The function of Ia+ dendritic cells and Ia- dendritic cell precursors in thymocyte mitogenesis to lectin and lectin plus interleukin 1

Pulmonary antigen presenting cells: isolation, purification, and culture

Antigen presenting cells (APCs) such as dendritic cells (DCs) and macrophages comprise a relatively small fraction of leukocytes residing in lymphoid and non-lymphoid tissues. Accordingly, functional analyses of these cells have been hampered by low cell yields. Also, alveolar macrophages share several physical properties with DCs, and this has complicated efforts to prepare pure populations of lung APCs. To overcome these difficulties, we have developed improved flow cytometry-based methods to analyze and purify APCs from the lung and its draining lymph nodes (LNs). In this chapter, we describe these methods in detail, as well as methods for culturing APCs and characterizing their interactions with T cells.

B cell-dependent TCR diversification

T cell diversity was once thought to depend on the interaction of T cell precursors with thymic epithelial cells. Recent evidence suggests, however, that diversity might arise through the interaction of developing T cells with other cells, the identity of which is not known. In this study we show that T cell diversity is driven by B cells and Ig. The TCR V beta diversity of thymocytes in mice that lack B cells and Ig is reduced to 6 x 10(2) from wild-type values of 1.1 x 10(8); in mice with oligoclonal B cells, the TCR V beta diversity of thymocytes is 0.01% that in wild-type mice. Adoptive transfer of diverse B cells or administration of polyclonal Ig increases thymocyte diversity in mice that lack B cells 8- and 7-fold, respectively, whereas adoptive transfer of monoclonal B cells or monoclonal Ig does not. These findings reveal a heretofore unrecognized and vital function of B cells and Ig for generation of T cell diversity and suggest a potential approach to immune reconstitution.

Granulocyte-macrophage colony stimulating factor is an anti-apoptotic cytokine for thymic dendritic cells and a significant modulator of their accessory function

Granulocyte-macrophage colony-stimulating factor (GM-CSF) is a growth-promoting factor for myeloid-derived dendritic cells (DC) but not for lymphoid DC. The data about its effect on thymic DC (TDC), which are both of lymphoid and myeloid origin, are very scarce. Using an in vitro model, we demonstrated in this work that GM-CSF significantly increased the survival of rat TDC in culture by inhibiting their apoptosis and the effect correlated with up-regulation of Bcl-2 expression. GM-CSF also stimulated differentiation and maturation of TDC as judged by higher expression of MHC class I and II molecules, CD54, CD80 and CD86. These changes correlated with stronger stimulatory activity of GM-CSF-pulsed TDC in syngeneic thymocyte proliferation assay and MLR. The stimulatory potential of TDC was further increased when thymocytes were cultivated with an anti-alphabeta TCR (R73) monoclonal antibody (mAb). The influence of unstimulated TDC on proliferation of thymocytes was inhibited by anti-CD86 but not anti-CD80 mAb, whereas in cultures with GM-CSF-treated TDC both mAbs exerted an additive blocking effect. After separation of TDC on CD11b(+) and CD11b(-) we demonstrated that GM-CSF inhibited apoptosis and potentiated accessory activity of both TDC subsets independently of the myeloid marker expression. Cummulatively, our results suggest that GM-CSF is one of the regulatory cytokine involved in survival, maturation, differentiation and accessory function of TDC.

Dendritic cells: a specialized complex system of antigen presenting cells

The dendritic cell (DC) network is a specialized system for presenting antigen to naive or quiescent T cells, and consequently plays a central role in the induction of T cell and B cell immunity in vivo. Despite considerable achievements in the last ten years, in our understanding of how DC induce and regulate immune responses, much remains to be learned about this complex system of cells. The history and current status of DC termed "directors of the immune system orchestra" is reviewed. The present understanding of DC cell biology, function and use, taking into account their complexity is discussed.

Purified donor T cells alone activate transplantation immunity to the male antigen but induce tolerance in combination with Mac-1+ donor cells

BACKGROUND

In most experimental systems examined, "professional" antigen-presenting cells (APCs), such as dendritic cells, have been found to activate T cells, whereas "nonprofessional" antigen-bearing cells (nonAPC) may induce tolerance. Some recent studies have suggested that nonAPCs may under certain conditions prime a T-cell immune response. We have attempted to separate the roles of transplanted T cells and monocytic/dendritic cells in activating or tolerizing antigen-specific T cells in vivo, by examining the consequences of parenteral exposure to male antigen in anti-male TCR transgenic female mice.

METHODS

Qualitative and quantitative changes in the large population of male-reactive transgenic T cells to various male donor cell populations in transgenic female mice were followed after injections of highly purified male lymphoid cells. Changes in male-reactive T cells with time and the long-term outcome of male skin grafts were measured.

RESULTS

When a nonAPC population consisting of highly purified male T cells alone was injected intravenously into H-Y antigen-specific TCR transgenic female mice, the number of host transgenic T cells was sustainably increased, and male graft rejection was accelerated. Injection of a combination of purified T cells and purified Mac-l+ cells induced massive and permanent deletion of the host male-reactive T-cell population and permanent graft tolerance. Mac-l+ cells alone gave no appreciable change in responsive T cells or graft rejection times.

CONCLUSIONS

The data indicate that highly purified T cells engrafted alone induce rapid sensitization toward the male antigen. They also show that both male donor T cells and a population of male monocytic/ dendritic cells are required to induce peripheral tolerance toward this antigen and that this tolerance is related to permanent peripheral deletion of male-reactive T cells.

Immunomodulation by iscoms, immune stimulating complexes

The iscom is a uniform stable complex consisting of cholesterol, phospholipid, adjuvant-active saponin, and antigen. The iscom matrix is a particulate complex with identical composition, shape, and morphology, but lacking the incorporated antigen. The assembly of the complex is based on hydrophobic interactions, but antigens that are not hydrophobic can be conjugated with a hydrophobic tail or hidden hydrophobic regions can be exposed, e.g., by acid treatment, to facilitate the incorporation into iscoms. The functional aspects of iscoms are described emphasizing immunomodulation in mouse models. Iscoms prominently enhance the antigen targeting, uptake, and activity of antigen presenting cells including dendritic and B cells and macrophages resulting in the production of proinflammatory cytokines, above all interleukin (IL)-1, IL-6, and IL-12. The expression of costimulatory molecules major histocompatibility complex (MHC) class II, B7.1 and B7.2, is also enhanced. The latter partly explains why the iscom is an efficient adjuvant for elderly mice. Iscoms enhance the Th1 type of response with increased production of IL-2 and interferon gamma. However, with some antigens and particularly in monkeys immunized with HIV iscoms, the production of IL-4 was enhanced. IL-4, IL-2, and interferon gamma (IFNgamma) together with the beta chemokines MIP-1alpha and MIP-1beta correlated with protection against challenge infection with a chimeric virus (simian immunodeficiency virus-human immunodeficiency virus). Iscoms were also shown to induce a potent immune response in the newborn and to be an efficient delivery system for mucosal administration. Technical information is given about formulation of iscoms and about handling of antigens to optimize their incorporation into iscoms.

