Granulocyte/macrophage colony-stimulating factor is essential for the viability and function of cultured murine epidermal Langerhans cells.

A panning method has been developed to enrich Langerhans cells (LC) from murine epidermis. In standard culture media, the enriched populations progressively lose viability over a 3-d interval. When the cultures are supplemented with keratinocyte-conditioned medium, LC viability is improved and the cells increase in size and number of dendritic processes. Accessory function, as monitored by stimulating activity in the mixed lymphocyte reaction (MLR), increases at least 10-20-fold. The conditioned media of stimulated macrophages and T cells also support the viability and maturation of cultured LC. A panel of purified cytokines has been tested, and only granulocyte/macrophage colony-stimulating factor (GM-CSF) substitutes for bulk-conditioned medium. The recombinant molecule exhibits half-maximal activity at 5 pM. Without activity are: IL-1-4; IFN-alpha/beta/gamma; cachectin/TNF; M- and G-CSF. A rabbit anti-GM-CSF specifically neutralizes the capacity of keratinocyte-conditioned medium to generate active LC. However, GM-CSF is not required for LC function during the MLR itself. We conclude that the development of immunologically active LC in culture is mediated by GM-CSF. The observation that these dendritic cells do not respond to lineage-specific G- and M-CSFs suggests that LC represent a distinct myeloid differentiation pathway. Because GM-CSF can be made by nonimmune cells and can mediate the production of active dendritic cells, this cytokine provides a T-independent mechanism for enhancing the sensitization phase of cell-mediated immunity.

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

The response of thymocytes to lectin is a standard tissue culture model for identifying cytokines such as IL-1 that are required for thymocyte mitogenesis. To study accessory cell requirements for these responses, it was necessary to deplete endogenous accessory cells with two techniques: anti-Ia and complement, and passage over nylon wool. Proliferation to Con A was then restored with 0.1-0.3% exogenous splenic dendritic cells, or 30-fold higher levels of peritoneal macrophages. The "costimulatory" action of IL-1, whereby responses to lectin were enhanced 3-10-fold, required the presence of dendritic cells. This effect of IL-1 could be reproduced by culturing the dendritic cells for 12 h in 1 U/ml human or murine rIL-1 alpha before addition to the thymocyte proliferation assay. The function of IL-1-treated dendritic cells was not blocked by a neutralizing anti-IL-1 antibody. The endogenous population of thymic accessory cells was partially characterized. A trace (0.1-0.3%) fraction of Ia+, Ig-, plastic nonadherent dendritic cells was visualized and enriched to a level of 1-10% by depleting CD4+,CD8+, and Ig+ lymphocytes. When this double-negative population was cultured with IL-1 and washed, the treated thymic dendritic cells were 10-fold more active as accessory cells. When the CD4-,CD8-, Ig- populations were depleted of dendritic cells with anti-Ia and complement, the subsequent addition of IL-1 had a second effect. Ia+ dendritic cells redeveloped over a 2-d interval, and they exhibited the same properties as resident dendritic cells in thymus and spleen. The majority were lysed by 33D1 anti-dendritic cell mAb and complement, lacked Fc receptors, and acted as powerful stimulators of the MLR and Con A mitogenesis. The development of dendritic cells did not occur with IL-2, -3, -4 or granulocyte/macrophage colony-stimulating factor or in nylon-nonadherent populations. The IL-1-dependent, Ia- precursor was not detectable in bone marrow. These results begin to analyze the endogenous accessory function of the thymus in culture. Dendritic cells actively stimulate thymocyte mitogenesis. The mitogenic action of IL-1 involves effects on resident Ia+ dendritic cells as well as a new population of thymic, Ia- precursors.

Antigen processing by epidermal Langerhans cells correlates with the level of biosynthesis of major histocompatibility complex class II molecules and expression of invariant chain.

