Control mechanism of lymphocyte traffic. A study of the action of two sulfated polysaccharides on the distribution of 51Cr- and [3H]adenosine-labeled mouse lymph node cells

The effects of dextrans of varying molecular weights and of pentosan sulfate on the distribution of ⁵¹Cr-labeled mouse lymph node cells were studied in vivo, i.e., in recipients treated with the sulfated polysaccharides, and in vitro, i.e., by following the fate of cells treated in vitro, in intact syngeneic recipients. Both types of experiments demonstrate that dextrans, especially dextran sulfate (DXS) and pentosan sulfate (PS), considerably reduce lymph node entry of lymphocytes, with concomitant increases in the blood and, in the case of DXS, in both the blood and lungs. A parallel quantitative autoradiographic analysis of the distribution of [³H]adenosine-labeled cells confirmed the data with the ⁵¹Cr-labeled cells and, in adidtion, indicated that DXS and PS slow down circulation of lymphocytes through the marginal zone and red pulp of the spleen and, in the case of DXS, in the pulmonary capillary bed. Unusually large numbers of unlabeled lymphocytes were found in the endothelial wall of the post-capillary venules in lymph nodes of PS-treated mice.     

The influence of strong transplantation antigens (Ag-B) on lymphocyte migration in vivo.

The tissue localization of syngeneic thoracic duct lymphocytes was compared to that of allogeneic cells in four rat strain combinations differing at the Ag-B locus (HO → DA, DA → HO, AO → HO, HO → AO). Dual isotope labeling with [³H]uridine and [¹⁴C]uridine was applied in order so that the distribution of allogeneic and syngeneic cells could be followed in one recipient. During the first couple of hours after iv injection, allogeneic lymphocytes usually migrated as easily into the various tissues as did syngeneic cells. However, after 24 and 48 hr, a reduced amount of label associated with allogeneic cells was often measured in the tissues. This reduction differed in magnitude in the different strain combinations and was most pronounced in the lymph nodes. A reduced number of allogeneic cells also appeared in the thoracic duct. By contrast, no reduced localization of allogeneic lymphocytes was measured in the draining popliteal lymph nodes late after sc injection. In preimmunized animals allogeneic cells were rapidly removed from the blood and therefore failed to localize in the lymphoid tissues. Furthermore, the lymph node localization of allogeneic cells was more like that of syngeneic cells in splenectomized rats, as well as in irradiated recipients (when the irradiation was given shortly before cell transfer). It is concluded that transplantation antigens play no essential role in the interaction between recirculating lymphocytes and the venous endothelium at the sites where the large-scale physiological emigration of the cells takes place (the HEVS of the lymph nodes and the marginal zone vessels of the spleen). The elimination of allogeneic cells is found later; it probably takes place in the lymph nodes and spleen. Possible mechanisms responsible for this rapid removal of allogeneic lymphocytes in nonimmunized recipients are discussed.     

Further evidence for the existence of B-lymphocyte subpopulations.

We have studied the homing properties of B lymphocytes by using ⁵¹Cr-labeled lymphoid cells obtained from athymic, nu/nu mice, and animals made T-lymphocyte deficient by thymectomy and lethal irradiation followed by reconstitution with syngeneic bone marrow. Comparison was made to the patterns of distribution observed when cell preparations containing normal numbers of T and B lymphocytes were migrated. A small but significant percentage of labeled lymphocytes from lymph nodes, spleen, Peyer's Patches, and bone marrow of T-cell-deficient animals was shown to be lymph node seeking. Secondary transfers of lymph node cells from primary recipients caused enrichment of this lymph node-seeking population. Treatment of T-lymphocyte-deficient lymphoid cell preparations with neuraminidase reduced the percentages of cells homing to the lymph nodes. The data showed that B lymphocytes exhibit unique homing properties when injected into normal recipients. In addition, direct comparison of the homing patterns of B lymphocytes prepared from spleen and lymph nodes of athymic mice revealed differences suggesting that these lymphoid organs contained unique mixtures of at least two different kinds of B cell. The evidence supports the notion that the B-lymphocyte populations contain at least two subpopulations, one of which possesses the ability to home to lymph nodes.     