Flt3 Ligand Plus IL-7 Supports the Expansion of Murine Thymic B Cell Progenitors That Can Mature Intrathymically

Flt3 ligand (flt3L) has potent effects on hemopoietic progenitors, dendritic cells, and B lymphopoiesis. We have investigated the effects of flt3L on intrathymic precursors. The addition of flt3L + IL-7 to lobe submersion cultures of murine fetal thymic lobes resulted in the expansion of an immature population of Thy-1low, CD44high, HSAhigh cells. This population contained cells with precursor activity, as determined by their capacity to repopulate deoxyguanosine-treated fetal thymic lobes. Upon reentry to the thymic lobe, flt3L + IL-7-cultured Thy-1low, CD44high, HSAhigh cells underwent expansion and differentiation into B cells. Two weeks after fetal thymic organ culture following thymic lobe reconstitution, intrathymic cells were Thy-1−, B220+, and a subset was sIgM+. The intrathymic B cells shared features of adult thymic B cells, including CD5 expression and proliferative responses to IL-4 + IL-5 + CD40 ligand, but not to LPS or soluble anti-IgM. Ig production was noted upon stimulation with IL-4 + IL-5 + LPS and IL-4 + IL-5 + CD40 ligand. In conclusion, we have demonstrated that flt3L + IL-7 supports the expansion of a subset of progenitors present in the fetal thymus. The cultured progenitors can repopulate a fetal thymic lobe and develop into mature functional B cells, demonstrating that the fetal thymus is able to support B cell as well as T cell development.

Effect of macrophage colony-stimulating factor (M-CSF) on mouse immune responses in vivo

We examined the effects of recombinant human M-CSF (rhM-CSF) on mouse macrophages and immune responses in vivo. Intraperitoneal administration of rhM-CSF (20-500 microgram/ml) increased Mac-1+ cell numbers in the peritoneal cavity. The tumoricidal activities of the macrophages from vehicle-administered (V-M phi) and from rhM-CSF-administered (M-M phi) mice were the same as those observed in vitro. However, when activated by lipopolysaccharide (LPS), the tumoricidal activity of M-M phi was stronger than that of V-M phi. Intravenous administration of rhM-CSF (500 micrograms/gk) increased the number of spleen cells. Flow cytometric analysis showed that administration of rhM-CSF increased Mac-1+, B220+ and NK 1.1+ cell counts in the spleen. However, CD4+ and CD8+ cell numbers did not change. Concomitant increases were observed in levels of IL-4 and IL-10 in mouse serum following rhM-CSF administration, but no significant changes were observed in the serum level of IFN-gamma. In experiments involving mouse immune responses, the administration of rhM-CSF reduced the contact sensitivity (CS) reaction against picryl chloride (PC) and augmented IgE production in response to 2,4-dinitrophenyl (DNP), but did not affect the production of either IgM or IgC1. These results suggest that administration of rhM-CSF not only activates murine macrophages, but modulates antigen-specific immune responses in vivo.

Human thymic dendritic cells

ABSTRACT Human thymic dendritic cells (DC) represent a member of the bone marrow-derived dendritic cell family. They have a dendritic shape and are found in small numbers mainly at the corticomedullary border and in medullary regions of the thymus. Human thymic DC were isolated by density gradient separation, followed by treatment with CD2, CD7, CD1, and CD11b mAb and immunobeads magnetic separation. The resulting population contains 60-75% brightly HLA-DR+ cells which present the morphological characteristics of DC observed in situ. Extensive phenotypic analysis confirmed that they are of mesenchymal origin and that some express CD11a and CD54 molecules. Freshly isolated DC do not stain with a wide variety of anti-T-B and -monocyte or -macrophage mAb. However, they acquire the CD1 molecule after a few days in culture. By using a cell sorter we obtained 90-95% of purified human thymic DC. Functional studies have shown that human thymic DC are potent activators in mixed lymphocyte reactions, act as accessory cells in mitogenic thymocyte proliferation, increase the thymocyte proliferative response to a toxin signal, and produce IL-1. They also formed spontaneous physical associations with thymocytes, which raises questions about the implication of DC in differentiation and/or maturation processes of thymocytes.

Physiology and pathophysiology of dendritic cells

Dendritic cells are antigen-presenting cells derived from the hematopoietic stem cell. The dendritic cell family includes Langerhans' cells (CD1a-positive dendritic cells of the skin), and antigen-presenting cells that are found in the lymphoreticular system and throughout the organ parenchyme. Dendritic cells play a key role in both the primary and secondary immune responses. Several studies indicate that these cells participate in antitumor immunity, tumor surveillance, graft-versus-host disease, and in the pathogenesis of clinical syndromes of unknown origin or those induced by viruses, such as the human immunodeficiency virus. Different disorders are characterized by an abnormal proliferation and accumulation of dendritic cells; for example, the Langerhans' histiocytes, which accumulate in Langerhans' cell histiocytosis. In this review the immunophenotypic, morphological, and functional characteristics of the dendritic cell family is described. The clinical and laboratory studies suggesting a unique role for these cells in various syndromes and diseases are reviewed. The Langerhans' cell histiocytoses and the malignant disorders associated with transformation of cells belonging to the dendritic cell family, are discussed.

Antigen-presenting-cell function of interferon gamma-treated human gingival fibroblasts

The present study was carried out to examine the antigen-presenting cell (APC) functions of human gingival fibroblasts (HGF) elicited with IFN gamma. Stimulation of HGF with IFN gamma clearly induced HLA-DR expression and enhanced expression of intercellular adhesion molecule-1 (ICAM-1) on HGF. Despite the phenotypical resemblance of IFN gamma-treated HGF to so-called APC, HLA-DR positive HGF were unable to induce proliferation of allo-reactive peripheral blood T cells (PBT) isolated from different donors. The failure of IFN gamma-treated HGF to stimulate unprimed allo-reactive PBT was not due to the lack of production of IL-1 or the immunosuppressive effect of PGE2 from HGF. On the other hand, the fact that detectable expression of CD80, ligand for CD28, was not found on IFN gamma-treated HGF may at least in part explain the ineffective function of HGF as APC. Interestingly, IFN gamma-treated HGF induced proliferation of primed allo-reactive CD4+ T cells in a HLA-DR dependent manner, suggesting that IFN gamma-treated HGF may have the ability to stimulate pre-activated T cells. We then confirmed that high levels of IFN gamma mRNA were detectable in inflamed gingival tissue. Although it cannot be concluded from this study that HGF are incapable of effectively presenting antigenic peptides to autologous T cells bearing appropriate T cell receptors, present results suggest that HGF may be affected by locally-secreted IFN gamma and that the IFN gamma-stimulated HGF may play a role in regulating immune responsiveness in inflammatory periodontal lesions.

