Characterization of cells comprising murine thymocyte multicellular complexes

Characterization of complexes between thymocytes and thymic stromal cells was facilitated in the present study by demonstrating that complexes would reform if cells were incubated for 1.5 to 2 h in vitro at ambient temperature. Several immunologic approaches were used to determine the phenotype of complexed cells. Bound T cells were 97% double-positive (CD4 and CD8), 3% double-negative and greater than 99% CD3 positive by using immunoperoxidase immunohistology on cytospins. Five percent expressed the TCR beta-chain and 1 to 2% were IL-2R positive. The percentages were the same whether complexes were preformed in vivo or formed in vitro. Despite the apparent absence of single positive cells in complexes, when isolated CD4 or CD8 positive cells were tested for their ability to bind to adherent thymic macrophages, each subpopulation contained some cells which were capable of complex formation. When thymocytes were fractionated by density, steroid sensitivity or peanut agglutinin positivity then allowed to form complexes, cells with an immature phenotype had a greater propensity for complex formation. Central stromal cells all were class II MHC gene product (I-A and I-E) positive, expressed macrophage-associated Ag (B23.1 and MAC-1), were negative for cytokeratin but positive for vimentin, were reactive with a polyclonal antimacrophage serum, but did not express dendritic cell Ag (33D1). The data demonstrate that immature thymocytes bind exclusively to class II MHC gene product positive thymic macrophages. This binding step may play a role in the acquisition of T cell function in the thymus.     

Deletion of self-reactive T cells in nude mice grafted with neonatal allogeneic thymus

The cellular basis of tolerance induction has been investigated in BALB/c(H-2d, thy 1.2, M1s1b2a) nude mice grafted with thymus of neonatal AKR/J mice(H-2k,Thy1.1,M1s1a2b). The spleen cells from nude mice grafted with AKR/J thymus showed a significantly decreased level of primary cytotoxic T cell response when stimulated with AKR/J cells, although these cells lysed well target cells of a third party C57BL/6 when stimulated with C57BL/6 cells. Consistent with CTL responses, T cells bearing V beta 6, that is important for recognizing M1s1a-encoded products of the thymic phenotype, were virtually abolished in the spleen and lymph node cells of nude mice 8 wk after grafting with AKR/J thymus. However, a substantial number of V beta 6-bearing T cells were detected in the peripheral organs of nude mice 23 wk after grafting with AKR/J thymus and in those of nude mice grafted with AKR/J fetal thymus depleted of macrophages/dendritic cells by incubating with 2'-deoxyguanosine in vitro before grafting. On the other hand, T cells bearing V beta 3, which are selectively related to M1s2a-encoded products of the host phenotype, were expressed neither on the peripheral T cells of nude mice grafted with AKR/J thymus at any stage after grafting nor on those of nude mice grafted with 2'-deoxyguanosine-treated AKR/J thymus. These data suggested that both V beta 6 and V beta 3 T cells were eliminated in the thymus of nude mice grafted with AKR/J thymus, presumably on the basis of interaction with both of graft-derived persisting and host-derived hemopoietic cells in the thymus and that thymic epithelium appears to have little capacity to eliminate T cells reactive to minor lymphocyte stimulating-encoded products.     

Freshly isolated spleen dendritic cells and epidermal Langerhans cells undergo similar phenotypic and functional changes during short-term culture

Spleen dendritic cells (DC) and epidermal Langerhans cells (LC) belong to the same family of dendritic leukocytes and are considered to be prototypes of lymphoid DC and nonlymphoid DC, respectively. These cells are active APC in vitro and play a key role in the induction of primary T cell dependent immune responses in vivo. Two functional states of LC have been characterized in vitro, freshly isolated LC and cultured LC (cLC). That cLC closely resemble spleen DC in phenotype and function, has led to the hypothesis that LC undergo maturation toward DC while in culture, an event that has been correlated with the emigration of LC from skin into lymphoid organs. To date, however, DC have been studied only after overnight culture. To better understand the relationship between LC and DC, we examined DC shortly after their isolation from spleen, and after 24 h of culture. Freshly isolated DC (fDC) express high levels of MHC molecules and low levels of Fc gamma RII and C3biR; fDC also uniformly express the Ag recognized by the mAb 33D1, NLDC-145, and J11d. After culture, DC display a marked increase in the expression of MHC molecules, and they are induced to express the low affinity receptor for IL-2. By contrast, the expression of Fc gamma RII and F4/80 decreases with culture. With respect to function, fDC can efficiently present keyhole limpet hemocyanin to Ag-specific T cells, whereas cultured DC exhibit a marked reduction in this capacity. Finally, both fDC and cultured DC are capable of endocytosing surface Ia molecules, but only fDC are able to deliver them into acidic compartments. Our data indicate that fDC from spleen resemble freshly isolated LC from epidermis and that both cells undergo parallel changes during culture. These results suggest that LC and DC possess analogous attributes in vivo and respond similarly to external influences.     

