally immortalized thymic cortical epithelial cell lines and dendritic cells

We have established conditionally immortalized thymic cortical epithelial cell lines from transgenic mice carrying a temperature-sensitive SV40 large T antigen. One of these cell lines expresses cortical markers and produces IL-1 alpha, IL-6, IL-7, and TGF-beta 1. These cells express class I major histocompatibility complex (MHC) constitutively and class II MHC upon induction with IFN-gamma. The cells appear to have a normal class I antigen presenting pathway since messages for both peptide transporter genes (TAP1, TAP2) were detected. The ability of these cortical epithelial cells to present peptide antigen was compared to that of thymic dendritic cells. In suspension culture with alpha beta T cell receptor (TcR) transgenic thymocytes, these epithelial cells and dendritic cells (pre-pulsed with peptide cognate for the transgenic TcR) caused down-regulation of CD4, CD8, and TcR in an antigen dose-dependent and MHC-restricted manner. CD4dullCD8dull cells were taken as evidence for negative selection because these cells contained apoptotic DNA. Concentration of peptide required for negative selection of thymocytes was similar between dendritic cells and cortical epithelial cells. In contrast, alpha beta TcR transgenic spleen cells were activated only by dendritic cells but not by cortical epithelial cells.

Presentation of a circulating self protein (C5) to MHC class II restricted T cells

Presentation of a soluble self antigen, the fifth component of complement (C5), is discussed with emphasis on the differential ability of presentation by subpopulations of APC (dendritic cells, macrophages, B cells, fibroblasts, B cell lines and bone marrow macrophages). Constitutive presentation of C5 in C5 sufficient mice is a prerequisite for tolerance induction in MHC class II restricted T cells and can be directly demonstrated by the ability of ex-vivo APC from C5 sufficient, but not C5 deficient mice, to activate C5 specific T cells in vitro in the absence of added antigen. C5 presentation and tolerance induction in MHC class II restricted T cells is strictly dependent on an exogenous source of self antigen. C5 biosynthesized, but not secreted by macrophages is ignored by MHC class II restricted cells and induces neither tolerance nor autoimmunity. C5 presentation for tolerance induction depends largely on the efficiency of antigen uptake by APC, a property which varies within different APC subpopulations and with the nature of the antigen.

Localization of self antigen: implications for antigen presentation and induction of tolerance

The fifth component of complement (C5) is a self antigen expressed in serum of normal mice at a concentration of about 50 micrograms/ml. We have previously shown that C5 is constitutively processed and presented by antigen-presenting cells (APC) in normal mice to induce and maintain complete tolerance in major histocompatibility complex (MHC) class II-restricted T cells. This report addresses the question of whether C5 presentation involves exogenous antigen which has been internalized for processing or whether intracellular, biosynthesized C5 is being presented with MHC class II. Macrophages were found to synthesize, but not secrete C5 in bone marrow chimeras made from irradiated C5-deficient [C5(-)] hosts reconstituted with C5-sufficient [C5(+)] bone marrow [C5(+)-->C5(-)]. In these mice, macrophages are the only source of C5. [C5(+)-->C5(-)] chimeras are not tolerant of C5 and generate C5-specific T and B cell responses upon immunization indistinguishable from those of C5(-) mice. Macrophages from [C5(+)-->C5(-)] chimeras are unable to activate C5-specific T cell hybrids in vitro unlike macrophages from a C5(-) strain that has matured in a C5-expressing environment [C5(-)-->C5(+) chimeras]. This shows that under physiological conditions in vivo intracellular C5 does not get access to the class II presentation pathway and thus, does not induce tolerance in class II-restricted T cells.