Diagnostic strategies of periodontitis based on the molecular mechanisms of periodontal tissue destruction

OBJECTIVE

Periodontitis is a disease showing differences in disease progression between patients and between sites within a patient. Routine clinical examinations today are not useful enough to distinguish susceptible patients and active lesions from resistant patients and chronic lesions. Diagnostic markers should be pathogenic and inflammatory factors participating in periodontal tissue destruction. These are both local and systemic factors.

MATERIALS AND METHODS

First of all, pathogenic factors and proinflammatory cytokines or mediators in gingival crevicular fluid (GCF) were examined and the difference was found between active and inactive periodontitis lesions distinguished by attachment loss. Active lesions were detected by discriminant-function analysis of these examinations, although the sensitivity of differential diagnosis was low. Then, we established a novel needle biopsy for understanding the pathophysiological conditions elicited in active and chronic inflammatory processes of periodontal tissue destruction. A variety of cytokines and mediators were detected in biopsied specimens by reversed transcription polymerase chain reactions (RT-PCR). Cytokine profiles were varied in inflammed periodontal biopsies. As IFN gamma mRNA expression was enhanced in inflamed gingiva, antigen-presenting-cell (APC) functions of human gingival fibroblasts (HGF) were examined.

RESULTS

Despite the phenotypical resemblance of IFN gamma-treated HGF to so-called APC, HLA-DR positive HGF could not induce proliferation but suppressed proliferation of alloreactive peripheral blood T cells (PBT). However, HLA-DR positive HGF stimulated the proliferative responses of PBT which had been primed with allo-APC. Regulatory immune responses by IFN gamma were different in T cell conditions.

CONCLUSIONS

Various kinds of cytokines participated in periodontal inflammation, and every cytokine is multi-functional. Complex and compound inflammatory processes can be clarified by examining cytokine networks and the precise effects of each cytokine on each of the cell types comprising periodontal tissue. It is, therefore, necessary for establishing diagnostic strategies to integrate pathogenic and inflammatory factors in periodontal tissue destruction.

Dendritic cells: origin and differentiation

Dendritic cells (DC) are bone marrow-derived cells that are specialized to take up, process and present antigen, and have the capacity to stimulate resting T cells in the primary immune response. DC are a unique population that is likely to derive from a myeloid precursor cell. DC differentiation from bone marrow precursors in enhanced by the cytokines GM-CSF and tumor necrosis factor-alpha. In contrast, it has been proposed that thymic DC and T cells arise from a common stem cell, and that these DC play a specific role in the negative selection of thymic T cells. A number of post-bone marrow differentiation stages can be defined phenotypically and functionally. Undifferentiated DC have very active endocytic pathways, including receptor-mediated endocytosis involving a mannose/beta glucan receptor, and macropinocytosis of soluble antigen. In contrast, later stages of maturation are associated with a decreased ability to take up and process antigen, and increasing expression of major histocompatibility complex, adhesion and costimulatory molecules. Finally, activation of DC for full antigen-presenting cell function can be identified by the expression of CD28 ligands. The inflammatory site in rheumatoid arthritis is a human model of DC differentiation in response to a chronic antigenic stimulus. The features of this DC model are discussed.

Interleukin-1 receptor antagonist suppresses contact hypersensitivity

Interleukin-1 receptor antagonist (IL-1ra), a naturally occurring inhibitor of interleukin-1 (IL-1), blocks IL-1 binding to its receptors but has no agonistic activity. IL-1 is thought to play an important role in contact hypersensitivity (CHS), although the effects of exogenously administered IL-1 in CHS have been somewhat controversial. To clarify the role of IL-1 in CHS, we studied the effect of IL-1 receptor blockade using exogenous IL-1ra and evaluated these effects on CHS. We examined the in vivo effects of local administration of recombinant human IL-1ra in the murine CHS model. Local injection of IL-1ra to sensitized BALB/c mice just before challenge with dinitrofluorobenzene resulted in a significant reduction in the intensity of CHS responses, assessed by ear swelling. A dose-response study revealed that maximal inhibition of ear swelling (36% to 43%) was observed after intradermal injection of IL-1ra at doses of 10 to 100 micrograms/ear. This reduction in ear swelling in IL-1ra-injected ears consisted of less inflammatory cell infiltration and decreased edema in the dermis compared with controls. Suppression of CHS was observed when IL-1ra was applied in the 24-h interval preceding challenge with dinitrofluorobenzene, whereas no suppressive effect was observed when IL-1ra was applied 48 h before or after the challenge. Local administration of IL-1ra to naive mice 5 h before sensitization also suppressed CHS responses. However, IL-1ra injection did not suppress phenol-induced inflammation. These results suggest that IL-1ra is an effective inhibitor of both the sensitization and elicitation phases of CHS expression in mice, thus emphasizing the role of IL-1 as an immunologic potentiator of responses associated with CHS.

Understanding the dendritic cell lineage through a study of cytokine receptors

Dendritic cells form a system of antigen presenting cells that are specialized to stimulate T lymphocytes, including quiescent T cells. The lineage of dendritic cells is not fully characterized, although prior studies have shown that growth and differentiation are controlled by cytokines, particularly granulocyte/macrophage colony-stimulating factor (GM-CSF). To further elucidate the nature and control of the dendritic cell lineage, we have studied the expression of specific cytokine receptors. Sufficient numbers of dendritic cells were purified from spleen and skin to do quantitative binding studies with radiolabeled M-CSF, GM-CSF, and interleukin 1 (IL-1). To verify the nonlymphoid nature of dendritic cells, we made an initial search for rearrangements in T cell receptor and immunoglobulin genes and none were found. M-CSF binding sites, a property of mononuclear phagocytes, also were absent. In contrast, GM-CSF receptors were abundant on mature dendritic cells, with approximately 3,000 binding sites/cell with a single Kd of 500-1,000 pM. Substantial numbers of high affinity (< 100 pM) IL-1 binding sites were identified as well; cultured epidermal dendritic cells (i.e., epidermal Langerhans cells) had 500/cell and spleen dendritic cells approximately 70/cell. Cross-linking approaches showed the 80-kD species that is expected of high-affinity type 1 IL-1 receptor. Anti-type 1 IL-1 receptor (R) mAbs also visualized these receptors by flow cytometry on freshly isolated epidermal dendritic cells. These results provide new evidence that dendritic cells represent a differentiation pathway distinct from lymphocytes and monocytes. Together with recent findings on the effects of IL-1 and GM-CSF on epidermal dendritic cells in situ (see Results and Discussion), the data lead to a proposal whereby IL-1 signals IL-1R to upregulate GM-CSF receptors and thereby, the observed responsiveness of dendritic cells to GM-CSF for growth, viability, and function.