The myelopoietic inducing potential of mouse thymic stromal cells

The thymus has generally been considered as being solely involved in T cell maturation. In this study we have demonstrated that mouse thymic stroma can also support myelopoiesis. Bone marrow from mice treated with 5-fluorouracil was depleted of cells expressing Mac-1, CD4, and CD8 and incubated on lymphocyte-free monolayer cultures of adherent thymic stromal cells. After 7 days there was a marked increase in nonadherent cells, the majority of which were Mac-1+, FcR+, and HSA+. These proliferating bone marrow cells also expressed markers (MTS 17 and MTS 37) found on thymic stromal cells. Such cells were not found in thymic cultures alone, in bone marrow cultured alone, or on control adherent cell monolayers. Supernatants from the cultured thymic stroma, however, were able to induce these cell types in the bone marrow precursor population. Incubation of normal thymocytes with a monolayer of these in vitro cultivated Mac-1+, MTS 17+, MTS 37+ myeloid cells leads to selective phagocytosis of CD4+ CD8+ cells. Hence, this study demonstrates that the thymic adherent cells can induce myelopoiesis in bone marrow-derived precursor cells and provide a form of self-renewal for at least one population of thymic stromal cells. Furthermore, these induced cells are capable of selective phagocytosis of CD4+ CD8+ thymocytes and may provide one mechanism for the selective removal of such cells from the thymus.     

Analysis of hemopoietic lineage of accessory cells in the developing thymus of Xenopus laevis

The developmental history of accessory cells in the thymus was studied by grafting hemopoietic stem cells into cytogenetically distinct frog embryos (diploid-2N or triploid-3N) before the establishment of circulation and overt differentiation and colonization of the thymus. The DNA content of cortical thymocytes and circulating erythrocytes was quantified by staining with propidium iodide and measuring the amount of red fluorescence emitted by individual nuclei with the use of flow cytometry. Accessory cells from thymic medulla were separated by incubating for 2 hr on glass slides. For comparison, the developmental history of peritoneal macrophages was examined as representative, myeloid-derived phagocytic cells. DNA content of adherent cells was quantified by staining with the DNA-specific Feulgen reaction and measuring light absorption of individual nuclei by microdensitometry. Thymic accessory cells were subdivided into phagocytic and nonphagocytic phenotypes on the basis of latex bead ingestion. Phagocytic cells in the thymus were usually nonspecific esterase positive and phenotypically resembled peritoneal macrophages. Nonphagocytic cells from the thymus were usually esterase negative and had a dendritic morphology characterized by branched cytoplasmic extensions. Nonphagocytic cells were positive for cytoplasmic RNA based on staining with methyl green-pyronin Y. Phagocytic cells from both the thymus and the peritoneal cavity had no levels of cytoplasmic RNA detectable by this method. Analysis of the embryonic derivation of thymic accessory cells, based on the proportion of cells carrying the cytogenetic marker, demonstrated that thymic lymphocytes and thymic accessory cells were a concordant pair of cells, distinct from myeloid-derived erythrocytes and possibly macrophages. These experiments provide circumstantial evidence suggesting thymocytes and thymic accessory cells could arise from a bipotential precursor that diverges into these separate lineages after colonization of the epithelial thymic rudiment during early development.     

