Production of immunity and unresponsiveness in the mouse by feeding contact sensitizing agents and the role of suppressor cells in the peyer's patches, mesenteric lymph nodes and other lymphoid tissues.

Mice were fed the contact sensitizing agents “oxazolone” or picryl chloride by tube. A single feed gave rise to contact sensitivity. However, the contact sensitivity and antibody production which occurred in mice painted with oxazolone were almost abolished when the mice were fed oxazolone 14 days before the skin painting. Feeding also reduced the DNA synthesis response in the regional lymph nodes. Two types of suppressor cells were found in mice after feeding. After a single feed of picryl chloride the Peyer's patches and mesenteric lymph nodes contained suppressor cells which suppressed the passive transfer of contact sensitivity. After three feeds of either agent spleen cells also caused inhibition. These suppressor cells were presumptive B cells as shown by their ability to form rosettes with red cells coated with antibody and complement and their resistance to anti-θ serum and complement. However, separated T cells from the same spleen transferred contact sensitivity. In addition to these B suppressor cells the spleens and peripheral lymph node cells of mice fed with contact sensitizing agent and then painted on the skin contained T cells which limited DNA synthesis in lymph nodes. This was shown by injecting their cells into normal recipients which were then painted with contact sensitizing agent and measuring DNA synthesis 4 days later in the regional lymph nodes. It was concluded that suppressor B and T cells were an important part of the mechanism of unresponsiveness caused by feeding contact sensitizing agents.     

Immunoregulation of experimental allergic encephalomyelitis: conditions for induction of suppressor cells and analysis of mechanism.

We determined requirements for the induction of immunoregulatory suppressor cells in experimental allergic encephalomyelitis (EAE) in Lewis rats. Pretreatment of rats with myelin basic protein (BP) in incomplete Freund's adjuvant (IFA) stimulates the proliferation of suppressor cells that localize in lymph nodes and spleen (but not thymus) and exert control over the development of clinical EAE. Dosage studies revealed that 3 X 10(7) suppressor cells can adoptively transfer suppression to syngeneic recipients. Transferred unresponsiveness wanes within 3 weeks, indicating that the suppressor cells are short-lived lymphocytes, although actively induced unresponsiveness persists for at least 8 weeks, probably as a result of continual proliferation under the influence of antigen. No evidence was obtained to suggest that antigen carry-over or blocking antibody production accounts for adoptive transfer of unresponsiveness. Suppressor cells apparently act at the inductive phase of the immune response since they had no inhibitory effect on adoptive transfer of disease by effector lymph node cells. Other mechanisms also may play a role in unresponsiveness to EAE, since rats pretreated i.v. with high dosages of soluble BP were temporarily rendered unresponsive, although suppressor cells could not be detected in these animals.     

Immunopotentiating effects of amphotericin B. II. Enhanced in vitro proliferative responses of murine lymphocytes.

Enhanced in vitro proliferative responses to DNBSO3 were seen in lymph node cells and spleen cells after in vivo sensitization of mice with DNFB plus AmB compared with mice primed with DNFB alone. The T cell proliferation in the nylon column nonadherent fraction for both groups was highly similar, and the enhanced lymph node cell proliferation with AmB was demonstrated to be in the nylon adherent population consisting of both T and B cells. These and earlier studies of immunopotentiation by AmB are consistent with a mechanism that depends on selective interaction of the polyene with a subset of T cells and a resultant impairment of the normally induced suppressor regulation that limits the magnitude and duration of immune responses.     

Enterically induced immunologic tolerance. I. Induction of suppressor T lymphoyctes by intragastric administration of soluble proteins.