Ontogeny of rat thymic dendritic cells

In the present study we have combined various in vivo and in vitro approaches to analyse the appearance and development throughout ontogeny and postnatal life of the dendritic cell (DC) populations of rat thymus. The in situ ultrastructural study demonstrated immature interdigitating cells (IDC)/DC in the thymus of 17-day-old embryonic rats, but thymic stromal cell cultures from 16-day-old fetal rats seemed to contain DC precursors which, after several days in culture, produced strongly class II major histocompatibility complex (MHC)-positive, mature DC. According to morphology and class II MHC expression we also defined three different DC populations in the late embryonic rat thymus; two of them, which remained in the adult rat thymus, could represent distinct developmental stages within the IDC/DC lineage. The third cell subset might be involved in a massive process of negative selection, presumably occurring at the end of fetal life in the rat thymus. In supporting the existence of thymic DC subpopulations, we also demonstrated a differential expression of various cell markers, including CD4, CD8, CD25, adhesion molecules and the antigen recognized by OX44 monoclonal antibody (mAb), on thymic DC during both embryonic and adult life. Their possible significance for the attributed functions to thymic DC are discussed extensively.

Interleukin 1 alpha but not transforming growth factor beta inhibits tumor antigen presentation by epidermal antigen-presenting cells

Cutaneous I-A+ Langerhans cells are the principal antigen-presenting cells within the epidermis, capable of both initiating and eliciting CD4-dependent immune reactions. We recently demonstrated that epidermal Langerhans cells can present tumor-associated antigens and thus may be important in cutaneous tumor immunity. Despite the ability of Langerhans cells to present tumor antigens, they generally fail to induce protective tumor immunity against growing tumors in situ. We therefore investigated whether locally produced cytokines may be able to down-regulate the presentation of tumor-associated antigens and alloantigen by epidermal antigen-presenting cells in primed as well as in unprimed systems in vivo and in vitro. Naive syngeneic mice could be successfully immunized against the spindle cell tumor S1509a by injecting them with granulocyte-macrophage colony-stimulating factor-exposed and tumor-associated antigen-pulsed epidermal cells three times at weekly intervals. Co-incubation of epidermal cells in granulocyte-macrophage colony-stimulating factor and interleukin-1 alpha inhibited tumor-antigen presentation by epidermal antigen-presenting cells in this system and also inhibited alloantigen presentation in the primary mixed epidermal cell-lymphocyte reaction. Tumor necrosis factor-alpha appeared to be a significant mediator of the inhibitory effect of interleukin-1 alpha on the ability of epidermal antigen-presenting cells to induce protective tumor immunity, because addition of anti-tumor necrosis factor-alpha antibody abrogated the observed effect of interleukin-1 alpha. However, the effects of interleukin-1 alpha and tumor necrosis factor-alpha differed with regard to presentation of tumor-associated antigens by epidermal antigen-presenting cells in a primed system. Whereas incubation of epidermal cells in interleukin-1 alpha before or after tumor antigen pulse inhibited their ability to elicit a delayed-type hypersensitivity response against S1509a tumor-associated antigens in tumor-immune mice, culture in tumor necrosis factor-alpha significantly enhanced delayed-type hypersensitivity. Again, these in vivo data corresponded well to similar results obtained in vitro using the secondary mixed epidermal cell-lymphocyte reaction. Incubation of epidermal cells in transforming growth factor-beta, which has been shown to down-regulate T-cell-mediated immune responses in other systems, did not suppress tumor immunity in our assays. Thus, interleukin-1 alpha may be an important regulator of Langerhans cell antigen-presenting function, having effects that are partially mediated via interleukin-1 alpha-induced up-regulation of tumor necrosis factor-alpha secretion within the skin.

Rat thymic dendritic cells: cell surface marker variations in culture

Rat thymic dendritic cells (DC) have been analyzed by flow cytometry in order to study the variations on the cell surface marker expression upon culture at 37 degrees C. Our results demonstrate that whereas expression of major histocompatibility complex (MHC) molecules, CD45, Mac-1, LFA-1, B-cell markers, macrophage markers and some T-cell markers (as CD2, CD4 and CD8) did not undergo changes in culture, the level of expression of the adhesion molecules VLA-4 and ICAM-1, and the T-cell markers CD5, CD25 and Thy-1 increased after 14 h incubation at 37 degrees C. VLA-4, ICAM-1 and Thy-1 expression was up-regulated from intermediate to high levels, the percentage of CD5+ cells increased from 20% to 50%, and the interleukin-2 (IL-2) receptor alpha chain (CD25) was induced in 50% of DC after the culture period. These results are discussed with regard to the functional significance of DC phenotypic variations, and their implications concerning the development of in vitro systems designed for T-cell differentiation studies involving purified DC.

Characterization of unique lymphoid cells derived from murine spleen which constitutively produce interleukin-6