Effects of concanavalin A on the migration of radioactively labeled lymphoid cells

The effects of the jackbean globulin Concanaalin A (Con A) on the distribution of radioactive ⁵¹Cr-labeled lymph node cells was studied in CBA mice. Lymph node cells treated in vitro with Con A in subagglutinating noncytotoxic doses were unable to “home” to the lymph nodes of syngeneic recipients after intraenous injection. The effect was almost immediate and seemed unrelated to mitogenesis. The inhibitory effect of Con A on lymphocyte migration could be partially reersed by alpha-methyl mannoside; the degree of migratory impairment was related to the amount of Con A bound to the lymphocyte surface at the time of transfer. The membrane site at which Con A binds to the lymphocytes is similar to that which is bound by heterologous antilymphocyte serum but is probably distinct from the theta antigenic site. These data lend support to the hypothesis that surface lymphocyte carbohydrate determinants are involved in the specific lymphocyte “homing” receptor.     

Effect of aging on T-cell tolerance induction

In the MHC compatible rat strain combination AS → HS, the same ⁵¹Cr-labeled lymph node suspension behaves totally differently depending on whether it is injected into syngeneic or allogeneic recipients. Using ⁵¹Cr-labeled lymph node suspensions from AS or (AS × HS)F1 donors, and AS, HS, and F₁ hosts, the distribution of label over a 72-hr period was studied. Evidence has been obtained that recognition of self-components results in the homing of cells to the lymph nodes in syngeneic hosts, while recognition of foreignness impairs homing of the same cells to the lymph nodes in allogeneic hosts. The spleen is the major organ in which these recognition processes occur. Substantially more cells are destroyed by nonimmune allogeneic hosts than by syngeneic hosts, a clear difference being apparent as early as 6 hr after injection. Some lymphoid cells are obligatory spleen seekers and do not enter the lymph nodes.     

Taenia crassiceps in the rat: transfer of immunity and immunocompetence with lymph node cells.

Using T. crassiceps infections of young AS₂ rats as a model system, it was shown that immunity can be transferred adoptively with lymph node cells, whereas serum from the same donors was ineffective. Normal adult rat lymph node cells also conferred immunocompetence on neonatal recipients. There was no correlation between antibody and elimination or persistence of metacestodes in infected rats. It is suggested that susceptibility of neonates to infection with this parasite is the result of functional immaturity of thymus-derived cells involved in cell-mediated immune responses rather than T-cell facilitation of antibody production.     

Tolerance induction to a thymus-dependent antigen in vitro: treatment of nonadherent cells with tolerogen biologically filtered in vitro

Highly tolerogenic bovine gamma globulin (BGG), a thymus-dependent antigen, was prepared by biologic filtraration in vitro. It readily induced tolerance in vivo in BALB/c mice and also rendered their nonadherent lymph node cells tolerant after in vitro incubation. Biologic filtration in vitro was carried out by incubating 2.5 × 10⁷ lymph node cells with 10 mg of nontolerogenic BGG in 10 ml of Eagle's medium containing 2% normal mouse serum at 37 °C for 6 hr. The BGG-containing medium was clarified by centrifugation and was used without further dilution.For tolerance induction in vitro, lymph node cells were separated into adherent and nonadherent populations on Falcon plastic. These cells were incubated for 0–18 hr at 37 °C with biologically filtered BGG (bBGG). After incubation, the cells were washed three times and (2–2.5) × 10⁷ nonadherent or 4 × 10⁶ adherent cells were injected iv with their untreated counterpart into lethally irradiated mice which had received 10⁶ bone marrow cells. The recipients were then challenged with 300 μg of aggregated BGG, and tolerance was assayed by the elimination of labeled BGG, rosette formation, and passive hemagglutination. Spleen cells were similarly treated for comparison. Our findings show that tolerance was not induced in vitro in adherent lymph node cells. However, in the nonadherent populations, those from the lymph node but not the spleen were rendered tolerant. The acquisition of tolerance in vitro was gradual. It was dependent upon the length of exposure to bBGG and required at least 6 hr.     

Effect of stimulating antibody formation under the influence of bone marrow cells in vivo]

Injection of intact bone marrow cells to mice at the peak of the secondary immune response results in a 2.4-fold increase of the number of antibody-forming cells in the regional lymph node. Preliminary injection of bone marrow cells to donors of the immune lymph node cells decreases the stimulation effect of antibody formation when the lymph node cells are subsequently cultivated with the intact bone marrow cells. The data obtained demonstrate the cell interaction at the level of mature antibody producers in vivo.     

