Migration patterns of dendritic cells in the mouse. Homing to T cell-dependent areas of spleen, and binding within marginal zone.

Using quantitative techniques we have shown elsewhere that dendritic cells (DC) migrate from blood into the spleen, under the control of T cells. Here we traced the localization of DC within the spleen and sought to explain the means by which they entered. DC were labeled with a fluorochrome, Hoescht 33342, and injected intravenously. Spleens were removed 3 or 24 h later and DC were visualized within particular areas that were defined by mAbs and FITC anti-Igs. At 3 h most DC were in the red pulp, whereas by 24 h the majority had homed to T-dependent areas of the white pulp and may have become interdigitating cells. Lymphoid DC, isolated from spleen and perhaps normally present in blood, may thus be a migratory stage distinct from the relatively fixed interdigitating cells. We also developed a frozen section assay to investigate the interaction of DC with various lymphoid elements. When DC were incubated on sections of spleen, at 37 degrees C but not at 4 degrees C they attached specifically within the marginal zone and did not bind to T areas; in contrast, macrophages attached only to red pulp and T cells did not bind specifically. However, DC did not bind to sections of mesenteric lymph node, whereas T cells localized in particular regions at 4 degrees C but not at 37 degrees C, probably the high endothelial venules. DC may thus express "homing receptors," similar to those of T cells, for certain endothelia. We propose that T cells can modify the vascular endothelium in certain areas to allow egress of DC from the bloodstream.

Dendritic cell loss from nonlymphoid tissues after systemic administration of lipopolysaccharide, tumor necrosis factor, and interleukin 1.

Dendritic cells (DC) in nonlymphoid organs can internalize and process foreign antigens before migrating to secondary lymphoid tissues to initiate primary immune responses. However, there is little information on which stimuli promote migration of DC from the tissues. Systemic administration of lipopolysaccharide (LPS), which induces in vivo production of cytokines, led to a reduction in the numbers of major histocompatibility complex class II-positive (Ia+) leukocytes in mouse hearts and kidneys: > 95% of DC were depleted 1-3 d after injection of 50 micrograms LPS. Several lines of evidence indicated that this response was due to migration of DC rather than loss of Ia expression or cytotoxic effects. In skin of treated mice, the number of Ia+ epidermal Langerhans' cells (LC) was reduced, and "cords" of Ia+ leukocytes became evident in the dermis. The latter cells expressed little NLDC145 and may have originated from recruited or resident DC progenitors. Systemic administration of recombinant tumor necrosis factor (rhTNF)-alpha resulted in a decrease in numbers of Ia+ cells in heart and kidney and of epidermal LC, and it also induced dermal cords. Administration of a rh-interleukin (IL)-1 resulted in a decrease in Ia+ cells only in renal medulla, appeared to activate a subset of epidermal LC, and induced dermal cords. Similar microgram doses of rhIL-2 had no obvious effect. Treatment with a neutralizing anti-TNF antiserum before LPS administration inhibited the depletion of LC from skin but not from heart or kidney. Therefore, TNF-alpha and IL-1 alpha may promote DC migration from nonlymphoid tissues and may have differential effects on different DC populations, but it is unclear whether they act on DC directly or indirectly (e.g., via other cytokines).

Migration and maturation of Langerhans cells in skin transplants and explants.

The behavior of Langerhans cells (LC) has been examined after skin transplantation and in an organ culture system. Within 24 h (and even within 4 h of culture), LC in epidermal sheets from allografts, isografts, and explants dramatically increased in size and expression of major histocompatibility complex class II molecules, and their numbers were markedly decreased. Using a new procedure, dermal sheets were then examined. By 24 h, cells resembling LC were found close to the epidermal-dermal junction, and by 3 d, they formed cords in dermal lymphatics before leaving the skin. In organ culture, the cells continued to migrate spontaneously into the medium. These observations establish a direct route for migration of LC from the epidermis into the dermis and then out of the skin. These processes are apparently induced by a local inflammatory response, and are independent of host-derived mediators. The phenotype of migratory cells was then examined by two-color immunocytochemistry and FACS analysis. The majority of migratory leukocytes were Ia+ LC, the remainder comprised Thy-1+, CD3+, CD4-, CD8- presumptive T cell receptor gamma/delta+ dendritic epidermal cells, which clustered with the LC, and a small population of adherent Ia-, FcRII+, CD11a/18+ macrophages. In contrast to the cells remaining within the epidermis of grafted skin at 1 d, the migratory cells were heterogeneous in phenotype, particularly with respect to F4/80, FcRII, and interleukin 2 receptor alpha expression, which are useful markers to follow phenotypic maturation of LC. Moreover, cells isolated from the epidermis of grafts at 1 d were more immunostimulatory in the allogeneic mixed leukocyte reaction and oxidative mitogenesis than LC isolated from normal skin, though less potent than spleen cells. The day 1 migratory cells were considerably more immunostimulatory than spleen cells, and day 3-5 migratory cells even more so, suggesting that functional maturation continues in culture. Thus, maturation of LC commences in the epidermis and continues during migration, but the cells do not need to be fully mature in phenotype or function before they leave the skin. In vivo, the migration of epidermal LC via the dermis into lymphatics and then to the draining nodes, where they have been shown previously to home to T areas, would provide a powerful stimulus for graft rejection.