Attempts have been made to isolate continuous lines of rare subsets of lymphoid cells present in murine spleen in order to analyse their function and lineage relationship with respect to other lymphoid cells. Mitogenic stimulation was used to expand the lymphoid cells remaining in spleen following depletion of CD4+ and CD8+ T cells by antibody and complement treatment. Cells were cultured in the presence of concanavalin A (Con A), interleukin-2 (IL-2) and syngeneic irradiated spleen feeder cells. This procedure expanded a population of non-T-, non-B-lymphoid cells bearing a common, unique phenotype resembling lymphoid precursors. Eight cloned lines from B10.A(2R) and B10.A(5R) strains of mice have been analysed here. Analysis of cell surface marker expression has revealed positive expression of class I and class II major histocompatibility complex (MHC) antigens, CD44, CD45 (T200 and B220) but expressing no markers unique to T, B or myeloid cells. All cell lines represent agranular lymphoblasts and show no evidence of early T-cell receptor (TcR) or Ig heavy chain gene rearrangements, suggesting no commitment to T-or B-lymphoid lineage. Despite expression of the NK1.1 marker for natural killer (NK) cells, none of the cell lines has been shown to have cytotoxic function for NK targets, nor could cytotoxic function be induced following various activation procedures. Analysis of lymphokine production has revealed no detectable IL-1, IL-2, IL-3, IL-4, IL-5, tumour necrosis factor-alpha (TNF-alpha) or granulocyte-macrophage colony-stimulating factor (GM-CSF) in cell supernatants. However, all but one of these cell lines constitutively produce IL-6. Each cell line has been shown to induce T-cell proliferation independently in mixed lymphocyte reactions, implicating the capacity of these cells to act as antigen-presenting cells. Consistent with this hypothesis is the observation that these cells also demonstrate endocytic activity for foreign proteins. This was visualized by their uptake of fluoresceinated albumin into cytoplasmic granules. Since they express many cell surface markers common to described isolates of spleen dendritic cells, including both class I and class II major histocompatibility molecules, they would appear to represent the first example of continuous lines of this rare cell subset.

Treatment of fetal thymic organ culture with IL-1 leads to accelerated differentiation of subsets of CD4-CD8- cells

Using fetal thymic organ culture (FTOC), we describe the effects of IL-1 on T cell differentiation, particularly within the CD4-CD8- subset. While treatment of FTOC with IL-1 led to a modest reduction in total thymocyte yield, it induced an increase in the percentage of CD4-CD8- cells that express IL-2R early in culture and a decrease in the number of their precursors (CD44+IL-2R- cells). The increase in the percentage of cells expressing IL-2R was not accompanied by an increase in the number of these cells. At later time points these IL-2R+ cells (and their precursors) were reduced relative to controls. The total number of CD4-CD8-CD3- precursor cells in IL-1-treated cultures was reduced to approximately half that in controls at Day 12 of culture. However, only minor inhibition of total cell number was observed, which, taken together with the greater frequency of IL-2R+ precursors, suggests that this depletion of the pool of precursors may have been due to the induction of premature differentiation rather than to its inhibition.

Cell surface marker analysis of mouse thymic dendritic cells

Cell surface markers of mouse thymic dendritic cells have been studied by flow cytometry after isolation by collagenase digestion, separation of the low-density cell fraction and differential adherence. The dendritic cell preparation had a purity of greater than 90%, the contaminating population being essentially composed of thymocytes, macrophages constituting less than 1%. Dendritic cells displayed high forward and low-intermediate side angle scatter, and expressed high levels of major histocompatibility complex (MHC) class I and class II molecules, the heat-stable antigen (HSA), the adhesion molecules Pgp-1 (CD44), LFA-1, ICAM-1 and low levels of Mac-1 and the leukocyte common antigen CD45. Thymic dendritic cells are negative for the stem cell antigen-2 (Sca-2), the B cell-specific form of CD45 (B220), the mouse macrophage markers Fc receptor and F4/80, and the granulocyte marker Gr-1. However, although they do not express the T cell markers Thy-1, CD2, CD3, CD4 and CD5, 20%-30% of dendritic cells are positive for the interleukin 2 receptor alpha chain (CD25), and about 30% express intermediate levels of CD8. These results are discussed with regard to the functional significance of the expression of CD8 by thymic dendritic cells, and the existence of different dendritic cell subpopulations in the murine thymus.

Interleukin-1 production by transformed fibroblasts. II. Influence on antigen presentation and T-cell-mediated anti-tumor response

Oncogene-transformed fibroblasts which expressed IL-1, spontaneously or after activation with conditioned medium (CM) and lipopolysaccharide (LPS), regressed in the syngeneic host. Since regression was significantly influenced by the immune competence of the host (see companion report), we speculated that regression was T-cell-mediated. Frequencies of cytotoxic T-cell precursors (CTLp) were in the same range for activated and non-activated, transformed fibroblasts. Furthermore, it was found that lysability of transformed fibroblasts was not influenced by expression of IL-1. These findings exclude the possibility that regression of CM- and LPS-treated transformed fibroblasts may have been due to the appearance of new, strongly immunogenic epitopes. On the other hand, frequencies of CTL were significantly increased after in vivo immunization with IL-1-expressing as compared to IL-1-non-expressing transformed fibroblasts. The in vivo maturation/expansion of CTL could have been the consequence of activation of helper T cells (TH), transformed fibroblast-associated IL-1 delivering the costimulatory signal. Analysis of frequencies and proliferation rates of TH confirmed this assumption. Both parameters were significantly increased after stimulation with transformed fibroblasts expressing IL-1 in comparison to transformed fibroblasts not expressing IL-1. Furthermore, purified T cells apparently depleted of cells expressing MHC class-II antigens, i.e. antigen-presenting cells, proliferated in the presence of transformed fibroblasts expressing IL-1. Since IL-1 rather than MHC class-II antigen expression was the limiting factor, antigen presentation by IL-1-expressing transformed fibroblasts appears unlikely. Instead, maturation of antigen-presenting cells could well have been initiated by tumor-associated IL-1. We conclude that IL-1 expression of transformed fibroblasts plays an important role in the induction of a T-cell-mediated anti-tumor response. The effect is due to increased efficiency in the activation of helper T cells and may be supported by activation of antigen-presenting cells.

IL-1 production by human thymic dendritic cells: studies on the interrelation with DC accessory function

Thymic dendritic cells (DC) have been proposed to play a critical role in the generation of immunocompetent T lymphocytes. Since IL-1 is widely considered to be an important second signal in T cell stimulation, we have studied the ability of isolated human thymic DC to produce IL-1. Using the EL4/CTLL conversion assay standardized with recombinant IL-1 beta (rIL-1 beta), we demonstrate that upon LPS-stimulation thymic DC produce small amounts of IL-1 as compared to peripheral blood monocytes (PBM). In contrast with PBM, DC IL-1 production is not influenced by indomethacin. IL-1 activity was detected in the supernatants of DC cultures from all thymuses tested, although quantitative variability was noted among individual thymic donors. The specificity of the active factor was confirmed by neutralization assays with anti-IL-1 beta mAb. On the other hand, we demonstrate that rIL-1 beta cannot substitute for nor amplify the accessory function of thymic DC and that anti-IL-1 beta mAb fails to block the DC accessory function. Thus we conclude that IL-1 beta might not be a major factor for the efficient DC accessory function toward mature thymocytes recently demonstrated in our laboratory. Of interest, IL-1 beta was also detected in the supernatants of DC-thymocyte cocultures in the absence of mitogenic factor, suggesting that thymocyte contacts can constitute a sufficient signal to induce DC to produce IL-1. These observations indicate that human thymic DC represent an intrathymic source of IL-1 whose role in thymocyte proliferation or maturation remains to be understood.

