Early-outgrowth of endothelial progenitor cells can function as antigen-presenting cells

Endothelial progenitor cells (EPCs) have been recently found to exist circulating in peripheral blood of adults, and home to sites of neovascularization in peripheral tissues. They can also be differentiated from peripheral blood mononuclear cells (PBMNCs). In tumor tissues, EPCs are found in highly vascularized lesions. Few reports exist in the literature concerning the characteristics of EPCs, especially related to their surface antigen expressions, except for endothelial markers. Here, we aimed to investigate the surface expression of differentiation markers, and the functional activities of early-outgrowth of EPCs (EO-EPCs), especially focusing on their antigen-presenting ability. EO-EPCs were generated from PBMNCs, by culture in the presence of angiogenic factors. These EO-EPCs had the morphological and functional features of endothelial cells and, additionally, they shared antigen-presenting ability. They induced the proliferation of allogeneic lymphocytes in a mixed-lymphocyte reaction, and could generate cytotoxic lymphocytes, with the ability to lyze tumor cells in an antigen-specific manner. The antigen-presenting ability of EO-EPCs, however, was weaker than that of monocyte-derived dendritic cells, but stronger than peripheral blood monocytes. Since EO-EPCs play an important role in the development of tumor angiogenesis, targeting EPCs would be an effective anti-angiogenic strategy. Alternatively, due to their antigen-presenting ability, EO-EPCs can be used as the effectors of anti-tumor immunotherapy. Since they share endothelial antigens, the activation of a cellular immunity against angiogenic vessels can be expected. In conclusion, EO-EPCs should be an interesting alternative for the development of new therapeutic strategies to combat cancer, either as the effectors or as the targets of cancer immunotherapy.     

Glia as antigen-presenting cells in the central nervous system

The contribution of the cells within the central nervous system (CNS) toward adaptive immune responses is emerging and incompletely understood. Recent findings indicate important functional interactions between T-cells and glial cells within the CNS that may contribute to disease and neuropathology through antigen presentation. Although glia are not classically considered antigen-presenting cell (APC) types, there is growing evidence indicating that glial antigen presentation plays an important role in several neurological diseases. This review discusses these findings which incriminate microglia, astrocytes, and oligodendrocyte lineage cells as CNS-resident APC types with implications for understanding disease.     

Interactions of HIV-1 with antigen-presenting cells.

There is currently much interest in the numerical and functional loss of antigen-presenting cells (APC) in HIV-1 disease and the contribution that this may make to HIV-1 pathology. The HIV-1 virus can interfere with the normal function of APC in a number of ways involving inappropriate signalling. These include changes in cytokine balance, cell-surface molecule expression and intracellular signalling pathways. This review examines how HIV-1 is able to disregulate APC function and discusses possible outcomes for the function of the immune system.     

Human dendritic cells: potent antigen-presenting cells at the crossroads of innate and adaptive immunity

Dendritic cells (DCs) are specialized, bone marrow-derived leukocytes that are critical to the development of immunity. Investigators have emphasized the role of DCs in initiating adaptive or acquired MHC-restricted, Ag-specific T cell responses. More recent evidence supports important roles for DCs in the onset of innate immunity and peripheral tolerance. Progress in the generation of DCs from defined hemopoietic precursors in vitro has revealed the heterogeneity of these APCs and their attendant divisions of labor. This review will address these developments in an attempt to integrate the activities of different DCs in coordinating innate and adaptive immunity.     

T cell development in B cell-deficient mice. IV. The role of B cells as antigen-presenting cells in vivo

B cell-deficient, rabbit anti-mouse IgM-treated mice were compared with normal or normal rabbit immunoglobulin-treated controls in their ability to develop proliferative T cell responses, delayed hypersensitivity, and primary or secondary cytotoxic T cell responses. Immunization with hapten-coupled autologous spleen cells resulted in anti-mu-treated mice generating only marginal T cell responses. This decreased responsiveness was shown to be attributable not to an intrinsic T cell defect or to changes in the ability of macrophages from anti-mu-treated mice to present soluble antigen, but rather to the greatly diminished capacity of B cell-deficient spleen cells to present antigen. The results support the concept that B cells play a significant role in antigen presentation required for T cell activation.     

Artificial antigen-presenting cells as a tool to exploit the immune 'synapse'

Recent progress in molecular medicine has provided important tools to identify antigen-specific T cells. In most cases, the approach is based on oligomeric combinations of recombinant major histocompatibility complex-peptide complexes fixed to various rigid supports available for binding by the T-cell receptor. These tools have greatly increased our insight into mechanisms of immune responses mediated by CD8+ T cells. Examples of the diverse fields of application for this technology include immunization, viral infections and oral tolerance induction.     