Systemic lipopolysaccharide recruits dendritic cell progenitors to nonlymphoid tissues.

Dendritic cells (DC) are thought to be the "passenger leukocytes" that sensitize the recipients of organ transplants against graft antigens and trigger allograft rejection. DC originate from MHC class II-negative (Ia-) progenitors in the bone marrow, which enter the tissues and develop into migratory cells with the specialized capacity to initiate primary immune responses. There is little information on which stimuli recruit DC progenitors to the tissues. Systemic administration of LPS to mice depletes Ia+ leukocytes from heart and kidney but recruits Ia- leukocytes (Roake JA, et al., see footnote 6). When these leukocytes were isolated and cultured overnight, Ia+ low density leukocytes developed that could stimulate primary T cell responses in vitro. Hearts from LPS-treated mice were transplanted to allogeneic recipients. One to 4 days after grafting, Ia+ donor cells were present in recipient spleens, localized to peripheral white pulp, and associated with CD4+, but not CD8+, T cells. Cells with the migratory characteristics of DC, therefore, originated from Ia- progenitors in the transplanted hearts. We conclude that LPS recruits Ia- DC precursors to the heart and kidneys. Hearts from LPS-treated donors were rejected by allogeneic recipients at the same tempo as normal hearts, implying that Ia- DC progenitors might ultimately contribute to heart graft rejection (direct sensitization). However, since hearts from cyclophosphamide-treated donors, which do not give rise to Ia+ cells in recipient spleens, were also rejected at a similar tempo, indirect sensitization could also play a role in heart graft rejection in this model.

Isolation of dendritic leukocytes from non-lymphoid organs.

These observation suggest that dendritic leukocytes from several different non-lymphoid organs in situ are functionally immature and that in this respect they more closely resemble epidermal LC than mature lymphoid DC. The exception appears to be the interstitial dendritic leukocytes from small and large intestinal lamina propria and Peyer's patches, where functional maturation could be attributed to constitutively secreted GM-CSF by lamina propria cell in situ, or alternatively to the isolation procedure which might lead to functional maturation of gut DC. After overnight culture, and possibly following organ transplantation, interstitial dendritic leukocytes may mature into potent activators of antigen-specific T-cell proliferation (immunostimulation). Further studies are needed to characterize dendritic leukocytes in solid non-lymphoid organs, and these may lead to new strategies for overcoming graft rejection by inhibiting the maturation of dendritic leukocytes after transplantation.

Isolation and characterization of dendritic cells from mouse heart and kidney.

Dendritic cells (DC) are thought to be distributed throughout lymphoid and most nonlymphoid tissues. Single cell suspensions were prepared from mouse hearts and kidneys. Subsets of MHC class II-positive (Ia+) leukocytes from both sources expressed markers such as CDw32 Fc receptors, F4/80, and complement receptor type 3 (CD11b/CD18). The capacity of these cells to initiate primary in vitro immune responses was assessed using oxidative mitogenesis and allogeneic mixed leukocyte responses. After fractionation by density centrifugation, cell sorting, immunomagnetic bead separation, or cell panning, the stimulatory activity of kidney cell suspensions was found to reside in the low density, Ia+ leukocyte fractions after overnight culture (day 1). In contrast, freshly isolated (day 0) cells had considerably less or no activity in these assays. However, depletion of Ia+ or CD45+ cells on day 0 followed by overnight culture removed the stimulatory activity on day 1. Therefore, day 0 kidney cells contain Ia+ leukocytes that can acquire or up-regulate their stimulatory activity during overnight culture. Similar observations were made for cells isolated from hearts, except that a population of uncharacterized nonleukocytes with stimulatory activity was detected on day 0 but not day 1. The phagocytic capacity of the leukocytes was then examined. Subsets of Ia+ cells phagocytosed zymosan, as shown by two-color flow cytometry and other immunofluorescence studies, and the zymosan-positive cells from kidney were able to initiate primary responses. Overall, these data demonstrate the existence of DC in kidneys and hearts, and suggest that in situ these cells resemble immature rather than mature DC.