Properties of reticulum cell sarcomas in SJL/J mice: II. Fate of labeled tumor cells in normal and irradiated syngeneic mice

Transplantable reticulum cell sarcoma (RCS) cells were labeled with ³H-uridine or ³H-thymidine in vitro and injected intravenously into normal and irradiated syngeneic SJL/J mice. RCS cells exhibited typical B cell migration characteristics in peripheral lymphoid organs in both normal and irradiated recipients, localizing in follicles in a pattern resembling that of labeled normal bone marrow cells. However, over the first 72 hr after transfer, RCS cells diluted their label much less in irradiated than in normal recipients, reflecting their inability to proliferate in the irradiated hosts. The presence of unlabeled tumor cells did not significantly affect the distribution of labeled normal bone marrow or lymph node cells in the recipients. Thus, RCS fails to grow in irradiated recipients in spite of undisturbed homing characteristics and in the absence of any evidence of cytotoxic influences from the host.     

Migration of IgA-bearing lymphocytes into salivary glands

The relative migratory properties of [¹²⁵I]iododeoxyuridine-labeled dividing mesenteric lymph node (MLN) and peripheral lymph node (PLN) cells were assessed in mice using the adoptive transfer system. MLN cells from virgin donors showed a greater tendency to localize in MLN, small intestine, and mammary glands (lactating recipients only) of virgin and lactating recipients. In addition, MLN cells were shown to selectively localize in the salivary (submandibular and sublingual) glands. The relative migratory properties of MLN and PLN cell populations were identical when donor cells were obtained from virgin or lactating animals. Selective depletion of IgA-bearing cells from the MLN transfer cell population abrogated the preferential localization in control mucosal tissues and salivary glands. These data show that the salivary glands can be included as an additional mucosal area populated by gut-derived IgA-bearing cells and provides direct evidence that the common mucosal immune sytstem extends to secretory tissue in the oral cavity.     

Effect of cortisone-resistant thymocytes on endogenous colony formation in inbred mice]

Endogenous colonies in the spleen of sublethally irradiated (CBA X C57BL/6) E1 hybrid mice were recorded after the injection of thymocytes and the lymph node cells from the hydrocortisone-treated and intact CBA mice. Cortisone-resistant thymocytes failed to suppress the endogenous colony formation, whereas the lymph node cells produced a distinct suppressive effect on the endogenous colonies. After the injection of cortisone-resistant thymocytes the number of colonies in the spleen of individual recipients was double that in control irradiated hybrids.     

Inhibition of erythroid cell growth by allogeneic murine lymphocytes. Evidence for a synergism between lymph node cells and thymocytes

Murine lymphoid cells from thymus and lymph nodes were tested for synergistic response in a graft-vs-host test. The test is based on the principle that allogeneic lymphocytes inhibit erythroid cell proliferation in the spleens of irradiated mice infused with syngeneic bone marrow cells.I was observed that mixtures of thymocytes and lymph node cells from the same parental strain yielded graft-vs-host responses in irradiated F₁-hybrids higher than expected by summing the responses of the two cell populations tested separately. A similar synergistic response was obtained using mixtures of thymocytes and lymph node cells obtained from the two parental strains of the hybrid, whereas such an effect was not detected using mixtures of lymph node cells or mixtures of thymocytes from the two parental strains. Nor could synergy be demonstrated between parental strain lymph node cells and thymocytes syngeneic with the bone marrow target cells. Thymocytes obtained from one parental strain which were injected into its irradiated F₁-hybrid transformed into a population of sensitized cells in the spleens of the recipients. This transformation was suppressed by the simultaneous injection of lymph node cells from the second parental strain. Since there is a synergistic immune response by such cell mixtures it is concluded that thymocytes may enhance the graft-vs-host response of lymph node cells. Parental strain thymocytes and lymph node cells, the latter being specifically immunologically tolerant to the bone marrow target cells, failed to give a synergistic response indicating that thymocytes do not transform unresponsive lymphocytes into responsive, but rather enhance the reactivity of existing, specifically responsive cells.The results thus show that thymocytes may enhance the response of lymph node cells in this specific graft-vs-host assay.     

Delayed-type hypersensitivity to allogeneic mouse epidermal cell antigens

Footpad swelling response was used to measure the alloantigenicity of epidermal cells (ECs) in delayed-type hypersensitivity (DTH). Strong footpad swelling was oberserved 3 h after the challenge, and it continued for 48 h after the challenge. Genetical incompatibility between the recipients and the ECs was required to induce significant footpad swelling. H-2 or non-H-2 incompatibility between mice and ECs in the sensitization phase sufficed to develop significant footpad swelling. Incompatibility caused by point mutation in the A region induced strong responses when B6. C-H-2 ^bm12 mice were immunized with B6/J ECs, but the disparity in immuno-globulin h (Igh) allotype genes was insufficient. H -Y antigen on ECs could also elicit the DTH response. Semiallogeneic F₁-derived ECs sensitized the parental recipients. The responses were successfully transferred by immune lymph node cells, but not by immune sera. Treatment of these immune lymph node cells with monoclonal antibodies plus complement revealed that the cells responsible for DTH transfer were Lyt-1⁺2^–, Ia^– T cells.Abbreviations used in this paper DNFB 2,4-dinitro-1-fluorobenzene - DTH delayed-type hypersensitivity - ECs epidermal cells - HBSS Hanks' balanced salt solution - MHC major histocompatibility complex - PBS phosphate-buffered saline     