B cells as antigen-presenting cells: antibody production in vitro against a T-dependent antigen

It was examined whether B cells can serve as antigen-presenting cells (APC) in the antibody response to a T-dependent antigen, trinitrophenyl-ovalbumin (TNP-OVA). B cells purified from mice primed with TNP (TNP-B cells) responded to TNP-OVA in the presence of purified T cells sensitized with OVA (OVA-T cells). OVA-T cells required the addition of APC to proliferate in response to TNP-OVA. APC activity of TNP-B cells in the T-cell proliferation was abolished by 4000 R irradiation. Our experiments also revealed that an antibody response requires more adherent cells than the T-cell proliferation. These results indicate that adherent cells possibly accompanying the T- and B-cell preparations were at a less than functional level. There was genetic restriction between T and B cells for the antibody response. B cells in the pellet fraction of 70% Percoll density sedimentation behaved similarly to the unfractionated TNP-B cells in the antibody response. A T-cell clone specific for human gamma-globulin (HGG) also induced an anti-TNP antibody response in B cells from unprimed mice in the presence of TNP-HGG. These results suggest that B cells are able to elicit an antibody response to a T-dependent antigen in the presence of carrier-primed T cells without the participation of macrophages.     

Astrocytes as antigen-presenting cells: expression of IL-12/IL-23

Interleukin-12 (IL-12, p70) a heterodimeric cytokine of p40 and p35 subunits, important for Th1-type immune responses, has been attributed a prominent role in multiple sclerosis (MS) and its animal model, experimental autoimmune encephalomyelitis (EAE). Recently, the related heterodimeric cytokine, IL-23, composed of the same p40 subunit as IL-12 and a unique p19 subunit, was shown to be involved in Th1 responses and EAE. We investigated whether astrocytes and microglia, CNS cells with antigen-presenting cell (APC) function can present antigen to myelin basic protein (MBP)-reactive T cells, and whether this presentation is blocked with antibodies against IL-12/IL-23p40. Interferon (IFN)-gamma-treated APC induced proliferation of MBP-reactive T cells. Anti-IL-12/IL-23p40 antibodies blocked this proliferation. These results support and extend our previous observation that astrocytes and microglia produce IL-12/IL-23p40. Moreover, we show that stimulated astrocytes and microglia produce biologically active IL-12p70. Because IL-12 and IL-23 share p40, we wanted to determine whether astrocytes also express IL-12p35 and IL-23p19, as microglia were already shown to express them. Astrocytes expressed IL-12p35 mRNA constitutively, and IL-23 p19 after stimulation. Thus, astrocytes, under inflammatory conditions, express all subunits of IL-12/IL-23. Their ability to present antigen to encephalitogenic T cells can be blocked by neutralizing anti-IL-12/IL-23p40 antibodies.     

Chemically modified antigen-presenting cells induce T lymphocyte allospecific hyporesponsiveness.

We have investigated the interaction between murine T lymphocytes and allogeneic APC in an in vitro proliferative mixed leukocyte reaction. Our results demonstrate that freshly isolated potentially alloreactive murine splenic T lymphocytes, in primary culture, can be induced to develop a state of allospecific proliferative hyporesponsiveness in vitro by exposure to 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide-modified allogeneic APC, a method similar to that previously used to induce nonresponsiveness in murine Ag-specific self-MHC-restricted T lymphocyte clones. This hyporesponsiveness was: specific for the allohaplotype of inducing APC, maintained for 96 h in vitro, not due to cellular inhibitory mechanisms, and associated with reduced ability to secrete IL-2 but not IL-3. Induction of this hyporesponsiveness was not due to altered expression of class II MHC gene products on the APC but was associated with markedly reduced T lymphocyte-APC adhesive interactions despite the lack of a detectable immunophenotypic change in lymphocyte function-associated Ag 1 (LFA-1) and intercellular adhesion molecule 1 (ICAM-1) expression on the modified APC. Therefore, we propose that TCR occupancy in the absence of normal T lymphocyte-APC adhesive clustering may induce T lymphocyte tolerance.     

Inducer T-cell-mediated killing of antigen-presenting cells

L3T4+ inducer/helper T-cell clones, once activated by antigen-presenting cells (APC) expressing the appropriate Ia allele and antigen, autonomously kill their target APC. All 13 L3T4+ inducer T-cell clones tested demonstrated this cytolytic activity. In addition, 11 different target cells representing the three major APC types, namely, macrophages, B cells, and dendritic cells, were all sensitive to this cytolytic activity. Moreover, normal macrophages which were treated with interferon-gamma to increase Ia expression were also killed. These observations convincingly demonstrate that the cytolytic activity of L3T4+ inducer T-cell clones is a general phenomenon. In contrast to other reports, lysis of target APC could not be detected following 4-6 hr of incubation. Marginal lysis was observed after 9 hr and a 20-hr incubation period was required to achieve maximal killing. The kinetics of killing paralleled other parameters of T-cell activation such as IL-2 release and cell proliferation. Activation of T cells for cytolysis of APC requires the interaction of T-cell receptors with Ia and antigen. Monoclonal antibody to Ia, L3T4 and the T-cell receptor inhibited the cytolysis of APC. The ability to mediate nonspecific bystander killing was variable depending on both the T-cell clone and the target. The implications of these findings to immune regulation and autoimmunity are discussed.     