Two prior studies with a small number of T cell lines have shown that the presentation of native protein antigens by epidermal Langerhans cells (LC) is regulated. When freshly isolated, LC are efficient antigen-presenting cells (APC), but after a period of culture LC are inefficient or even inactive. The deficit in culture seems to be a selective loss in antigen processing, since cultured LC are otherwise rich in major histocompatibility complex (MHC) class II products and are active APC for alloantigens and mitogens, which do not require processing. We have extended the analysis by studying presentation to bulk populations of primed lymph node and a T-T hybrid. Only freshly isolated LC can be pulsed with the protein antigens myoglobin and conalbumin, but once pulsed, antigen is retained in an immunogenic form for at least 2 d. The acquisition of antigen, presumably as MHC-peptide complexes, is inhibited if the fresh LC are exposed to foreign protein in the presence of chloroquine or cycloheximide. The latter, in contrast, improves the efficacy of antigen pulsing in anti-Ig-stimulated B blasts. In additional studies of mechanism, we noted that both fresh and cultured LC endocytose similar amounts of an antigen, rhodamineovalbumin, into perinuclear granules. However, freshly isolated LC synthesize high levels class II MHC molecules and express higher amounts of the class II-associated invariant chain. Fresh LC are at least 5-10 times more active than many other cells types in the level of biosynthesis of MHC class II products. These findings provide a physiologic model in which newly synthesized MHC class II molecules appear to be the principal vehicle for effective antigen processing by APC of the dendritic cell lineage. Another APC, the B lymphoblast, does not appear to require newly synthesized MHC class II molecules for presentation.

The distinct leukocyte integrins of mouse spleen dendritic cells as identified with new hamster monoclonal antibodies.

Hybridoma fusions with hamster hosts were undertaken to generate mAbs to mouse spleen dendritic cells. Two mAb were obtained and used to uncover the distinct integrins of these APC. One, 2E6, bound a determinant common to all members of the CD11/CD18 family, most likely the shared 90 kD CD18 beta chain. 2E6 immunoprecipitated the characteristic beta 2 integrin heterodimers from lymphocytes (p180, 90; CD11a) and macrophages (p170,90; CD11b), but from dendritic cells, a p150,90 (presumably CD11c) integrin was the predominant species. 2E6 inhibited the binding function of the CD11a and CD11b integrins on B cells and macrophages in appropriate assays, but 2E6 exerted little or no inhibition on the clustering of dendritic cells to T cells early in primary MLR, suggesting a CD11/CD18-independent mechanism for this binding. The second mAb, N418, precipitated a 150, 90 kD heterodimer that shared the 2E6 CD18 epitope. This N418 epitope may be the murine homologue of the previously characterized human CD11c molecule, but the epitope was only detected on dendritic cells. N418 did not react with peritoneal macrophages, anti-Ig-induced spleen B blasts, or bulk lymph node cells. When used to stain sections of spleen, N418 stained dendritic cells in the T-dependent areas, much like anti-class II mAbs that were also generated in these fusions. In addition, N418 revealed nests of dendritic cells that punctuated the rim of marginal zone macrophages between red and white pulp. This localization positioned most dendritic cells at regions where arterial vessels and T cells enter the white pulp. We conclude that the p150, 90 heterodimer is the major beta 2 integrin of spleen dendritic cells, and we speculate that it may function to localize these APC at sites that permit access to the recirculating pool of resting T cells.

Quantitation of surface antigens on cultured murine epidermal Langerhans cells: rapid and selective increase in the level of surface MHC products.

It was recently discovered that murine epidermal Langerhans cells (LC) changed significantly in function and phenotype when maintained in culture. Notably, accessory cell function for primary immune responses increased while cytologic markers like ATPase, nonspecific esterase, and Birbeck granules were lost. To further analyze LC differentiation, we used flow cytometry and a panel of 22 monoclonal antibodies to quantitate changes in surface antigens at the single-cell level. A striking change was a fivefold increase in the amount of Ia antigens (which are expressed on class II MHC products) during the first day of culture. The increase was evident within 3 h and reached a plateau at 15-24 h. Both I-A and I-E products behaved similarly. The increase in Ia was blocked by 1 microgram/ml cycloheximide. Expression of other surface antigens was then monitored on Ia+ LC by two-color flow cytometry. Low levels of class I (H-2D and H-2K) MHC products were detected on freshly isolated LC, and these antigens also increased severalfold during the first day of culture. Fc receptors (identified with the 2.4G2 mAb) and the F4/80 macrophage antigen decreased, as reported previously. Three antigens that were detected in fresh suspensions were expressed at constant levels in culture. These were the C3bi receptor and the pan leukocyte and interdigitating cell antigens. Several leukocyte antigens that were not found initially on LCs did not appear, including B220 anti-B cell, 33D1 anti-dendritic cell, and CD4, CD5, CD8 T-cell specificities. We conclude that the surface of cultured LCs undergoes selective changes in culture. As a result, the cells are rich in Ia and H-2 and have detectable C3bi receptors, but have little or no LFA-1, Ti, CD4, 5, and 8, 33D1, 2.4G2, F4/80, and B220 antigens.