Specific immune unresponsiveness was induced in inbred mice (BDF1) by the administration of soluble ovalbumin (OVA) by gastric intubation. Anti-hapten (DNP) responses likewise were specifically diminished when animals were fed autologous carrier (OVA or keyhole limpet hemocyanin). Adoptive transfer of spleen cells demonstrated that the tolerant state could be maintained in irradiated recipient mice, and specific anergy could be transferred to normal recipient animals. Adoptive suppression was mediated by T lymphocytes, as demonstrated by nylon wool fractionation and susceptibility of the cells to anti-Thy 1.2 and complement. Transferred B cells had neither suppressive nor augmentative effects. Enteric administration of OVA also specifically diminished antigen-induced DNA synthesis of primed lymph node T cells, although suppressor cells were not identified in the lymph nodes per se.     

The B cell is the initiating antigen-presenting cell in peripheral lymph nodes

We have examined the role of B cells in antigen presentation in lymph nodes in several ways. We found that mice depleted of B lymphocytes via chronic injection of anti-mu-chain antibody do not mount peripheral lymph node T cell proliferative responses to normally immunogenic doses of antigen. Depletion of B cells by passage of immune lymph node cells over anti-immunoglobulin columns early after immunization depletes antigen-presenting function from draining lymph nodes, and this function can be restored by using B cells or splenic adherent cells to allow the remaining T cells to proliferate. Lymph node B cells present antigen very effectively to lines of antigen-specific T cells. However, unfractionated lymph node cells from anti-mu-treated mice present very poorly, if at all, whereas unfractionated spleen cells from the same mice do present antigen. This is in keeping with our previous finding that helper T cell function in the spleen is normal in B cell-deprived mice. Finally, when mice homozygous for the lymphoproliferative gene lpr are treated chronically with anti-mu-chain antibody, lymphadenopathy is greatly retarded, suggesting a role for B cells in the massive proliferation of T cells in this syndrome. From this analysis, it would appear that the initiating antigen-presenting cell in the lymph node is a B lymphocyte, and that B lymphocytes in lymph nodes may be distinct from those in the spleen. It is of interest that these results also suggest that the lymph node lacks an antigen-presenting cell that is found in the spleen, perhaps the dendritic cell.     

The absence of lymphoid suppressor cells in tumor-involved lymph nodes of patients with head and neck cancer

Patients with head and neck cancer often have decreased local or regional immunocompetence. Lymphocytes obtained from tumor-involved or -uninvolved lymph nodes (LNL) of these patients showed low or undetectable levels of antitumor cytotoxicity and low proliferative responses in vitro to interleukin 2 (IL2) or mitogens in comparison to peripheral blood lymphocytes (PBL). Lymphokine-activated killer (LAK) cell activity of LNL was lower (P less than 0.05) than that of autologous PBL. Fresh LNL were neither enriched in cells with the CD8+ CD11b+ "suppressor" phenotype nor did they suppress proliferative or cytotoxic responses of autologous PBL in mixing experiments. LNL did not inhibit LAK cell generation from autologous PBL in the presence of IL2. Also, no evidence for the inhibition of autotumor-restricted responses by IL2-activated LNL was obtained. Spontaneous or in vitro-induced production of IL1 beta. TNF alpha, and IFN-tau was low or undetectable in LNL from tumor-involved and -uninvolved lymph nodes in comparison to that in normal or autologous PBL. Mitogen-induced IL2 production was normal in LNL. The depressed ability to produce certain cytokines may be in part responsible for a state of unresponsiveness present in lymph nodes obtained from patients with head and neck cancer. No evidence for the presence of lymphoid suppressor cell in LNL of these patients was obtained.     

Experimental manipulations of afferent immune responses influence efferent immune responses to brain tumors