Naked antigen-presenting molecules on dendritic cells

Antigen-presenting cells work to present peptides derived from exogenous and endogenous antigens to circulating T cells, sparking off an immune response. Dendritic cells are unique amongst antigen-presenting cells, not least for their newly described ability to circumvent the need to internalize exogenous antigens before presenting them.     

Induction of peripheral T cell tolerance by antigen-presenting B cells. II. Chronic antigen presentation overrules antigen-presenting B cell activation

Ag presentation in the absence of danger signals and Ag persistence are the inductive processes of peripheral T cell tolerization proposed so far. Nevertheless, it has never been definitively shown that chronic Ag presentation per se can induce T cell tolerance independent of the state of activation of APCs. In the present work, we investigated whether chronic Ag presentation by either resting or activated B cells can induce tolerance of peripheral Ag-specific T cells. We show that CD4(+) T cells that re-encounter the Ag for a prolonged period, presented either by resting or activated Ag-presenting B cells, become nonfunctional and lose any autoimmune reactivity. Thus, when the main APCs are B cells, the major mechanism responsible for peripheral T cell tolerization is persistent Ag exposure, independent of the B cell activation state.     

Regulation of antigen-presentation-I. IFN-gamma induces antigen-presenting properties on B cells

B cells require activation to efficiently present Ag to T cells. In agreement with this earlier observation we show that live, mitomycin C-treated B cells, but not B cells fixed in paraformaldehyde, stimulated the growth of allogeneic T cells in the primary MLR. However, if B cells were cultured with anti-Ig antibodies and IFN-gamma before fixation they acquired excellent T cell stimulatory activity. Neither reagent alone conferred this novel co-stimulatory function on the B cell surface. The activity induced by both stimuli was not attributed to an increase expression of class II-MHC molecules or IL-1. IL-2 or IL-4, in combination with anti-Ig, also induced B cell stimulatory activity, but were less effective than IFN-gamma. TNF failed to stimulate B cells, but synergized with IFN-gamma in the induction of this activity. These studies therefore demonstrate an important role for lymphokines in modulating B cell Ag-presenting activity as well as the acquisition by B cells of a novel co-stimulatory surface activity.     

Semaphorins in interactions between T cells and antigen-presenting cells

Although semaphorins were identified originally as guidance cues for developing neuronal axons, accumulating evidence indicates that several semaphorins are expressed also in the immune system. SEMA4D (CD100), which is expressed constitutively by T cells, enhances the activation of B cells and dendritic cells (DCs) through its cell-surface receptor, CD72. SEMA4A, which is expressed by DCs, is involved in the activation of T cells through interactions with TIM2. So, these semaphorins seem to function in the reciprocal stimulation of T cells and antigen-presenting cells (APCs). Emerging evidence indicates that additional semaphorins and related molecules are involved in T-cell-APC interactions also.     

Cationization of protein antigens. IV. Increased antigen uptake by antigen-presenting cells

Cationization of BSA generates a molecule that mounts antibody responses of increased magnitude and duration and induces T cell proliferation at concentrations 500 times less than native BSA (nBSA). To explain the alteration in immunogenic properties of this Ag, the uptake of nBSA and cationized BSA (cBSA) by splenic APC has been investigated. T cell proliferation assays were conducted with nBSA and cBSA preparations with varying degrees of substitution. An inverse correlation between the degree of cationization and the amounts of Ag needed for optimal T cell reactivity was observed. To determine whether affinity for APC resulted in an increased uptake of cBSA, splenic APC were incubated with nBSA or cBSA for varying amounts of time. Comparisons were made at each time point between untreated Ag-pulsed APC (Ag uptake) and paraformaldehyde-fixed Ag-pulsed APC (processed Ag). Proliferation of T cells primed with nBSA or cBSA increased in proportion to the amount of time of APC exposure to high concentrations of nBSA, first appearing after a 2-h pulse and peaking at 8 h. Conversely, untreated APC needed only a 30-min cBSA exposure to induce either nBSA- or cBSA-primed T cell proliferation, indicating a rapid uptake of cBSA. Comparisons with proliferation induced by paraformaldehyde-fixed cBSA APC indicate that nBSA T cells recognize a lag phase-processed form of cBSA, whereas a majority of cBSA T cells recognize either a rapidly processed form of cBSA, or a membrane-processed cBSA molecule without a classical lag phase processing event. When monensin was used as an inhibitor of fluid phase pinocytosis in splenic APC, the presentation of nBSA was inhibited by 85%, but the presentation of cBSA was inhibited by only 20%. These results imply that nBSA enters the cell by fluid phase pinocytosis, whereas cBSA enters by a nonspecific adsorptive mechanism. The different modes of cellular entry for the two molecules, nBSA and cBSA, resulting in a rapid uptake of cBSA, may have important ramifications on T cell activation and immunoregulation.     