Cytokines in T-cell development

The thymus provides a unique environment for the development of T cells, supporting both precursor cell proliferation and differentiation. The control of these processes is unknown but they may be mediated by cytokines, or other soluble factors, or by interactions with specific elements of the thymic stroma. Here, Simon Carding, Adrian Hayday and Kim Bottomly describe cellular, immunochemical and molecular studies of the production and action of cytokines within the human and mouse thymus and demonstrate their essential role in T-cell development.

The functional activity of high endothelial venules: a role for the subcapsular sinus macrophages in the lymph node

Adherence of lymphocytes to high endothelial venules (HEV3) is the first step in normal lymphocyte emigration and recirculation. At sites of chronic inflammation, venules often become high-walled and may also be a site for leukocytes to leave the bloodstream. The immunologic and inflammatory mediators, responsible for these effects on endothelial cells, may be important for the maintenance and function of HEV in physiological conditions. It is reported here that the morphological and functional aspects of HEV can be studied by organ cultures of lymph nodes (LN). At 24 h of culture, the appearance of the node was still quite normal, whereas the HEV became flat-walled, with a 45-50% reduction in the capacity to bind lymphocytes. This decrease in function of HEV could be reduced when LN were cultured in the presence of lipopolysaccharides (LPS). The effect of LPS on the function of HEV was presumably mediated by macrophages in the subcapsular sinus, because HEV in LN, which were depleted of subcapsular sinus and medullary macrophages previous to culture, could not be stimulated by addition of LPS to the cultures.

Signals arising from antigen-presenting cells

It has been customary to consider that antigen-presenting cells provide, in addition to the presented antigen, a second or co-stimulatory signal that leads to T-cell growth and effector function. The recent literature indicates that this two-signal notion oversimplifies the function of antigen-presenting cells. Instead it is useful to consider four groups of events: the formation of peptide-MHC complexes, the role of soluble cytokines, the action of antigen-presenting cell-T cell molecular couples distinct from the receptor for peptide MHC, and the function of antigen-presenting cells in situ.

Effect of cytokines on thymic hematopoietic precursors. Phenotypic and electron-microscopic study

We have previously shown that the interaction of thymocytes with thymic accessory cells (macrophages and/or interdigitating cells) is one of the factors required for thymocyte activation. Precursors of both thymic accessory cells and thymocytes are included in the CD4- CD8- Mac-1- Ia- subpopulation, and their respective maturation and/or activation may be modulated by granulocyte-macrophage colony-stimulating factor, interleukin 1 and interleukin 2. When CD4- CD8- thymic cells are activated with granulocyte-macrophage colony-stimulating factor plus interleukin 2, both macrophages and interdigitating-like cells are present, as shown by electron microscopy. When activated with interleukin 1 plus interleukin 2, the interdigitating-like cell is the only accessory cell present. In both culture conditions, large clusters are formed between interdigitating cells and lymphoid cells. These results have led us to propose two-step signals for thymocyte proliferation: first, the maturation of macrophages under granulocyte-macrophage colony-stimulating factor control and the production of interleukin 1, and secondly, the maturation of interdigitating cells under interleukin 1 control, their clustering with thymocytes which are then activated.

Differential kinetics of various subsets of thymic bone marrow-derived stromal cells in rat chimeras

Identification of those cells within the thymic stroma which are responsible for tolerance induction remains controversial. Evidence derived from studies of bone marrow chimeras or thymus transplants attributed this function to cells of haematopoietic origin, usually class II positive medullary dendritic cells (DC). Recent data suggest, however, that a stromal element located in the thymus cortex might be involved in negative selection. To further explore this issue we used immunohistology and immunocytology with a combination of allotype and cell type specific monoclonal antibodies (MoAb) to study the turnover of thymic stromal cells of haematopoietic origin in different rat models of allogeneic and congenic bone marrow (BM) radiation chimeras. Use of CFU-GM cultured BM inoculum for congenic recipients allowed us to distinguish between direct homing of donor myeloid cells and the delayed migration of the donor stem cell progeny after the post-irradiation recovery of the recipient. Our data indicate a heterogeneity in the turnover rate of thymic mobile stromal cells. While DC and a subset of macrophages located in the cortex as well as in the medulla (ED1+), within 4 weeks were virtually all of donor type, cortical macrophages detected by ED2 MoAbs were still incompletely replaced after a period as long as 20 weeks. Slow turnover, location and variable class II expression may imply a role for thymic cortical macrophages in (self-) tolerance induction.

Towards an integrated view of thymopoiesis

One prediction from the complex series of steps in intrathymic T-cell differentiation is that to regulate it the stroma controlling the process must be equally complex: the attraction of precursors, commitment to the T-cell lineage, induction of T-cell receptor (TCR) gene rearrangement, accessory molecule expression, repertoire expansion, major histocompatibility complex (MHC) molecule-based selection (positive and negative), acquisition of functional maturity and migratory capacity must all be controlled. In this review, Richard Boyd and Patrice Hugo combine knowledge of T-cell differentiation with thymic stromal cell heterogeneity to offer an integrated view of thymopoiesis within the thymic microenvironment.

Monoclonal antibodies against T cell receptor/CD3 complex induce cell death of Th1 clones in the absence of accessory cells

We have used anti-T cell mAbs as mimic ligands to study the effects of TCR/CD3 ligation of Th1 clones in the presence or absence of accessory cells. Our results demonstrated that ligation of TCR/CD3 in the presence of accessory cells induces proliferation of Th1 clone, while the same ligation in the absence of accessory cells results in death. This effect is inhibited by cyclosporin A and by anti-IFN-gamma mAbs and is restored by adding exogenous recombinant IFN-gamma tb CsA treated cells. We propose a model which could provide a general framework to explain activation, clonal anergy as well as clonal deletion of T lymphocytes during thymic development and in the peripheral.

Production of interleukin-1 by draining lymph node cells during the induction phase of contact sensitization in mice

Biologically active interleukin-1 (IL-1) has been detected in supernatants of draining lymph node cells isolated from contact-sensitized mice. Induction of IL-1 was dependent upon the concentration of sensitizer applied and occurred within 2 hr of exposure. The IL-1 activity could not be attributed to other interleukins and was neutralized by a specific antiserum. Reduced concentrations of IL-1 were produced by cells isolated from the draining nodes of mice that had been pre-exposed to the sensitizer. Since IL-1 has the potential to influence several aspects of lymphocyte activation, the production of significant concentrations of biologically active IL-1 by draining lymph node cells indicates that it is likely to play an important role in the afferent phase of contact sensitization.