Capacity of antigen uptake by B cells, fibroblasts or macrophages determines efficiency of presentation of a soluble self antigen (C5) to T lymphocytes

Self antigens in the body fluids must be taken up, processed and presented by antigen-presenting cells (APC) in order to induce T cell tolerance. For self antigens like the fifth component of complement (C5) which is not picked up by APC via antigen-specific receptors, presentation has to rely on uptake by nonspecific means. C5 was used as a model soluble self antigen to study the capacity of different APC (B lymphoma cells, fibroblasts and macrophages) of taking up, processing and presenting low concentrations of soluble C5 to C5 specific T cell hybrids. Under conditions of limiting antigen amounts macrophages and fibroblasts exhibited similar presentation capacity for soluble C5 while B cells did not. C5 presentation by macrophages was enhanced in the presence of C5-specific antibody and augmented further if antigen was added in the form of particulate latex-antigen-antibody complexes indicating enhanced uptake via Fc receptor-mediated endocytosis or phagocytosis. B cells presented soluble C5 only in the presence of C5-specific antibody. Uptake of C5 under these conditions occurred via Fc receptors type II. This pathway of antigen uptake did not operate with other antigens which were presented efficiently after nonspecific endocytosis. In light of these findings it seems reasonable to propose that nonspecific endocytosis of serum proteins like C5 by B cells is normally limited in order to avoid interference with their critical role in antigen receptor-mediated uptake and presentation for the initiation of an antibody response. It seems likely that presentation of soluble self antigens present in the circulation may normally be the task of dendritic cells and macrophages depending on the physical shape of the antigen.

Mouse macrophage clones immortalized by retroviruses are functionally heterogeneous

Murine macrophage clones were generated from thymus, spleen, brain, and bone marrow by in vitro immortalization with recombinant retroviruses carrying an avian v-myc oncogene. The cloned cell lines express F4/80 molecules, exert phagocytosis, have nonspecific esterase activity, and express class II molecules after interferon gamma activation. The macrophage clones are diploid and their karyotypes have remained stable for greater than 3 years in culture. After the macrophage clones were activated, their pattern of cytokine production was investigated. Functional heterogeneity in cytokine transcription was demonstrated: one of six liposaccharide-activated macrophages was unable to transcribe interleukin 1 alpha, whereas all of the liposaccharide-activated clones were able to transcribe tumor necrosis factor alpha. Interleukin 6 production was detected in three of six clones. The production of nitrite and tumor necrosis factor alpha as effector molecules of cytotoxicity was detected in all clones, thus showing that a single macrophage can exert more than one cytotoxic mechanism. The results indicate that immortalized and cloned macrophages have a differentially regulated expression of cytokine genes, adding further evidence for the existence of functional heterogeneity among cloned macrophages. This heterogeneity seems to derive from differentiation-related mechanisms rather than from external constraints.

Novel pathways of antigen presentation for the maintenance of memory

Follicular dendritic cells (FDC) store native antigen for long periods in lymphoid follicles and so provide a source of continued stimulation for specific B cells. The expression of MHC class II by FDC suggested they might act as antigen-presenting cells for MHC class II-restricted T cells. We show here, however, that the MHC class II molecules found on their surface are not synthesized by the FDC but are picked up from surrounding B cells in germinal centres. Although FDC by themselves cannot present native antigen to T cells, acquired MHC class II-peptide complexes can be recognized by T cells. The true physiological role of FDC seems to be as long-term antigen depots. We demonstrate that antigen localized onto FDC in vivo can be retrieved by antigen-specific B cells, which in turn process and present it to T cells. These presentation pathways are likely to be crucial in both the maintenance of long-term immune responses and the continued survival of memory cells.

Molecules that modify antigen recognition

MHC class II molecules assemble in the presence of invariant chains. These probably serve not only to protect the peptide-binding site on MHC class II molecules from endogenous peptides, but also to sort MHC class II molecules from the Golgi complex to endosomes and there to retain the class II polypeptides to allow binding of peptides generated from exogenous antigens.

Analysis of T lymphocyte reactivity to complex antigen mixtures by the use of proteins coupled to latex beads

This report describes a suitable model for analysing heterogeneous T cell responses to complex foreign antigens using coated polystyrene beads. The advantage of this technique is that it allows the simple removal of detergents from bound antigen so that biochemically separated antigens or crude antigen mixtures can be used. Furthermore, due to the enhanced uptake of latex-bound antigens by phagocytic antigen-presenting cells (APC), very small amounts of antigen will suffice for activation of T cells in vitro. The potential use of this technique to analyse relevant T cell responses to antigens which are difficult to obtain purified in bulk quantities, is discussed.