Tumors grow more readily in the brain than in the periphery, in part due to immune privilege. Differences in both afferent and efferent components of the immune response contribute to this lower level of responsiveness. On the afferent side, despite the lack of lymphatic vessels in the brain, antigens from brain arrive in lymph nodes and spleen by several routes, and the route taken may influence the type of response generated. Work with viruses and soluble antigens in mice has shown that the intracerebral location and the volume of the inoculation influence the strength of the cytotoxic T cell response. We examined whether these factors influence the T cell response against experimental brain tumors in mice. Placement of tumor cells in the cerebral ventricles instead of the parenchyma generated an immune response sufficient to increase survival time. A large volume of an intraparenchymal infusion of tumor cells caused spread of cells to the ventricles, and resulted in longer survival time relative to a small volume infusion. Infusion of the same dose of radiolabeled tumor cells in either a small volume or a large volume allowed tracking of potential tumor antigens to the periphery. Both modes of infusion resulted in similar levels of radioactivity in blood, spleen and kidney. Unexpectedly, cells infused intraparenchymally in a small volume, compared to a large volume, resulted in (1) more radioactivity in cervical lymph nodes (parotid and deep cervical lymph nodes), (2) a greater number of CD11b+/Gr1+ myeloid suppressor cells in the tumors, and (3) fewer CD8+ cells within the tumor mass. Consistent with these observations, providing a stronger afferent stimulus by giving a concurrent subcutaneous injection of the same tumor cells infused into the brain increased CD8+ T cell infiltration of the tumor in the brain. These results suggest that the immune response elicited by antigens that drain predominantly to the cervical lymph nodes may be less effective than responses elicited at other lymph nodes, perhaps due to immunosuppressive cells. Directing therapies to the optimal peripheral sites may improve immune responses against brain tumors.     

Antigen-specific inhibition of immune interferon production by suppressor cells of autoimmune encephalomyelitis

Previous work from this laboratory has revealed that spleen and/or lymph node cells from Lewis rats, that have recovered from an acute episode of experimental autoimmune encephalomyelitis (EAE), suppress the development of EAE when injected into syngeneic recipients subsequently challenged with myelin basic protein (MBP) in CFA. In an effort to understand the mechanism of this suppression, we measured the production of immune IFN-gamma, which may be required for the induction of an immune response, by EAE effector T cells (which transfer disease) and EAE suppressor cells when cultured in vitro with MBP. We now report that EAE effector T cells produce IFN-gamma when cultured in vitro with MBP. In contrast, spleen cells from recovered rats (which manifest suppressor activity in vivo) do not produce IFN-gamma. Moreover, in cell mixing experiments, these suppressor spleen cells inhibited the production of IFN-gamma by EAE effector cells. This inhibition was not eliminated by the removal of macrophages nor by the inhibition of PG synthesis by indomethacin. Furthermore, the inhibition was shown to be Ag-specific and mediated by nylon-adherent, radiation-sensitive splenic T cells. The findings suggest that suppressor cells regulate EAE by inhibiting IFN-gamma production by effector cells. This inhibition may result in the down-regulation of IFN-gamma-induced expression of class II major histocompatibility Ag on cells of the central nervous system, thus reducing the presentation of tissue-specific Ag (i.e., MBP) to autoreactive lymphocytes.     

Antigen-specific clones of proliferating T lymphocytes. I. Methodology, specificity, and MHC restriction

In this report we describe in detail a new method for cloning antigen-specific, proliferating T lymphocytes directly from primed murine lymph nodes after 3 days of activation in vitro. After expansion in liquid culture the cells from the colonies were shown to be antigen specific and to require I-A histocompatible, irradiated spleen cells for stimulation. For hapten-carrier-type antigens, the T cells were shown to be carrier specific in their recognition but they were also capable of distinguishing the presence of the hapten. Recloning of small numbers of these cells in soft agar under conditions of high plating efficiency yielded true clones (i.e., populations derived from a single cell) whose antigen specificity was identical to that of cells from the original colony. The fact that a clone of T cells was I-A restricted in its antigen recognition demonstrates that suppressor T cell function cannot account for the phenomenon of major histocompatibility complex restriction.     

Contact sensitivity to picryl chloride: the occurrence of B suppressor cells in the lymph nodes and spleen of immunized mice.