Use of the fluorescence activated cell sorter to enrich dendritic cells from mouse spleen.

Dendritic cells are a specialized but trace population of antigen presenting cells that always have been enriched by multi-step procedures over a period of 1 or more days in tissue culture. Here we describe the isolation of dendritic cells from fresh mouse spleen suspensions using the FACS and a monoclonal antibody, N418, to the p150/90 member of the leukocyte integrin family (Metlay et al., 1990). By two color fluorescence activated cell sorter (FACS) analyses, the trace N418+ subset expressed most of the surface markers, including the 33D1 antigen, that are characteristic of dendritic cells isolated by other methods. An exception was that small amounts of Fc receptors, CD4 and F4/80 antigen were detected initially, but these diminished upon culture. In functional assays, sorted N418+ cells from fresh spleen were at least 30 times more active than N418- cells in presenting antigen to T cells. The assays were stimulation of the primary mixed leukocyte reaction and presentation of exogenous protein antigens to sensitized populations of lymph node T cells. The viability and MLR stimulating function of the sorted populations both were increased upon exposure to the cytokine, granulocyte-macrophage colony stimulating factor (GM-CSF). These results indicate that dendritic cells can be enriched from fresh isolates of mouse spleen using the FACS, and that when this is done, many of the distinctive features of dendritic cells - phenotype, APC function, and sensitivity to appropriate cytokines - are apparent.

The surface of dendritic cells in the mouse as studied with monoclonal antibodies.

A family of dendritic cells has been identified in situ and in vitro by microscopy and immunolabeling. The members of this family include the dendritic cells isolated from lymphoid organs, Langerhans cells [LC] of the epidermis, veiled cells in afferent lymph, and interdigitating cells [IDC] in the T-cell areas. Some common features to all members of the family are high levels of MHC class II antigens, a lack of most B and T cell markers, and an absence or low levels of macrophage/granulocyte antigens. This review summarizes the markers of mouse dendritic cells as assessed by a panel of monoclonal antibodies, and stresses a few recent findings. 1) In spleen, there are two populations of dendritic cells. More than 75% of isolated cells are 33D1+, NLDC145-, and J11d-, while the remainder have the reciprocal phenotype and thus share the NLDC145 antigen of IDC. Thymic dendritic cells, released by collagenase digestion, and epidermal LC also are 33D1-, NLDC145+, J11d+. 2) When epidermal LC are placed in culture, there are changes in cell function and phenotype. There is a decrease in Fc gamma receptors and the F4/80 macrophage antigen, an increase in class I and II MHC products and p55 IL-2 receptors, and persistence of the NLDC145 IDC antigen. The cultured LC thereby resembles the IDC. 3) A new antibody N418 shows that dendritic cells express the p150/90 member of the leukocyte beta 2 integrin family. Immunolabeling of tissue sections of spleen indicates that N418+ dendritic cells not only are present in the periarterial sheaths, the location of IDC, but also in "nests" at the periphery of the T area where 33D1 has been found. The peripheral collections interrupt the marginal zone of macrophages that separates white and red pulp, and places the dendritic cells in the path of T cells as they move through the white pulp. Therefore the members of the dendritic cell family have important markers in common, as well as differences that are associated with state of immunologic function and location.

Tissue distribution of the DEC-205 protein that is detected by the monoclonal antibody NLDC-145. II. Expression in situ in lymphoid and nonlymphoid tissues.

The rat monoclonal antibody NLDC-145, which has been utilized as a marker for mouse dendritic cells in numerous studies, binds an antigen that is more broadly distributed. This antigen is a unique 205-kDa integral membrane glycoprotein called DEC-205, which we have recently purified in quantities sufficient for basic biochemical studies, N-terminal sequencing, and immunization of rabbits. In cytofluorographic experiments, both the new polyclonal antibody and the original monoclonal detected DEC-205 on many classes of nondendritic murine leukocytes, particularly B cells. The quantities of DEC-205 on the surfaces of these cells were 10 to 50 times lower than those on epidermal and bone marrow dendritic cells. Here we utilize these reagents to reassess the tissue distribution of DEC-205 by immunohistochemical staining of frozen sections from a variety of organs, and by multiple-organ immunoblotting. Abundant expression of DEC-205 was confirmed histologically on thymic and intestinal epithelia and on dendritic cells in the T cell areas of peripheral lymphoid organs. In addition, DEC-205 was visualized in several other locations: B lymphocytes within B cell follicles, the stroma of the bone marrow, the epithelia of pulmonary airways, and the capillaries of the brain. Immunoblotting confirmed the presence of substantial levels of DEC-205 protein in lysates prepared from lymphoid tissues and from lung, marrow, and intestine. Thus, while DEC-205 is expressed at high levels by dendritic cells, it is also expressed by a number of other cell types in situ.

