Human thymic dendritic cell-thymocyte association: ultrastructural cell phenotype analysis

Dendritic cells enriched from swine thymus co-express CD1, CD2 and major histocompatibility complex class II and actively stimulate alloreactive T lymphocytes

Initial characterization and partial purification of thymic dendritic cells (DC) from miniature swine were carried out with the ultimate goal of using these cells to induce transplantation tolerance in this preclinical animal model. Immunohistochemical analysis of swine thymic tissue sections has shown DC to be large cells located in the medullary and the cortico-medullary regions as evidenced by the presence of surrounding Hassal bodies. These cells exhibit membrane processes and express the CD1, granulocyte/macrophage (G/M), and major histocompatibility complex (MHC) class II surface antigens, as well as the S100 cytosolic and nuclear markers found in humans to be specific for DC. Dendritic cells were purified from thymi following collagenase treatment, Percoll gradient centrifugation, and adhesion steps to plastic. Cells similar in morphology and phenotype to those described in tissue sections were detected in the lighter density layers of the gradient and represented 0.02% of the starting cell number. Removal of plastic nonadherent cells showed enrichment levels similar to those reported for murine and human DC. Two-colour flow cytometric analysis of purified pig DC identified these cells as MHC class IIhi, CD1+, CD2+, and G/M+. The dendritic nature of these cells was confirmed by their potent ability to stimulate alloreactive T lymphocytes. Modification of porcine thymic DC by transfer of allogeneic MHC genes and reinjection into the DC donor should permit testing of the role of this DC subset in the induction of transplantation tolerance.

Expression of CD146 adhesion molecules (MUC18 or MCAM) in the thymic microenvironment

The thymic microenvironment is thought to play a critical role in T-lymphocyte development, providing signals both via cell surface molecules such as adhesion molecules and soluble molecules. The present investigation is focused on immunoelectron microscopical analysis of distribution patterns of CD146 adhesion molecules (MUC18 or MCAM) in the microenvironment of normal human thymus, using the pre-embedding indirect immunoperoxidase technique. The anti-CD146 monoclonal antibody (mAb) revealed strong membraneous labelling of immature thymocytes at both the light and electron microscopical level. Proliferating thymocytes, most of the epithelial cells, macrophages, endothelial cells and smooth musle cells of small vessels and capillaries showed both membraneous and cytoplasmic labelling with anti-CD146 mAb as was demonstrated by electron microscopy. In contrast, these cells displayed a strong cytoplasmic immunoreactivity at the light microscopical level. The extracellular matrix was also stained with the anti-CD146 mAb. No labelling was observed in interdigitating cells. Interestingly, the CD146 molecule was strongly expressed on apical and lateral membranes of endothelial cells as was demonstrated electron microscopically. This selective CD146 labelling of capillary endothelium mainly localized at the cortico-medullary junction may be manifestations of lymphocyte transmembrane migration and lymphocyte homing. In conclusion, the present study suggests that CD146 is expressed by most elements of the microenvironment of normal human thymus. Therefore, it may be a pan-antigen which is essential for the maintenance of thymic architecture and function.

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.

An improved method for purifying human thymic dendritic cells

Thymic dendritic cells (DC) play a prominent role in the immune response as they constitute a key element involved in the maturation of thymocytes in the thymus. Human thymic DC, like DC from other lymphoid organs, represent a minor cell population (< 2%) of the thymus. Since these cells cannot replicate in vitro, the development of efficient purification methods is an essential prerequisite for extensive functional studies. DC express high levels of HLA-DR, a cell surface marker of the MHC class II antigen which is not exclusive to DC. Since no specific human thymic DC marker has been identified so far, DC purification methods are mainly based on depletion of particular subgroups of cells. We report here an improved method for purifying human thymic dendritic cells. In contrast to prior work, CD2+ thymocytes were first depleted by rosetting with neuraminidase treated sheep red blood cells. The nonrosetted cells were separated in a Percoll gradient, and the low-density cells were subsequently depleted of nondendritic cells by using thymocyte and macrophage specific monoclonal antibodies and either magnetic bead depletion or cytofluorometry. Cell populations (18-55 x 10(6) cells) obtained following magnetic bead purification were at least 80% HLA-DR+/CD2- and exhibited ultrastructural morphological features and functional activities such as those described previously for thymic DC. This improved method was compared with different purification approaches that use various combinations of cell density-based separation techniques and cell surface specific markers antibody reactivity. The magnetic beads depletion approach provided higher yields.