Effect of tumor immunity on the distribution of labeled lymphoid cells in tumor-challenged mice

The distribution of ⁵¹Cr-labeled lymphoid cells from normal mice and mice immunized against a tumor were compared after intravenous inoculation of the labeled cells into normal syngeneic recipients. Spleen cell preparations from immune donors contained increased percentages of spleen and bone marrow-seeking cells, thus suggesting expansion of these cell populations when immunity to a tumor exists. Homing of labeled normal cells in tumor cell-injected normal animals was somewhat different from that seen in tumor cell-inoculated mice that were immunized against the tumor. In the latter case, accumulations of lymph node and spleen cells in recipient lymph nodes and bone marrow were consistently lower. In contrast, lymphoid cells from animals immunized against the tumor were found to accumulate in virtually the same percentages in lymphoid organs of normal and immune recipients. The behavior of lymphoid cell populations from thymus or bone marrow that consist mainly of precursor cells was unaffected by presence of malignancy and/or tumor immunity.     

Restoration of allograft responsiveness in B rats: IV. The divergent migratory behavior of lymphocyte populations mediating cardiac allograft rejection

The T lymphocyte-deprived (B) rat, produced by X-radiation and bone marrow reconstitution of adolescent thymectomized animals, exhibits a true immunological deficit and are unable to reject histoincompatible heterotopic cardiac allografts. A comprehensive survey of lymphocyte traffic in B recipients was performed to correlate the differential potency of specifically sensitized lymphocyte populations mediating re-establishment of immune responsiveness toward the graft, with their migratory and recirculatory behavior. ¹¹¹In-oxine-labeled thoracic duct lymphocytes (TDL) were retained in the peripheral blood and migrated from nonlymphoid organs to lymph nodes of B recipients in higher proportion than any other lymphoid population, particularly splenic lymphocytes (SL). Although all cell groups but TDL were sequestered in the spleen in equal and relatively large numbers, no differences were found between the lymphocyte populations tested in their capacity to accumulate in the grafts. In contrast, an increased avidity in the allograft of ¹²⁵IUdR-labeled TDL and lymph node (LNL) lymphoblasts, as compared to ¹²⁵IUdR-labeled SL, resembles closely the results of functional studies of the differential potency of adoptively transferred cells. We assume that specific cellular interactions induced by the accumulated ¹²⁵IUdR-labeled cells invoke nonspecific mechanisms for the recruitment of other uncommitted ¹¹¹Inlabeled lymphocytes which recirculate between blood and lymph and localize indiscriminately in the allograft amplifying its rejection. The latter lymphocytes can be “armed” by adherent cells residing in the lymphoid organs of graft recipients, particularly spleen, and subsequently increase the penetration of the foreign tissue. When radiolabeled lymphocytes were traced in B recipients experiencing rejection of their allografts following transfer of sensitized cells plus lymphokine, their migration patterns as well as blastogenic response in B hosts were similar to those observed during acute rejection of cardiac allografts in unmodified hosts. Thus the similarities between the rejection network brought by alloimmune cells into otherwise unresponsive animals and immunocompetent animals able to reject their grafts are stressed.     

B-cell suppression of antibody response to sheep red blood cells in mice of high- and low-responding genotypes.

CBA and C57B1 mice (high and low responders to sheep red blood cells, respectively) were injected intravenously with syngeneic lymph node, marrow, spleen, or thymus cells together with sheep red blood cells (SRBC), and the production of antibody-forming cells (AFC) was assayed in the spleen. Transfer of lymph node, marrow, spleen, or thymus cells led to a significant enhancement of immune responsiveness in low-responding C57B1 mice. In contrast, transfer of marrow, lymph node, or spleen cells to high-responding CBA mice was accompanied by a decline in AFC production. These effects were magnified if syngeneic cell donors had been primed with SRBC; suppression in CBA mice and stimulation in C57B1 mice were especially pronounced after transfer of SRBC-primed lymphoid cells. Pretreatment of CBA donors with cyclophosphamide in a dose causing selective B-cell depletion completely abrogated the suppression of immune responsiveness. A large dose (10⁷) of syngeneic B cells injected together with SRBC suppressed the accumulation of AFC in both CBA and C57B1 mice. No suppression of immune responsiveness was observed after transfer of intact thymus cells, hydrocortisone-resistant thymocytes, or activated T cells. We conclude that suppression of the immune response to SRBC is induced by B cells. At the same time, there is a possibility that the addition of “excess” B cells acts as a signal, triggering suppressor T cells.     