Differences in turnover between thymic medullary dendritic cells and a subset of cortical macrophages

To investigate the turnover of thymic accessory cells, we performed vascular thymus transplantation in RT7 congenic rats. mAb specific for one of the two allelic variants of the RT7 molecule, as well as mAb specific for either medullary interdigitating cells or a subset of cortical macrophages (M phi), were used on cryostat sections and cell suspensions prepared from grafted thymuses to monitor the turnover of these two cell types. In contrast to the complete turnover of interdigitating cells within 3 wk after transplantation, ED2-labeled cortical M phi showed a very slow turnover. Seventy-six days after transplantation, more than 30% of these M phi were found to be still of donor origin. The different turnover rates of these thymic accessory cells could reflect their function in T cell development.     

Distribution of Lyt antigens on the surface of thymocytes associated with thymic macrophages and dendritic cells

Summary Thymocyte subpopulations that are associated with macrophages and dendritic cells of the thymus in vivo were isolated from the thymuses of C57Bl/6 mice, and their Lyt phenotypes were analyzed. Electron-microscopic examination of immunogold-labeled cells revealed that the thymic complexes formed by macrophages mainly contained Lyt-2-positive thymocytes, while Lyt-1-positive thymocytes were more frequently associated with dendritic cells. The characteristic distributions of Lyt antigens on the surface of thymocytes in regions of reciprocal contact with macrophages (Lyt-2-positive cells) and dendritic cells (Lyt-1-positive cells) suggest that these antigens play a role in specific interactions between thymocytes and stroma cells.Dedicated to Professor Dr. T.H. Schiebler on the occasion of his 65th birthday     

Development and maturation of thymic dendritic cells during human ontogeny

Thymic dendritic cells (TDC) are dendritic cells situated mainly in the cortico-medullary zone and in the medullary region of the thymus. However, the phenotype of TDC during ontogeny is poorly documented. The aim of this study has been to investigate the development and maturation of TDC during human ontogeny. Immunohistochemical analyses and immunoelectron-microscopic investigation of 21 human thymus specimens have been performed to detect the subtypes of TDC by using various DC-related and DC-development-related markers. TDC express a Langerhans-cell-like phenotype during human ontogeny. Cells expressing thymic stromal lymphopoietin receptor have been observed in Hassal’s corpuscles of the thymus. Granulocyte/macrophage colony-stimulating factor (GM-CSF) is also expressed in thymic epithelial cells (TEC) localized in Hassal’s corpuscles. During human ontogeny, GM-CSF is produced by TEC of Hassal’s corpuscles and might play a key role in the differentiation of TDC having Langerhans-cell-like phenotypes.     

Improved FACS analysis confirms generation of immature dendritic cells in long-term stromal-dependent spleen cultures

Cells produced in spleen stroma-dependent long-term cultures (LTC) have now been clearly defined as dendritic cells (DC). Characterization of cells by antibody staining and FACS analysis has only been possible using a procedure to quench the high autofluorescence of DC produced in LTC (LTC-DC). The population of large cells produced by the established LTC-X1 culture are homogeneously positive for a number of cell-surface markers expressed by DC. These include CD11c, CD11b, Dec-205, Fc receptor and CD86. They also express markers detectable with the F4/80 and 33D1 antibodies. Cells produced in LTC do not uniformly express the MHC II marker, consistent with an immature DC phenotype. Most cells are weakly positive for MHC II with a small subset of highly positive cells. The quenching method involves staining cells with crystal violet dye, which is taken up within the cell. The importance of optimizimg fluorescent antibody staining assays for delineating DC subsets is indicated and the LTC system is established as a valuable and continuous source of DC precursors.     

Hemopoiesis in long-term stroma-dependent cultures from lymphoid tissue: Production of cells with myeloid/dendritic characteristics

Summary A long-term stroma-dependent culture system (LTC) has been developed which continuously produces hemopoietic cells providing an in vitro system for the study of cell differentiation. These nonadherent cell populations contain a large subpopulation of dendritic cells (DC). LTC producing DC were easily generated from spleen, but could also be established from bone marrow (BM) and lymph node with less success. It was difficult to establish DC-producing LTC from thymus. The properties of splenic and thymic stroma have been compared. Spleen stroma developed more complicated networks of fibroblasts, endothelial cells, macrophages, and DC. Thymic stromal monolayers were dominated by epithelial cells and fibroblasts, with a lower proportion of macrophages and endothelial cells. They had a relatively sparse structure of cell networks compared with spleen stroma. Cells with dendritiform morphology first appeared in cultures by 2–3 wk. The majority of cells produced were large cells which expressed DC-specific cell surface markers, major histocompatibility complex (MHC) Class II molecules, and the CD80/CD86(B7) costimulator. A high proportion of cells also expressed myeloid cell markers. No T or B lymphoid cells or granulocytes were present in the cultures. LTC continued to produce nonadherent cells resembling myeloid/DC for long periods, even after passage of stromal cells and stem cells at about 3–4 mo. after culture establishment. The LTC system offers potential to study the in vitro differentiation of myeloid/DC.     