Macrophages and interdigitating reticulum cells in normal human thymus and thymomas: immunoreactivity for interleukin-1 alpha, interleukin-1 beta and tumour necrosis factor alpha

Pairs of monoclonal/polyclonal antibodies directed against interleukin-1 (IL-1) alpha, IL-1 beta and tumour necrosis factor (TNF) alpha were used for immunocytochemical identification of cytokine-containing cells in cryostat sections of human fetal thymuses and thymomas. In the fetal thymus immunoreactivity for IL-1 alpha was mainly confined to the medulla and was detected in S-100 positive interdigitating reticulum cells. The pattern of immunoreactivity for IL-1 beta was similar to that for IL-1 alpha, but the number of positive cells was much lower. Cells positive for TNF alpha were extremely rare in the fetal thymus. In 11 thymomas macrophages were constantly present and were regularly distributed throughout the tumour, whereas S-100 positive interdigitating reticulum cells were fewer and were characterized by a zonal distribution. Thymoma-associated macrophages were negative for IL-1 beta and were poorly reactive for IL-1 alpha, only a few positive cells being detected in five of the cases. Some macrophages with immunoreactivity for TNF alpha were detected in seven cases; they formed rosettes with surrounding lymphocytes or were located in a perivascular position. A marked immunoreactivity for TNF alpha was constantly detected in mast cell granules, which were observed in nine thymomas but not in fetal thymus. Positive immunoreactivity of interdigitating reticulum cells for IL-1 alpha was confirmed in five reactive lymph nodes and was also observed in Langerhans' cells in dermatopathic lymphadenitis. Our findings suggest that IL-1 alpha is a crucial molecule for interdigitating reticulum cell and Langerhans' cell function.(ABSTRACT TRUNCATED AT 250 WORDS)

The role of graft-derived dendritic leukocytes in the rejection of vascularized organ allografts. Recent findings on the migration and function of dendritic leukocytes after transplantation

Dendritic cells isolated from lymphoid tissues are potent stimulators of primary allogeneic T-cell responses in vitro and in vivo. Similar major histocompatibility complex class II-bearing dendritic-shaped leukocytes are contained within transplanted organs and these are thought to be important passenger leukocytes that trigger rejection. Recent findings on the migration, phenotype, and function of cardiac dendritic leukocytes (DLs) are reviewed. After transplantation donor DLs migrate rapidly from mouse cardiac allografts into the recipients's spleens. Within the spleens donor DLs associate with recipient CD4+ T cells. Isolated cardiac DLs, like lymphoid dendritic cells, are potent stimulators of T-cell proliferation in vitro. This suggests that DLs function as passenger leukocytes by migrating from grafts into the lymphoid tissues of the recipient and that sensitization to vascularized organ allografts may occur centrally within lymphoid tissues rather than peripherally in the graft itself.

Ontogenic characterization of thymic B lymphocytes. Analysis in different mouse strains

We have characterized a population of murine B lymphocytes present in the thymus (TBL). They are a minor subset (0.2%-1% of total thymocytes), present from perinatal periods onwards and constituted by activated cells with a high proportion of Ig-secreting cells. They represent the first B lymphocytes detected that secrete IgG after birth. Functional analysis reveals that the frequency of lipopolysaccharide-responding cells in TBL is 5- to 10-fold lower than in the spleen. TBL from adult mice did not show any significant difference in their VH repertoire expression when compared to peripheral B lymphocytes. Furthermore, we have been able to isolate a subpopulation of B220+IgM-CD3- thymocytes whose putative B cell precursor potential needs to be directly analyzed. These and other findings support the intrathymic resident characteristics of TBL and suggest new ways of elucidating its physiological role in the complex selective processes occurring inside the thymus.

Characterization of murine lung dendritic cells: similarities to Langerhans cells and thymic dendritic cells

Dendritic cells (DC) are potent accessory cells (AC) for the initiation of primary immune responses. Although murine lymphoid DC and Langerhans cells have been extensively characterized, DC from murine lung have been incompletely described. We isolated cells from enzyme-digested murine lungs and bronchoalveolar lavages that were potent stimulators of a primary mixed lymphocyte response (MLR). The AC had a low buoyant density, were loosely adherent and nonphagocytic. AC function was unaffected by depletion of cells expressing the splenic DC marker, 33D1. In addition, antibody and complement depletion of cells bearing the macrophage marker F4/80, or removal of phagocytic cells with silica also failed to decrease AC activity. In contrast, AC function was decreased by depletion of cells expressing the markers J11d and the low affinity interleukin 2 receptor (IL-2R), both present on thymic and skin DC. AC function was approximately equal in FcR+ and FcR- subpopulations, indicating there was heterogeneity within the AC population. Consistent with the functional data, a combined two-color immunofluorescence and latex bead uptake technique revealed that lung cells high in AC activity were enriched in brightly Ia+ dendritic-shaped cells that (a) were nonphagocytic, (b) lacked specific T and B lymphocyte markers and the macrophage marker F4/80, but (c) frequently expressed C3biR, low affinity IL-2R, FcRII, and the markers NLDC-145 and J11d. Taken together, the functional and phenotypic data suggest the lung cells that stimulate resting T cells in an MLR and that might be important in local pulmonary immune responses are DC that bear functional and phenotypic similarity to other tissues DC, such as Langerhans cells and thymic DC.

The cascading, interrelated roles of interleukin-1, interleukin-2, and interleukin-6 in murine anti-CD3-driven T cell proliferation

T cell stimulation occurs following interaction of T cell receptor (TcR) with processed antigen presented by autologous accessory cells (AC). The effects of antigen stimulation on T cells are mimicked by monoclonal antibodies (Mabs) defining proteins of the TcR-CD3 complex. In this study, we examine the roles of T cell density, AC density, divalent and polyvalent forms of anti-CD3 Mab, and the cytokines interleukin (IL)-1, IL-2, and IL-6 in T cell activation and proliferation. Stringently AC-depleted T cells do not proliferate in response to Con A or divalent anti-CD3; however, polyvalent anti-CD3 provides a powerful signal for isolated resting T cell proliferation. Recombinant (r)IL-2 strongly amplifies T cell proliferation in response to anti-CD3, whereas rIL-1 exerts no direct effects on anti-CD3-stimulated T cells. In the presence of AC, however, rIL-1 augments T cell proliferation to anti-CD3. Recombinant IL-6 promotes T cell proliferation among T cells stimulated with polyvalent but not divalent anti-CD3. As deduced by Northern blot analysis, rIL-1 increases cytoplasmic levels of IL-6 mRNA in AC. Recombinant IL-6, in turn, amplifies the accumulation of stable IL-2 transcripts in purified T cells stimulated with polyvalent anti-CD3. Hence, IL-1, IL-6, and IL-2 support T cell proliferation through cascading effects at the level of gene transcription. The cytokines evaluated in this study, however, do not fully reconstitute AC functions in promoting anti-CD3 Mab T cell proliferation.