Mice were immunized for contact sensitivity and antibody production by painting the skin with picryl chloride. Lymph node and spleen cells taken 4 days later transferred contact sensitivity. However, cells taken at 7–8 days failed to transfer but were able to block the transfer by 4 day immune cells. These suppressor cells occurred in the regional lymph nodes, spleen and thymus. The suppressor activity of lymph node and spleen cells was due to B cells as shown by the effect of anti-θ serum and complement, nylon wool filtration and separation of EAC positive and negative cells by centrifugation on a discontinuous gradient. The transfer of fractions rich or poor in macrophages showed that the suppressor cell in the transferred population was not a macrophage. Separation using EAC rosettes suggested that B cells were responsible for the suppressor activity in the thymus.T cells isolated from the lymph nodes and spleen 7–8 days after immunization transferred contact sensitivity although the initial population was inactive. This indicates that passive transfer cells are present in the regional lymph nodes and spleen at later times after immunization but cannot be demonstrated because of the presence of suppressor B cells. However, no passive transfer cells were found in the thymus. The production of B suppressor cells required little or no T cell help and following immunization the spleens of reconstituted (B) mice were at least as active as control cells in causing suppression. There are several different suppressor cells which act in the picryl system and the B suppressor cells in immunized mice described here are distinct from the T suppressor cells in mice injected with picryl sulphonic acid.     

Lymphocyte function in experimental African trypanosomiasis. III. Loss of lymph node cell responsiveness

The relationship between immunosuppression and suppressor cell activity in the lymphoid organs of animals with experimental African trypanosomiasis has been examined further. In the present study we measure the primary in vitro PFC response to SRBC by spleen and lymph node cells from Trypanosoma rhodesiense infected or drug-cured C57BL/6 mice. Passive transfer experiments with this culture system tested for the presence or absence of suppressor cells. We demonstrate that infected mice exhibit immunosuppression in the spleen cell population several weeks before becoming suppressed at the level of the lymph node cell populations. Although suppressor cells are present in immunosuppressed spleen cell populations, suppression of lymph node cell responsiveness was not attributable to suppressor cells detectable withi, lymph nodes. After Berenil treatment of terminally infected mice immunocompetence was restored gradually, first to the lymph node cells and subsequently to the spleen cell population. Recovery of spleen cell responsiveness was attributable to the loss of detectable suppressor cell activity within spleens. These results demonstrate that there is anatomical restriction of the suppressor cell population to trypanosome-infected mouse spleen and that loss of immunocompetence in the lymph nodes may be due to factors unrelated to suppressor cell effects.     

Interaction of the lymph node and splenic lymphocytes of mice in inactivation of allogeneic hematopoietic stem cells

A study was made of interaction of mouse spleen and lymph node lymphocytes in inactivation of allogeneic stem cells. It was established that T lymphocytes of the lymph nodes and spleen lymphocytes do not interact on combined administration; their action is of additive nature. B lymphocytes of the lymph nodes have a regulating activity both in respect to T lymphocytes of the lymph nodes and lymphocytes of the spleen. The stem cells serve as target. Depending on the stem cells/B lymphocytes ratio B lymphocytes are capable of exerting either helper or suppressor action.     

Peripheral tolerance induced in lymph nodes by syngeneic spleen cells inhibits generation of CTLs to hapten-altered self antigens but not to alloantigens.