Development of T cells in vitro from precursors in mouse bone marrow

Bone marrow cells from 6- to 8-week-old athymic nude mice were depleted of nylon-wool adherent cells and cultured in vitro at low cell numbers (300 cells/well) in medium supplemented with a supernatant from a thymoma cell line. About 1% of cultured cells grew. Pooled cultures contained cells expressing CD3 (52%), CD4 (37%), CD8 (11%), Thy 1.2 (72%), MAC-1 (43%) and J11d (86%) but no cells expressing sIg. They also contained cells expressing mRNA for the alpha, beta, gamma, and delta chains of the T cell receptor as assessed with C region probes using a sensitive dot blot assay. These cells appear to develop from progenitors which are CD3-. When pooled Day 10 cultures were depleted of nylon-wool adherent cells, the remaining cells were nearly all J11d+, Thy 1.2+, MAC-1-, CD3+, and either CD4+CD8+; CD4+CD8-; CD4-CD8+, or CD4-CD8-; i.e., their surface marker patterns were reminiscent of those of thymocytes. We conclude that our culture system is enabling bone marrow precursors to commence differentiation down the T cell lineage in the absence of a thymic environment.     

The role of Ia molecules in the activation of T lymphocytes. IV. The basis of the thymocyte IL 1 response and its possible role in the generation of the T cell repertoire

The activation requirements for thymocyte proliferation were investigated. Thymocytes proliferate in the presence of exogenous interleukin 1, which has been used as the classic assay for this factor. This response, however, is greatly decreased in cultures of purified thymic T cells. Purified thymic T cells will proliferate in the presence of IL 1 if accessory cells are added to culture. The requisite accessory cell is a non-T, adherent, radioresistant cell found in macrophage/dendritic cell-enriched fractions of both thymus and spleen. This cell bears Ia molecules, which are critically involved in the activation of thymocytes. This thymocyte-accessory cell interaction is not dependent on exogenous nominal antigens. Therefore, it appears that IL 1 allows the expansion of thymocytes with specificity for self-class II MHC antigens. This response was found to be unique to this stage of T cell development and can be observed with both mature and immature thymic T cell subsets. The implications of these findings for the physiologic expansion of self-restricted T cells in the thymus are discussed.     

Nature of the thymocytes associated with dendritic cells and macrophages in thymic rosettes

Thymic rosettes, structures consisting of 3-30 thymic lymphoid cells attached to a central macrophage or dendritic cell, were released from mouse thymus tissue by collagenase digestion. They were shown to be preexistent structures within the thymus, but to be subject to extensive exchange with free thymocytes under certain conditions. An isolation procedure was developed, using a new technique of zonal unit-gravity elutriation, which minimized exchange and produced a completely pure sample of the larger rosettes. The rosette-associated thymocytes were analyzed by two- and three-color immunofluorescent staining and flow cytometry. The dominant cell type was a small, CD4+CD8+, cortical-type thymocyte. However, all of the established thymus subpopulations defined by CD4 and CD8, including CD4-CD8+ and CD4+CD8- mature thymocytes and CD4-CD8- early thymocytes, were also present in rosettes. Very few of the cells present were of an intermediate or transitional phenotype. Rosette-associated thymocytes were somewhat enriched in large dividing thymocytes, in CD4-CD8- thymocytes, and in mature thymocytes expressing the T-cell antigen receptor-CD3 complex. Their most striking characteristic was a marked depletion in small thymocytes lacking surface H-2K expression, a major population among free thymocytes. The physiological role of the rosette structure is discussed, and it is suggested that the heterogeneity of the associated thymocytes in part reflects the existence of different types of rosettes in different areas of the thymus.     