B lymphocytes as antigen-presenting cells for CD4+ T cell priming in vivo

The contribution of B lymphocytes as APCs for CD4+ T cell priming remains controversial, based on findings that B cells cannot provide the requisite ligating and costimulatory signals for naive T cells to be activated. In the current study, we have examined Ag-specific T:B cell collaboration under circumstances in which B cells take up Ag through Ig receptors in vivo. This results in their activation and an ability to effectively stimulate naive CD4+ T cells both in vitro and in vivo. The aim of this work was to establish some of the key molecular interactions, as well as kinetics, between Ag-specific T and B cells that enable this priming to take place. Our approach was to amplify the starting pools of both Ag-specific T and B cell populations in vivo to track directly the events during initial T:B cell collaborations. We show that the induction of optimal levels of T cell priming to a protein Ag requires the involvement of Ag-specific B cells. The interaction that results between Ag-specific T and B cells prevents the down-modulation of B7 costimulatory molecules usually observed in the absence of appropriate T cells. Moreover, this prevention in down-modulation is independent of CD40:CD40 ligand contact. Finally, we present data suggesting that once Ag-specific T and B cells interact, there is a rapid (1-2-h) down-regulation of antigenic complexes on the surface of the B lymphocytes, possibly to prevent them from engaging other T cells in the vicinity and therefore focus the initial interaction.     

Differentiation of myoblasts and CNS cells grown either separately or as co-cultures on microcarriers

Dispersed neuronal and muscular elements from fetal or neonatal origin, can organize and mature in culture when grown on positively charged cylindrical microcarriers (MCS), to a stage which simulatein vivo maturation. Cells arrange themselves on the MCS to form aggregates which remain floating in the nutrient medium. In such a tridimensional organization, the neuronal tissue is capable of regenerating a network of nerve fibers which establish synapse interconnections and undergo myelination. Oligodendrocytes organize on MCS in a tridimensional pattern and produce extensive myelin-like membranes. Myoblasts in MC-cultures fuse into polynucleated myotubes which become striated and contract spontaneously. Creatine kinase and acetylcholine receptor (AChR) are formed during myogenesis in similar quantities in MC-cultures and in monolayers. When both neuronal and muscle tissues are prepared from the same fetus (autologous nerve-muscle co-cultures) and are cultured on MCS, they interconnect to form neuro-muscular junctions. Cells from both tissues, exhibit better differentiation, for longer periods in MC-cultures than they do in monolayers. The floating functional entities are easy to sample and can be harvested for ultrastructural, immunocytochemical and biochemical analysis. In addition, MC-cultures can be used as a good tool for the study of acute and chronic exposures to toxicological agents, as well as for implantation into demyelinated, injured or dystrophic tissues. In this case the MCS in the implanted entities will serve as identifiable markers.     

B cells as antigen-presenting cells: antigen-specific IL-2 production by cloned T cells without expression of IL-2 receptors

A murine T cell clone, 24-2C, responds specifically to human IgG (HGG) in the context of I-Ab. B cells purified from mouse spleen cells were examined for their function as antigen-presenting cells (APC) in the response of 24-2C cells to HGG. B cells functioned as APC for IL-2 production but not for proliferation, whereas spleen cells or spleen-adherent cells functioned as APC for both IL-2 production and proliferation. LPS-activated B cells also failed to induce the proliferative response. The addition of the culture supernatant of 24-2C cells stimulated with HGG presented by irradiated spleen cells to the culture of 24-2C cells, irradiated B cells, and HGG induced the proliferative response of 24-2C cells, whereas IL-1, IL-3, and/or interferon-gamma did not reconstitute the proliferation. The expression of IL-2 receptors (IL-2R) on 24-2C cells was examined using a monoclonal anti-mouse IL-2R antibody AMT 13 or 7D4. 24-2C cells cultured with spleen cells as APC expressed IL-2R. Those cultured alone or with B cells as APC did not express IL-2R. Enlargement of 24-2C cells in response to HGG was also examined, and the relative cell size of those cultured with B cells or spleen cells as APC was larger than that of those cultured alone. These results demonstrate that B cells as APC induce IL-2 production and cell size enlargement in the response of 24-2C cloned T cells to HGG, but not IL-2R expression nor proliferation.