The development of T and non-T cell lineages from CD34+ human thymic precursors can be traced by the differential expression of CD44

In addition to T-lineage cells, a small proportion of hematopoietic non-T cells are present in the human postnatal thymus. However, the origin of this minor non-T cell thymic compartment is presently unknown. In this study we have analyzed the developmental potential of the earliest human intrathymic precursors, characterized as CD34+ cells expressing intermediate levels of CD44. We show that these CD34+CD44int thymocytes cultured with interleukin 7 were able to develop simultaneously into both T- and non-T (monocytes and dendritic cells) -lineage cells. Both developmental pathways progress through a CD1+CD4+ intermediate stage, currently believed to be the immediate precursor of double positive thymocytes. However, separate progenitors for either T or non-T cells could be characterized within CD1+CD4+ thymocytes by their opposite expression of CD44. Downregulated levels of CD44 identified CD1+CD4+ T-lineage precursors, whereas CD44 upregulation occurred on CD1+CD4+ intermediates that later differentiated into non-T cells. Therefore, commitment of human early intrathymic precursors to either T or non-T cell lineages can be traced by the differential expression of the CD44 receptor.

Surface expression and distribution of Fc receptor III (CD16 molecule) on human natural killer cells and polymorphonuclear neutrophils

Human natural killer cells and polymorphonuclear neutrophils constitutively express the low-affinity IgG Fc receptor (Fc gamma RIII, CD16 molecule). To investigate cell surface morphology, antigenic receptor density, and topographical distribution of Fc gamma RIII on the plasma membrane of natural killer cells and polymorphonuclear neutrophils, conventional scanning electron microscopy (SEM), flow cytometry, and immunoscanning electron microscopy were used. Fc gamma RIII was detected with an indirect immunogold labeling procedure, and receptors were visualized in the backscattered and secondary electron imaging mode of SEM. Natural killer cells showed a cell surface morphology compatible with lymphocytic differentiation characterized by microvilli and microridges. Polymorphonuclear neutrophils showed surface features characterized by ridges with folds and scattered short microvilli. Natural killer cells displayed a lower cell labeling density, whereas polymorphonuclear neutrophils showed a high level of expression of Fc gamma RIII on the plasma membrane by quantitative analysis with SEM in the backscattered electron imaging mode. Flow cytometry analysis confirmed these findings. Analysis of the topographical distribution of Fc gamma RIII antigenic receptor sites by SEM in the backscattered and secondary electron imaging modes showed that Fc gamma RIII on natural killer cells are randomly distributed, whereas Fc gamma RIII are located on ridges and folds of the plasma membrane of polymorphonuclear neutrophils. These observations suggest that natural killer cells and polymorphonuclear neutrophils differ in their levels of expression and topographic distribution of Fc gamma RIII on the plasma membrane. This different spatial distribution of Fc gamma RIII would provide morphological evidence of certain cellular functions mediated by natural killer cells and polymorphonuclear neutrophils.

Development in the thymus: it takes two to tango

Intrathymic T-cell development is dependent upon signals provided by the thymic stromal cell microenvironment. However, loss of thymic T cells in natural and experimentally induced situations is associated with a reduction in the surrounding epithelium, suggesting an interdependence between thymocytes and their microenvironment. Here, the authors review the evidence in favour of this intrathymic symbiosis, and hypothesize that T cells may provide maturation and survival signals that are necessary for the development and maintenance of their microenvironment.

The human thymic dendritic cell phenotype and its modification in culture

In order to extend our study of human thymic dendritic cells (DC) we have purified DC by density gradient separation followed by treatment with CD1 and CD2 mAb and antibody-coated immunobeads. The resulting population contains 60 to 75% brightly HLA-DR+ cells. Morphological and functional studies demonstrate that these cells share the common characteristics of dendritic cells. Extensive phenotypic analysis of the purified DC has been made using a panel of mAb. Cytofluorometric assays with mAb reactive with common leucocyte antigen confirm that the brightly HLA-DR+ cells are of mesenchymal origin. Thymic DC express HLA-DQ and HLA-class I antigens. They are also positive for the expression of CD45RA molecules and some express the ICAM-1 and the LFA-1 molecules. DC do not stain with a wide variety of anti-T, -B, and -monocyte or -M phi mAb and lack Fc gamma RIII, CR2, and CR3. Freshly isolated DC failed to stain with OKT6 mAb; however, they progressively acquire the CD1 molecule after a few days culture. The acquisition of CD1 molecule is selective since CD4, CD2, and HLA-ABC molecules are not upregulated under the same conditions. From phenotypic results, it was therefore possible to sort brightly HLA-DR+ or -DQ+ cells and so obtain greater than 90 to 95% purified human thymic DC. Such homogeneous DC populations are obviously of great interest for the study of thymic DC functions.

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.

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.

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.

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.