Adherent cells in granulocyte-macrophage colony-stimulating factor-induced bone marrow-derived dendritic cell culture system are qualified dendritic cells

A widely-used method for generating dendritic cell (DC) is to culture bone marrow cells in granulocyte-macrophage colony-stimulating factor (GM-CSF)-containing medium for 6-10 days. Usually, non-adherent cells are used as qualified dendritic cells while the adherent ones are discarded as “non-dendritic cells” or macrophages. In this study, we show that the adherent cells are nearly identical to the non-adherent cells in both dendritic cell surface markers expression and main dendritic cell-related functions, hence to prove that these “junk cells” are actually qualified dendritic cells.     

Total lymphoid irradiation leads to transient depletion of the mouse thymic medulla and persistent abnormalities among medullary stromal cells

Mice given multiple doses of sublethal irradiation to both the thymus and the peripheral lymphoid tissues showed major transient, and some persistent disruptions in general thymic architecture and in thymic stromal components. At 2 wk after total lymphoid irradiation (TLI), the thymus lacked identifiable medullary regions by immunohistochemical analyses. Medullary stromal cells expression MHC Ag or a medullary epithelial cell Ag, as well as medullary macrophages, were undetectable. Instead, the processes of cortical epithelial cells were observed throughout the entire thymus. Strikingly, thymocyte subsets with mature phenotypes (CD4+CD8- and CD4-CD8+) were present in the apparent absence of a medulla. This early, gross effect was rapidly reversed such that by 1 to 2 mo after TLI, medullary areas with MHC Ag-positive cells were evident. However, abnormalities in a subset of medullary stromal cells appeared to be more persistent. Medullary epithelial cells, identified by the MD1 mAb, were greatly reduced in number and abnormally organized for at least 4 mo after TLI. In addition, macrophages containing endogenous peroxidase activity, normally abundant in medullary regions, were undetectable at all times examined after TLI. Therefore, this irradiation regimen induced both transient and long term effects in the thymus, primarily in medullary regions. These results suggest that TLI may be used as an experimental tool for studying the impact of selective depletion of medullary stromal cells on the development of specific T cell functions.     

Development of peritoneal macrophage along a dendritic cell lineage in response to uptake of oligomannose-coated liposomes

In this study, we investigate the potential of peritoneal macrophages to differentiate into dendritic cell (DCs) in response to preferential uptake of oligomannose-coated liposomes (OMLs). About 30% of peritoneal cells (PECs) preferentially took up OMLs that were administered into the peritoneal cavity. The OML-ingesting cells expressed CD11b and F4/80, but lacked CD11c expression, indicating that the OML-ingesting PECs with a CD11b^highCD11c⁻ phenotype are resident peritoneal macrophages. During in vitro cultivation, CD11c⁺ cells arose among the PECs with ingested OMLs. CD11c⁺ cells also developed among enriched peritoneal CD11b^highCD11⁻ cells from OML-treated mice, and the resulting CD11c⁺ cells expressed co-stimulatory molecules and MHC class II. In addition, OML-ingesting CD11b^highCD11c⁺ cells were found in spleen after the enriched peritoneal macrophages with ingested OMLs were transplanted in the peritoneal cavity of mice. These results show that a fraction of peritoneal macrophages can differentiate into mature DCs following uptake of OMLs.     

Circulating CD2+ monocytes are dendritic cells

Low levels of CD2 have been described on subsets of monocytes, macrophages, and dendritic cells. CD2 is expressed on about one-third of circulating monocytes, at levels one-half log lower than on T or NK cells, representing 2-4% of PBMC. FACS analysis of CD2+ and CD2- monocytes revealed no significant difference in the expression of adhesion molecules (CD11a/b/c), class II Ags (HLA-DR, -DQ, -DP), myeloid Ags (CD13, CD14, CD33), or costimulatory molecules (CD80, CD86). Freshly isolated CD2+ and CD2- monocytes were morphologically indistinguishable by phase contrast microscopy. However, scanning electron microscopy revealed large prominent ruffles on CD2+ monocytes in contrast to small knob-like projections on CD2- monocytes. After 2 days of culture, the CD2+ monocytes largely lost CD14 expression and developed distinct dendrites, whereas the CD2- monocytes retained surface CD14 and remained round or oval. Freshly isolated CD2+ monocytes were more potent inducers of the allogeneic MLR and more efficiently induced proliferation of naive T cells in the presence of HIV-1 gp120 than did CD2- monocytes. After culture in the presence of GM/CSF and IL-4, CD2+ monocytes were up to 40-fold more potent than monocyte-derived dendritic cells or CD2- monocytes at inducing allogeneic T cell proliferation. These findings suggest that circulating CD2+ and CD2- monocytes are dendritic cells and the precursors of macrophages, respectively. Thus, dendritic cells are far more abundant in the blood than previously thought, and they and precursors of macrophages exist in the circulation as phenotypically, morphologically, and functionally distinct monocyte populations.     