The immunological tolerance that is induced in lymph nodes that have been exposed to syngeneic spleen cells has been examined. Development of cytotoxic T lymphocytes was used to assess the immunological status of the lymph node cells. The tolerance was studied from the viewpoint of its induction, its activation, and its specificity. We had already reported that injecting either T or B cells of splenic origin into a regional lymph node environment a week prior to immunization for CTL to hapten-altered self antigens prevents development of the CTL. Here, we confirm that syngeneic splenic cells but not lymph node cells will induce the suppression provided that spleen cells are not coupled with hapten. We now report that splenic cells that cannot replicate or synthesize and secrete protein are capable of inducing the suppression. The data suggest a preformed surface marker peculiar to spleen cells and perhaps on cells that traverse the thymus induces local tolerance that is mediated by suppressor cells. Triggering the induced suppressor T cells (previously identified as CD8-) was achieved by syngeneic spleen cells as well as by H-2-compatible, Mls-disparate spleen cells but not by syngeneic lymph node cells or apparently by allogeneic spleen cells. Furthermore, triggering suppression was achieved by hapten-coupled syngeneic spleen cells whereas such cells would not induce the suppression. Thus, activating the suppressor cells requires reexposure to splenic cells of the proper MHC haplotype, unaltered or coupled with either TNP or FITC. Once triggered, the suppression was manifested toward CTL generation against hapten-coupled syngeneic antigens on either spleen or lymph node cells but not against allogeneic antigens. Thus, the specificity of the tolerance was directed to altered self antigens despite its induction by unaltered spleen antigen. Furthermore, for suppression to be seen the spleen antigen was not required to be on the hapten-coupled syngeneic cells used for the CTL immunization. The relationship of the splenic cell "antigen" to hapten-altered self antigens and to other surface markers and its site of acquisition within the body and its significance for cell homing have become intriguing questions of importance. This information has been discussed from the viewpoint of its applicability to autoimmune diseases as well as to cessation of inflammatory reactions that may be mediated by lymph node cells.     

Immunophenotypic and cell cycle analysis of lymph node cells from dimethylbenzanthracene-treated mice

The chemical carcinogen 7, 12-dimethylbenz-(a)anthracene (DMBA) depletes Langerhans cells from murine epidermis. Application of contact sensitizers to DMBA-treated skin induces specific immunological tolerance due to a DMBA-resistant epidermal antigen presenting cell (APC) migrating to local lymph nodes where it presents antigen in a way which activates suppressor cells. As alterations in local lymph node lymphocytes may enhance the ability of the DMBA-resistant APC to activate suppressor cells, these cells were examined in DMBA-treated mice. Lymph nodes in DMBA-treated mice had normal morphology but were larger and contained increased numbers of lymphocytes. Cell cycle analysis revealed that these lymphocytes did not arise from division within the lymph node, suggesting alterations in homing properties of lymphocytes. Contact sensitizer applied to DMBA-treated skin did not increase lymphocyte division, possibly due to suppressor cell inhibition of the development of effector lymphocytes. DMBA treatment had no effect on B cells or Ia expression, but decreased levels of the T lymphocyte cell surface molecule Thy-1, and increased L3T4 and Lyt-2 as quantitated by flow cytofluorimetry. These changes could influence the development of immune responses as these T cell molecules are receptors involved in lymphocyte interactions.     

Immunophenotypic and cell cycle analysis of lymph node cells from dimethylbenzanthracene-treated mice

The chemical carcinogen 7, 12-dimethylbenz(a)anthracene (DMBA) depletes Langerhans cells from murine epidermis. Application of contact sensitizers to DMBA-treated skin induces specific immunological tolerance due to a DMBA-resistant epidermal antigen presenting cell (APC) migrating to local lymph nodes where it presents antigen in a way which activates suppressor cells. As alterations in local lymph node lymphocytes may enhance the ability of the DMBA-resistant APC to activate suppressor cells, these cells were examined in DMBA-treated mice. Lymph nodes in DMBA-treated mice had normal morphology but were larger and contained increased numbers of lymphocytes. Cell cycle analysis revealed that these lymphocytes did not arise from division within the lymph node, suggesting alterations in homing properties of lymphocytes. Contact sensitizer applied to DMBA-treated skin did not increase lymphocyte division, possibly due to suppressor cell inhibition of the development of effector lymphocytes. DMBA treatment had no effect on B cells or Ia expression, but decreased levels of the T lymphocyte cell surface molecule Thy-1, and increased L3T4 and Lyt-2 as quantitated by flow cytofluorimetry. These changes could influence the development of immune responses as these T cell molecules are receptors involved in lymphocyte interactions.     