Soluble CD23 (Fc epsilon RII) and interleukin 1 synergistically induce early human thymocyte maturation

The ability of human thymus-derived CD7+CD2-CD3- cells to acquire mature T cell antigens was assessed. Purified CD7+ thymocytes were incubated with rIL-1, rIL-2, and/or recombinant soluble CD23 (rsCD23). Short-term incubation of these cells with only rsCD23 + rIL-1 induced mature T cell antigen expression on at least half of the cells. The induction of CD2 was functionally significant, as these cells became able to respond to CD2 triggering and could proliferate in response to IL-2. Possible sources of CD23 in the thymus are under investigation.

Dendritic cell production of cytokines and responses to cytokines

Dendritic cells (DC) are a family of bone marrow-derived MHC class II expressing cells which occur in small numbers in most lymphoid and nonlymphoid tissues. They represent a distinct lineage of leukocytes which can be found in two distinct maturational stages: immature dendritic cells are exemplified by the Langerhans cells in the epidermis, and are considered to be precursors to the mature dendritic cells in the lymphoid organs. These maturational stages can be distinguished by phenotypic and functional characteristics. Immature dendritic cells are weak stimulators of resting T lymphocytes but are excellent in processing soluble protein antigens for presentation to T cell clones. Mature dendritic cells show exactly reciprocal features. In this review the relatively few available data on cytokine production by DC and responses of DC to cytokines are collected. Our goal is to consider the role of cytokines in DC function including the transition from immature to mature stages.

Interstitial dendritic cells

Interstitial dendritic cells (IDC) were first identified in the interstitium of non-lymphoid organs as leucocytes which stained intensely with anti-MHC class II antibodies. These cells have been identified in several species including man, and can be distinguished from tissue macrophages by their immunological phenotype and cytochemical and functional characteristics. IDC appear to be closely related to lymphoid dendritic cells (DC), and have the capacity to bind antigen and stimulate T lymphocyte responses. It seems probable that they represent a stage of nonlymphoid dendritic cell differentiation necessary for antigen surveillance, similar to the Langerhans cell of the skin. Exposure to antigen appears to induce migration of these cells into adjacent lymphatics and subsequent localization in the interfollicular areas of lymph node, where the DC present processed antigen to activate a primary T cell response. The IDC has been identified as the passenger leucocyte within organ allografts which contributes substantially to graft immunogenicity, so that eradication of donor organ IDC improves organ graft survival.

Dendritic cells as antigen presenting cells in vivo

The biology of antigen presenting cells (APC) traditionally is studied in tissue culture systems using T cells that have been expanded beforehand by stimulation with antigen. Here we consider the distinctive roles of dendritic cells for sensitizing or priming T cells both in vitro and in vivo. Several functions of dendritic cells have been identified in tissue culture that are pertinent to T cell sensitization. These include the ability to a) capture and retain foreign antigens in an immunogenic form, b) bind antigen-specific resting lymphocytes, and c) activate T cells to produce lymphokines and undergo long term clonal growth. Dendritic cells have several properties in vivo that also would contribute to APC function. These are a) their widespread tissue distribution permitting access to antigens in most organs, b) the capacity to home via the blood stream and afferent lymph to the T-dependent areas of spleen and lymph node, and c) the ability to capture antigen in antigen-pulsed animals. Dendritic cells bearing antigen have been administered in situ to initiate responses like contact sensitivity, graft rejection, and antibody formation. A most striking recent example is that, when dendritic cells are pulsed with protein antigens in vitro and administered to immunologically naive mice, there is direct priming of antigen-specific T cells that are restricted to the MHC of the injected APC.

Interleukin 1: the first interleukin

The name 'interleukin' and the designation of interleukin 1 (IL-1) derived from the Second International Lymphokine Workshop held in Switzerland in 1979. Since then interest in the original interleukin (IL-1) has increased exponentially as measured by the numbers of publications and meetings. The main reasons for this can be seen in the accompanying centrefold. The perception of IL-1 as a biological mediator in every organ system has attracted scientists from widely different backgrounds into this area and a steady succession of important and often surprising insights into IL-1 biology has ensured that interest has been sustained at a high level. This overview of the biology of IL-1 on the tenth anniversary of its turbulent life has been compiled by Franco di Giovine and Gordon Duff. It is of necessity selective and biased towards human IL-1 and begins with some general points (mainly cautionary) as a backdrop to the centrefold.

Thymic dendritic cells and B cells: isolation and function

The thymus is the primary organ in which T cells undergo rearrangement of T cell receptor alpha and beta genes, positive selection for affinity to self MHC products, and elimination (negative selection) of reactivity to self antigens. These events require an interaction of the developing T cell with other cell types in the thymus. The latter include epithelial cells, macrophages, dendritic cells, and the recently described thymic B cells the majority of which are CD5+. Here we review the identification and isolation of thymic dendritic cells and CD5+ B cells. We consider phenotype, ontogeny, and function, including possible contributions to the induction of self tolerance. Thymic dendritic cells are similar to spleen dendritic cells, but are larger and exhibit a few differences in phenotype. Dendritic cells from both organs are equally potent accessory cells for the MLR and lectin-induced, T cell proliferation. Thymic dendritic cells have higher levels of Fc receptors and support anti-CD3 dependent mitogenesis. Thymic CD5+ B cells share phenotypic features with peritoneal CD5+ B cells. However thymic B cells neither proliferate nor form antibody producing cells in response to the stimulation with LPS or anti-IgM plus IL-4, but do respond to stimulation with MHC class II-restricted helper T cells. Thymic dendritic cells and CD5+ B cells both appear at a similar time in ontogeny, about 14 d of gestation, which is the time T cell differentiation begins to take place. Dendritic cells from spleen, which are potent activators for peripheral T cells, are also potent inactivators for thymic-derived cytotoxic T cells. A correlation between reactivity to MIs products and the expression of TCR-V beta genes is well documented, and B cells are the primary APC for this antigen. Therefore, thymic CD5+ B cells may be a good tool for the investigation of tolerance to M1s products.