The lymphoid past of mouse plasmacytoid cells and thymic dendritic cells

There has been controversy over the possible lymphoid origin of certain dendritic cell (DC) subtypes. To resolve this issue, DC and plasmacytoid pre-DC isolated from normal mouse tissues were analyzed for transient (mRNA) and permanent (DNA rearrangement) markers of early stages of lymphoid development. About 27% of the DNA of CD8(+) DC from thymus, and 22-35% of the DNA of plasmacytoid pre-DC from spleen and thymus, was found to contain IgH gene D-J rearrangements, compared with 40% for T cells. However, the DC DNA did not contain IgH gene V-D-J rearrangements nor T cell Ag receptor beta gene D-J rearrangements. The same DC lineage populations containing IgH D-J rearrangements expressed mRNA for CD3 chains, and for pre-T alpha. In contrast, little of the DNA of the conventional DC derived from spleen, lymph nodes, or skin, whether CD8(+) or CD8(-), contained IgH D-J rearrangements and splenic conventional DC expressed very little CD3 epsilon or pre-T alpha mRNA. Therefore, many plasmacytoid pre-DC and thymic CD8(+) DC have shared early steps of development with the lymphoid lineages, and differ in origin from conventional peripheral DC.     

Characterization of T lymphocyte colony-forming cells in the mouse. The colony-forming cell is confined to Lyt-1,2,3+ cell subsets in the thymus and the lymph nodes

When cell populations from the thymus were studied with FACS, it was found consistently that the brightly labeled Thy-1.2+ populations contained very few T colony-forming cells (CFC), while these latter cells were numerous in the cell populations showing lower Thy-1.2 antigen density. This was paralleled by findings after peanut agglutinin (PNA) separation that showed enrichment of CFC in the PNA-negative medullary population, and by sorting based on TL, T-200, and H-2 determinants or light scatter properties of the cells. By FACS sorting of Lyt-labeled thymic cells, it was also shown that CFC were predominantly present in cell populations that were brightly Lyt-1+, and exclusively in populations that were Lyt-2+ and Lyt-3+. After FACS sorting of lymph node cells, no major differences in colony formation were found between dully- and brightly-labeled Thy-1.2+ or Lyt-1+ populations, or between lymphoid cells showing different light scatter characteristics. In addition, it was shown that CFC--like thymic CFC--were of the Lyt-1,2,3+ phenotype. It is concluded that the CFC may be present in several differentiation steps of Lyt-1,2,3+ cell lines, and that the frequency of these cells increases from the thymic cortex via the medulla and to peripheral lymphoid tissues.     

Cutting Edge: A possible role for CD4+ thymic macrophages as professional scavengers of apoptotic thymocytes

A vast majority of thymocytes are eliminated during T cell development by apoptosis. However, apoptotic thymocytes are not usually found in the thymus, indicating that apoptotic thymocytes must be eliminated rapidly by scavengers. Although macrophages and dendritic cells are believed to play such role, little is known about scavengers in the thymus. We found that CD4(+)/CD11b(+)/CD11c(-) cells were present in the thymus and that they expressed costimulatory molecules for T cell selection and possessed Ag-presenting activity. Moreover, these CD4(+)/CD11b(+) cells phagocytosed apoptotic thymocytes much more efficiently than thymic CD4(-)/CD11b(+) cells as well as activated peritoneal macrophages. CD4(+)/CD11b(+) cells became larger along with thymus development, while no such change was observed in CD4(-)/CD11b(+) cells. Finally, engulfed nuclei were frequently found in CD4(+)/CD11b(+) cells. These results strongly suggest that thymic CD4(+)/CD11b(+) cells are major scavengers of apoptotic thymocytes.