The inhibitory effect of histamine on lymphoid tissue proliferation in mice

Histamine, injected subcutaneously (10 mg/kg), inhibited the DNA synthesis response to a contact-sensitizing agent (picryl chloride) and also had an inhibitory effect on DNA synthesis in untreated mice. The synthesis was measured by 5-[125I]iodo-2'-deoxyuridine incorporation in spleen, lung, liver, and peripheral lymph nodes and the inhibitory effect was marked and consistent in spleen in both sensitized and nonsensitized animals, but was variable in the other tissues. Since histamine is believed to activate suppressor cells, it is suggested that the inhibition of DNA synthesis in picryl chloride-treated mice is due to the activation of those suppressor cells which limit the specific DNA synthesis in response to the contact-sensitizing agent. The inhibition of DNA synthesis in untreated mice could be due to the activation of suppressor cells that control the ongoing immune response to environmental antigens.     

Activation requirements of cloned inducer T cells. I. Differential inhibition by anti-L3T4 or anti-I-A is determined by the accessory cell population

We have described a trinitrophenyl (TNP)-specific inducer clone, clone Ly-1-T1, which responds to a variety of different stimuli, including a) soluble TNP-protein conjugates plus syngeneic (H-2d) spleen cells, b) TNP directly coupled to syngeneic or allogeneic spleen cells, and c) activated I-A identical B cells in the absence of nominal antigen. In the present study we used a panel of antibodies to investigate the recognition structures involved in the activation of clone Ly-1-T1 by these different stimuli. We show that allogeneic spleen cells must be conjugated by using relatively high concentrations of TNBS to be efficient stimulators of the clone. In contrast, syngeneic spleen cells conjugated by using a much wider range of concentrations will activate the clone. The response of the clone to TNP-coupled allogeneic spleen cells is inhibited by anti-L3T4 and anti-Ia antibodies. In contrast, stimulation of the clone with syngeneic spleen cells coupled by using the same concentrations of TNBS is not inhibited with either anti-Ia or anti-L3T4 antibody. The inhibition pattern observed with anti-Ia and anti-L3T4 antibodies was also determined by the nature of the accessory population used to present soluble TNP-protein conjugates. Anti-I-Ad antibodies blocked the activation of clone Ly-1-T1 by TNP-protein plus splenic adherent cells, indicating the involvement of polymorphic I-A determinants in this response. Anti-L3T4 antibody had little or no effect on this response, suggesting that a significant L3T4-Ia interaction is not required. Finally, the response of the clone to activated B cells in the presence or absence of TNP-protein is exquisitely sensitive to inhibition by anti-L3T4 as well as anti-I-A antibodies. The data suggest that the requirement for an L3T4-I interaction depends on the combination of antigen and accessory cell type used to stimulate the clone.     

Antigen-specific suppressor T cell interactions. I. Induction of an MHC-restricted suppressor factor specific for L-glutamic acid50-L-tyrosine50

The synthetic polymers L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT) and L-glutamic acid50-L-tyrosine50 (GT) stimulate specific suppressor T cells in certain strains of mice. Extracts from these T cells contain factors (TsF) that inhibit GAT- or GT-specific antibody responses by normal spleen cells or proliferative responses by primed T cells. We constructed T cell hybridomas that constitutively produce GAT-TsF or GT-TsF, which functionally and serologically are identical to factors extracted from suppressor T cells. In this report we demonstrate that monoclonal GT-TsF can induce specific unresponsiveness in vivo or in vitro and that this unresponsiveness is due to development of second-order antigen-specific suppressor T cells. T cell hybridomas were constructed by fusion of BW5147 with GT-TsF1 induced second-order suppressor T cells and clones that produced suppressor factor (GT-TsF2) were isolated and characterized. GT-TsF2 differs from the GT-TsF1 used to induce it in that GT-TsF1 acts across allogeneic barriers whereas GT-TsF2 does not. This restriction is controlled by genes in the H-2 gene complex and maps to the I-J subregion. GT-TsF2 is antigen-specific in suppressive activity and also in its antigen-binding site(s). Thus, GT-TsF2 closely resembles the carrier-specific, I-J+, genetically restricted factor described by Tada and his colleagues. Because GT-TsF2 was induced by GT-TsF1, we suggest cells producing GT-TsF1 are an early cell in the pathway of suppression, and that this cell is required for the activation of antigen-specific, MHC-restricted TsF.     