A role of Ia-associated invariant chains in antigen processing and presentation

Most native antigens require processing in a cellular compartment for efficient presentation to T helper cells. The cellular elements that permit processing are not known. We investigated a possible role of the class II MHC-associated invariant chains in antigen processing. Fibroblast cells that were transfected with class II genes were compared with fibroblasts supertransfected with the invariant chain gene for their capacity to present the fifth component of complement (C5) to C5-specific class II restricted T cell clones or influenza virus protein to a virus-specific T cell clone. Only fibroblasts supertransfected with the invariant chain gene were able to present native antigen, even at very low antigen concentration, whereas both fibroblast types could present cyanogen bromide-fragmented C5 or the virus peptide. Presentation of intact antigen but not of fragmented antigen was totally abrogated by treatment of fibroblasts with chloroquine. The invariant chain gene encodes two polypeptides, li31 and li41. Expression of either li31 or li41 was sufficient to render class II-expressing fibroblasts capable of presenting intact antigen.

T cell immunity or tolerance as a consequence of self antigen presentation

In this study we investigated the basis for immunity or tolerance to a mouse serum protein, the fifth component of complement (C5). In C5-deficient mice this protein is absent from serum and therefore they are not tolerized. Immunization of C5-deficient mice with C5-sufficient serum generates CD4+ T cells, which recognize C5 presented in the context of class II. No C5-specific responses were observed in T cells from C5-sufficient mice. We show that this self protein is processed and presented with class II by cells from C5-sufficient tolerant mice and can be recognized by C5-specific T cell clones and hybrids in the absence of exogenously added antigen. The stimulation of C5-specific T cells by C5-sufficient antigen-presenting cells is not a consequence of C5 secretion and subsequent processing in vitro but rather employs C5 peptide/class II complexes generated in vivo. We conclude that this self antigen is presented in normal mice in a form recognizable by T cells to induce and maintain immunological tolerance.

An intracellular self protein synthesized in macrophages is presented but fails to induce tolerance

Mice deficient for the fifth component of murine complement (C5), unlike normal mice, do not possess the secreted form of C5 in their body fluids and can be readily immunized to serum-derived normal C5. Although macrophages from C5-deficient mice do not secrete C5, they synthesize the precursor form (pro-C5). Therefore contact of T cells with autologous pro-C5 presented by macrophages is theoretically possible. We show that macrophages from C5-deficient mice can indeed stimulate a class II restricted C5-specific T cell clone without addition of exogenous C5. Immunization of C5-deficient mice with autologous pro-C5 induces vigorous C5-specific T cell proliferation and pro-C5 is recognized by C5-specific T cells in vitro, demonstrating that this protein fails to induce tolerance under physiological conditions. Thus, intracellular pro-C5 is processed and presented by C5-deficient macrophages and can activate T cell clones in vitro, yet is neither immunogenic nor tolerogenic for T cells in vivo.

Purification of the fifth component of murine complement from ascites fluid

The murine complement component C5 was purified on an affinity column using a monoclonal anti-mouse C5 antibody. We describe in this paper that ascites fluid from normal (C5-sufficient) mice contains almost as much C5 protein as mouse serum. Since ascites fluid is much easier to obtain in large quantities it is a convenient source for the purification of this mouse serum protein.