Macrophages, but not dendritic cells, accumulate colloidal carbon following administration in situ.

The dendritic cell system operates in situ to capture and present antigens in a form that is immunogenic to T cells. It is likely that dendritic cells require endocytic activity in order to process antigens. On the other hand, macrophages are considered to be the principal cells that internalize substrates in situ. We therefore investigated the phenotype of cells that scavenge the indigestible endocytic tracer, colloidal carbon, by phenotyping the endocytic cells with monoclonal antibodies that help distinguish macrophages from dendritic cells. Of some importance was the monoclonal N418, an antibody to the p150/90 leukocyte beta 2 integrin. FACS analyses on isolates from blood, spleen and peritoneal cavity showed that N418 reacts primarily with dendritic cells. N418 also stained dendritic profiles strongly in tissue sections of liver and spleen, but most of the cells that actively endocytosed carbon in both organs showed little or no N418 staining. Likewise, carbon could not be identified in cells that react with M342, which stains intracellular granules of dendritic cells. In contrast, the carbon-labeled cells in both liver and spleen were labeled with antibodies (SER-4, F4/80, FA11) that bind primarily to isolated macrophages. Therefore the clearance of colloidal carbon in situ reflects the scavenging activity of macrophages and not the endocytic activity that underlies the antigen presenting function of dendritic cells.

Identification of macrophages and dendritic cells in the osteopetrotic (op/op) mouse.

We used a panel of monoclonal antibodies and immunocytochemistry to identify macrophages and dendritic cells in mice that are deficient in macrophage colony stimulating factor (M-CSF or CSF-1) because of the recessive osteopetrotic (op/op) mutation. Prior work had shown that osteopetrosis is associated with a lack of osteoclasts, phagocytic cells required for remodelling in bone. Additional macrophage populations proved to be very M-CSF dependent. op/op mice had few and sometimes no peritoneal cavity phagocytes, splenic marginal zone metallophils, and lymph node subcapsular sinus macrophages. Other populations, however, reached substantial levels in the absence of M-CSF, including phagocytes in the thymic cortex, splenic red pulp, lymph node medulla, intestinal lamina propria, liver (Kupffer cells), lung (alveolar macrophages) and brain (microglia). Dendritic cells, which are specialized accessory cells for T-dependent immune responses and tolerance, were readily identified in skin and in the T-dependent regions of spleen, lymph node and Peyer's patch. The identification of dendritic cells utilized antibodies to MHC class II products and four different antigens that are primarily expressed by these accessory cells. Our findings indicate that only a few macrophage populations are critically dependent upon M-CSF in vivo. With respect to dendritic cells, the data are consistent with prior in vitro work where it was noted that GM-CSF but not M-CSF supported dendritic cell viability, function and growth.

Bone marrow-derived chimerism in non-irradiated, cyclosporin-treated rats receiving microvascularized limb transplants: evidence for donor-derived dendritic cells in recipient lymphoid tissues.

Tolerance to donor transplantation antigens develops when recipients are made chimeric with donor bone marrow. To establish chimerism, the haemopoietic system of recipients typically is severely compromised. We report on a system in which chimerism develops without ablative therapies. Immunosuppression with cyclosporin A allowed the lower limb of a rat to be replaced by a microvascularized transplant from a fully allogeneic donor. Many donor-derived cells populated recipient lymph nodes and spleen, and most had the large size, irregular shape and strong major histocompatibility complex (MHC) class II expression that typify dendritic cells. Donor cells were not found in the macrophage-rich regions of lymphoid tissues, but instead occupied splenic white pulp and lymph node cortex. The donor cells were derived from radiosensitive marrow precursors, as chimerism was abolished if the grafted limb was irradiated, or if muscle and skin flaps devoid of bone were grafted. Donor cells were rare or not detectable in blood, thymus and liver. Whereas lymphoid chimerism was prominent following limb transfer, donor cells were not detected 1-2 weeks after an injection of two femur equivalents of a marrow suspension. We suggest that dendritic cells that undergo rapid turnover in lymphoid organs are replaced from allogeneic precursors in bone grafts. The combination of cyclosporin and vascularized bone provides a means for inducing chimerism in lymphoid tissues of non-irradiated recipients.