Synergy among rat T cells in the proliferative response to alloantigen.

A synergistic interaction in the proliferative response to alloantigen is described for mixtures of rat thymus and lymph node cells. The optimal conditions for synergy are quantitatively defined. Regression analysis of the slope of the dose-response curve has been utilized to estimate the degree of interaction in thymus-lymph node cell mixtures. The slope of the response of cell mixtures was noted to be significantly greater than the slope for the response of lymph node cells alone. Irradiation was shown to have a differential effect on the response of thymus and lymph node cells in mixtures. Irradiated thymus cells retained the capacity for synergy in mixtures, whereas irradiated lymph node cells did not. Additional studies have demonstrated that both de novo protein synthesis and specific antigen recognition by both responding cell populations in mixtures was required for maximal synergy. These studies demonstrate that synergy cannot be explained as an artifact of altered cell density in vitro. They establish that thymus cells and lymph node cells represent distinct subsets which manifest qualitatively different functions in the proliferative response to alloantigen. Thymus cells can respond directly to alloantigen by proliferation but also have the capacity to amplify the proliferative response of lymph node cells—a capacity which is resistant to X irradiation but requires recognition of alloantigen and de novo protein synthesis. Lymph node cells may similarly respond by proliferation to alloantigen but lack the amplifier activity of thymus cells. Synergy for rat lymphoid cells, like mouse lymphoid cells, has been shown to involve an interaction of thymus-derived lymphocytes.     

Strongyloides ratti: Transfer of immunity in rats by lymph node cells or serum

Immune mesenteric lymph node cells (IMLNC) and hyperimmune serum, alone or in combination, were transferred to recipient, syngeneic Lewis rats. On the day of cell transfer, the recipients, along with appropriate controls, were infected with 1,000Strongyloides ratti larvae. Twelve days later, the number of adult worms in the anterior small intestine was counted and the number ofS. ratti eggs in the terminal uterus of representative female worms was determined. Using these methods, we showed that worm fecundity was reduced in the IMLNC recipients, the hyperimmune serum recipients, and the recipients of both cells and serum as compared with regular controls (averages of 2.45, 2.93, and 2.98 eggs, respectively, vs. 4.73 eggs). The number of adult worms recovered from the IMLNC recipients was not reduced (474.6 worms). However, significantly fewer worms were recovered from the recipients of IMLNC-hyperimmune serum and the recipients of hyperimmune serum only as compared with regular controls (184.8 and 171.5 worms, respectively, vs. 567.2 worms). A working hypothesis, involving an interaction of serum and cellular components, is postulated as the mechanism for this protective response.     

Localization of PNA-binding and nonbinding thymus cells in peripheral lymphoid organs

Thymus cells were labeled in vitro with FITC and injected into syngeneic recipients. In cell suspensions of lymphoid organs green cells were inspected for PNA receptors with double immunofluorescence. A striking preference of PNA-negative cells to localize in lymph nodes and the lymphoid compartment of the spleen was demonstrated. Incubation with anti-Ly sera revealed that Ly 1⁺ PNA-negative cells homed in popliteal lymph nodes and Peyer's patch but not in mesenteric lymph nodes.     

Lymphocyte traffic through granulomas: Differences in the recovery of indium-111-labeled lymphocytes in afferent and efferent lymph

Afferent lymphatics draining granulomas and efferent lymphatics from normal and stimulated lymph nodes were cannulated in sheep. There was a greatly increased output of cells in afferent lymph-draining chronic inflammatory sites or Freund's adjuvant-induced granulomas. Cells collected from these lymphatics were radiolabeled with ¹¹¹In and injected intravenously. The reappearance of these labeled cells in lymph at various sites was measured. Labeled afferent lymph cells migrated from blood through the granuloma back into afferent lymph in large numbers and with kinetics which were comparable to efferent lymphocytes recirculating through a lymph node. When labeled afferent lymph cells were injected the specific activity (cpm/10⁷ cells) in afferent lymph was five times higher than that in efferent lymph from a normal node. When efferent lymph cells were labeled the afferent lymph specific activity was one-half that in efferent lymph. It is suggested that the cells in afferent lymph migrate preferentially from blood through the granuloma and constitute a unique population of cells.