Induction of an immune response to a self antigen

The question has been addressed whether the endogenous B cell population of a mouse can be induced to secrete antibodies specific for a self antigen present in serum. The antigen studied was the fifth component of mouse complement (C5). Nude BALB/c mice which are C5 sufficient were used as a source of potentially C5-reactive B cells and endogenous serum C5 provided the antigenic stimulus. We purposely avoided immunization with C5 in adjuvant. T cells from C5-deficient mice which lack this component in serum and are therefore not tolerant of C5 were injected into nude mice as a source of T cell help for anti-C5 reactive B cells. Control groups received T cells from C5-sufficient euthymic donors, which are tolerant of C5. Initiation of a response to C5 was monitored by testing the hemolytic function of serum. Reduction of C5-dependent hemolysis was observed in sera of mice which had received T cells from C5-deficient donors. Recipients of T cells from C5-sufficient donors maintained normal hemolytic complement levels throughout the test period of 45 days. Reduction of functional complement levels correlated with the presence of immune complexes of anti-C5/C5. C5-specific antibodies were mainly IgG1 and carried the IgG1 allotype of BALB/c providing unequivocal evidence that they were derived from the endogenous B cell population of the C5-sufficient host.

Generation of a monoclonal antibody to mouse C5 application in an ELISA assay for detection of anti-C5 antibodies

We have generated a monoclonal antibody with specificity for the fifth component of mouse complement (C5). This antibody precipitates the two chains of C5 from normal mouse serum and inhibits C5-dependent hemolysis in a functional complement test. In this study we describe its application in an enzyme-linked immunoadsorbent assay (ELISA assay) for the detection of anti-C5 antibodies in serum. Monoclonal anti-C5 coupled to wells of an ELISA plate specifically binds C5 from unfractionated normal mouse serum. This subsequently serves as antigen to bind anti-C5 serum antibodies. By this approach we have circumvented the need for extensive purification of C5 from serum which would be required if C5 was directly coupled to ELISA plates as antigen. Serum antibodies from C5-immunized mice bound with high avidity to wells containing normal serum as antigen source in amounts representing 1 microgram to 250 ng C5. There was no antibody binding to wells containing C5-deficient serum as antigen source. The immune reaction was detected by development with enzyme-coupled goat-anti mouse Ig antibodies specific for various mouse Ig subclasses. This method allows the qualitative characterization of immune responses to mouse C5 which is an ideal model for a natural self antigen in studies of immunological tolerance.

Adsorption on B cell hybridomas removes suppressor cells from spleen cells of neonatally tolerized mice

Spleen cells from CBA mice neonatally tolerized to Dd MHC (major histocompatibility complex) determinants were adsorbed on monolayers of Dd-specific B cell hybridomas. Adsorption on 4 different Dd-specific hybridomas but not on a Kd-specific hybridoma removed suppressor cells and resulted in generation of cytotoxic T lymphocyte (CTL) effector cells against the tolerogen. Responses of normal CBA CTL against Dd as well as anti-third party responses were not influenced by adsorption. Successful adsorption was also achieved on monolayers of fixed hybridoma cells. Monolayers of Dd-specific hybridomas specifically removed suppressor cells from CBA mice tolerant to Dd; they failed to adsorb suppressor cells from AKR mice tolerant to H-2b. Immunofluorescence analysis with antibodies specific for determinants on tolerizing cells showed the presence of donor-derived F1 cells on the monolayer. Under the experimental circumstances described suppressor cells are most likely removed by recognition of their MHC determinants by the monolayer population. These data suggest that neonatal tolerance is actively maintained by donor-derived suppressor cells.

Cytotoxic T-cell precursors revealed in neonatally tolerant mice

Induction of neonatal tolerance leads to a profound reduction in cytotoxic T-lymphocyte precursor frequencies against the tolerated alloantigen ("tolerogen") as evaluated by limiting-dilution analysis. The curves obtained were linear within the range tested and, thus, did not yield evidence for any dissociation of cytotoxic precursors from regulatory cell populations. However, it could be shown that cytotoxic T-lymphocyte precursor frequencies against the tolerogen increased drastically if the tolerant spleen cells were adsorbed, prior to limiting-dilution culture, on monolayers of syngeneic blasts expressing receptors for the tolerogen but not if they were adsorbed on syngeneic blasts against third-party antigens. This finding implies that cytotoxic precursor cells against the tolerogen are not clonally deleted in tolerant animals but rather are suppressed by a regulatory cell population that is present at high frequency and presumably acts in an anti-idiotypic fashion.