Regulation of cellular immune response against autologous human melanoma. II. Mechanism of induction and specificity of suppression

The cytotoxic immune response in the peripheral blood lymphocytes (PBL) against an autologous malignant melanoma cell line, PJ-M, was found to be down-regulated in in vitro co-culture (IVC) selectively by unfractionated resident lymph node lymphocytes (derived from a lymph node infiltrated with the PJ-M melanoma cells) and T4+ as well as T8+ fractions of the resident lymph node-derived lymphocytes. In this study, the mechanism involved in, and the specificities of, cytotoxic immune response in this autologous system were examined at population and clonal levels. Resident lymph node lymphocytes were isolated from both involved and uninvolved lymph nodes from the same patient. Resident lymphocytes from both sources regulated the generation of cytotoxic immune response when both types of resident lymph node lymphocytes were further sensitized against the PJ-M cells in IVC and were expanded in interleukin 2 (IL 2). An IL 2-dependent homogeneous lymphocyte line (I-10:1) bearing the phenotype of a helper T cell (T4+) and a T4+ clone (I-10.3) of the I-10:1 line, established by limiting dilution culture, also down-regulated the generation of cytotoxic immune effector cells in the PBL in IVC against the PJ-M targets. The IL 2-dependent T4+ inducer line I-10:1 generated a functionally differentiated T8+ suppressor population(s) that, in turn, could abrogate cytotoxic response in fresh PBL in IVC against PJ-M cells. The inducer line I-10:1 and its subclone I-10.3 suppressed the generation of cytotoxic effector cells in the PBL in IVC selectively against the autologous PJ-M cells. Generation of cytotoxic allo-response in IVC was unaffected by the inducer lines. These results provide further evidence for the involvement of the regulatory network in cytotoxic immune response in an autologous human tumor system, and suggest a potential explanation for cytotoxic unresponsiveness against autologous melanoma cells.     

Distribution of primed T cells and antigen-loaded antigen presenting cells following intranasal immunization in mice

Priming of T cells is a key event in vaccination, since it bears a decisive influence on the type and magnitude of the immune response. T-cell priming after mucosal immunization via the nasal route was studied by investigating the distribution of antigen-loaded antigen presenting cells (APCs) and primed antigen-specific T cells. Nasal immunization studies were conducted using the model protein antigen ovalbumin (OVA) plus CpG oligodeoxynucleotide adjuvant. Trafficking of antigen-specific primed T cells was analyzed in vivo after adoptive transfer of OVA-specific transgenic T cells in the presence or absence of fingolimod, a drug that causes lymphocytes sequestration within lymph nodes. Antigen-loaded APCs were observed in mediastinal lymph nodes, draining the respiratory tract, but not in distal lymph nodes. Antigen-specific proliferating T cells were first observed within draining lymph nodes, and later in distal iliac and mesenteric lymph nodes and in the spleen. The presence at distal sites was due to migration of locally primed T cells as shown by fingolimod treatment that caused a drastic reduction of proliferated T cells in non-draining lymph nodes and an accumulation of extensively divided T cells within draining lymph nodes. Homing of nasally primed T cells in distal iliac lymph nodes was CD62L-dependent, while entry into mesenteric lymph nodes depended on both CD62L and α4β7, as shown by in vivo antibody-mediated inhibition of T-cell trafficking. These data, elucidating the trafficking of antigen-specific primed T cells to non-draining peripheral and mucosa-associated lymph nodes following nasal immunization, provide relevant insights for the design of vaccination strategies based on mucosal priming.