Prophylactic immunization against experimental leishmaniasis. III. Protection against fatal Leishmania tropica infection induced by irradiated promastigotes involves Lyt-1+2- T cells that do not mediate cutaneous DTH

Protective immunity against fatal L. tropica infection in genetically vulnerable BALB/c mice can be induced by prophylactic immunization with irradiated promastigotes even when heat-killed. Such immunity is adoptively transferable transiently into intact or durably into sub-lethally irradiated (200 or 550 rad) syngeneic recipients by splenic T but not B cells. The effector T cells are of the Lyt-1+2- phenotype, devoid of demonstrable cytotoxic activity. The immune splenic T cell population expresses specific helper activity for antibody synthesis. A causal role for helper T cells in this capacity, however, seems unlikely, because it was shown in the accompanying paper that antibody does not determine the protective immunity against L. tropica. The immunized donors show no detectable cutaneous DTH or its early memory recall in response to live or killed promastigotes or a soluble L. tropica antigen preparation. Spleen, lymph node, and peritoneal exudate cells from protectively immunized donors similarly fail to transfer DTH locally or systemically. These cells also lack demonstrable suppressive activity against the expression or induction of DTH to L. tropica. Thus, protection against L. tropica induced by prophylactic i.v. immunization with irradiated promastigotes appears to be conferred by Lyt-1+2- T cells that are distinguishable from T cells mediating either both DTH and T help, or cytotoxicity.     

Prophylactic immunization against experimental leishmaniasis. VI. Comparison of protective and disease-promoting T cells

In previous studies, we reported that mice immunized i.v. with lethally irradiated Leishmania major promastigotes developed substantial resistance to a subsequent L. major infection. However, such protection could be totally suppressed by prior s.c. injection with the same antigens. Both the protective immunity and the inhibition of its induction could be adoptively transferred with specific Lyt-2- T cells. Here, we present evidence showing that protection and disease promotion resulting from i.v. or s.c. immunization, respectively, are mediated by functionally distinct subsets of T cells. In a series of titration experiments, it was found that freshly isolated T cells derived from prophylactically i.v. immunized BALB/c mice were either protective (greater than 10(7) cells/recipient) or ineffective (less than 10(7) cells/recipient). No exacerbation of disease was observed at any dose. Conversely, T cells from mice immunized s.c. either accelerated disease development and inhibited protective immunization (greater than 10(7) cells/recipient) or had no effect (less than 10(7) cells/recipient). No protection was observed at any dose tested. In mixed transfer experiments, increasing numbers of T cells from s.c. immunized donors progressively inhibited the protective effect of T cells from i.v. immunized donors. Supernatant of T cell cultures from protectively immunized donors contained substantial macrophage-activating factor whereas such activity was not detectable in the supernatant of T cell culture from s.c. immunized donors. Analysis by flow cytometry showed that the spleen and lymph nodes of normal, i.v., or s.c. immunized BALB/c mice contained similar ratios of L3T4+ cells and Lyt-2+ cells.     

Prophylactic immunization against experimental leishmaniasis. IV. Subcutaneous immunization prevents the induction of protective immunity against fatal Leishmania major infection

Durable immunity against fatal L. major infection in genetically susceptible mice can be induced by immunization with 150,000-rad irradiated or heat-killed promastigotes administered i.v. or to a lesser extent i.p. Conversely, subcutaneous (s.c.) and intramuscular (i.m.) injections are not only totally ineffective but generally increase susceptibility to and enhance the progression of the disease, leading to earlier mortality. This detrimental effect is particularly evident with lower infecting challenge doses. Disease exacerbation is apparent in mice given 4 X s.c. injections of as few as 2 X 10(4) irradiated promastigotes, but it appears most potent after doses of 2 X 10(7). When mice given 4 X s.c. injections were subsequently immunized i.v. with 2 X 10(7) irradiated promastigotes, they failed to develop any evidence of protection against infection with 2 X 10(5) promastigotes, whereas mice given i.v. immunization alone were strongly protected. Thus, s.c. injections are capable of blocking the prophylactic effect of i.v. immunization with irradiated parasites. This inhibitory effect can be achieved with a single s.c. injection, although rather less potently than with four, and is even effective against four repeated weekly i.v. immunizations. Once induced, the effect persists undiminished after 100 days. A weaker effect is also inducible by s.c. injection given after i.v. immunization. The blocking effect of s.c. injection is not dependent on continuing viability of the promastigotes, as it can be induced equally readily with heat-killed, formalin-fixed, or sonicated parasites. The phenomenon extends to mouse strains genetically resistant as well as susceptible to L. major infection and, in congenic mice of BALB background, is independent of the major histocompatibility (H-2) gene complex.     

Prophylactic immunization against experimental leishmaniasis. II. Further characterization of the protective immunity against fatal Leishmania tropica infection induced by irradiated promastigotes

The genetic vulnerability of BALB/c mice to Leishmania tropica (L. major) infection renders them incapable of controlling a primary cutaneous lesion that leads to uniformly fatal visceral disease. Potent, long-lasting protection involving both lesion healing and survival can be induced by repeated prophylactic i.v. immunization with gamma-irradiated (150K rad) L. tropica promastigotes. The effect is not dependent on continuing viability or cellular invasiveness of the irradiated parasites because their effective immunogenicity withstands heating at 56 degrees C for 1 hr. Immunity is not stage specific and encompasses both amastigote and promastigote challenges. Similar prophylaxis can be induced by immunization with heterologous irradiated L. donovani promastigotes. Repeated i.v. immunization with irradiated L. tropica promastigotes induces an antibody response in the isotype sequence M leads to G1/G3 leads to G2a/G2b leads to A with substantially higher titres than are found in response to the infection itself. Splenectomy before immunization drastically reduces this antibody response without incurring any impairment of the extent of protection. Passive transfer of large amounts (up to 10 ml) of hyperimmune serum (or isotype fractions thereof) throughout the first 8 wk of infection fails to arrest disease progression during this period. Despite the previously described lack of any detectable cutaneous DTH reactivity, which has hitherto correlated with protective cell-mediated immunity, the results obtained do not support attribution of an alternative causal role to the humoral response.     

Distinctive cellular immunity in genetically susceptible BALB/c mice recovered from Leishmania major infection or after subcutaneous immunization with killed parasites

Genetically susceptible BALB/c mice are refractory to further infection after recovery from Leishmania major infection after a sublethal dose of gamma-irradiation. In contrast, mice immunized with killed promastigotes s.c. develop exacerbated lesions after infection. Both groups of mice produce only a low level of specific antibody and no detectable cytotoxic T cells, but do have a strong antigen-specific DTH, which is adoptively transferable with Lyt-1+2-, L3T4+ T cells. Kinetic and histological studies revealed that mice immunized s.c. developed Jones-Mote hypersensitivity, peaking at 15 hr. with little mononuclear cell infiltration at the site of antigen administration; whereas mice that had recovered from infection developed tuberculin-type of reactivity, peaking at 24 to 48 hr, with intense mononuclear cell infiltration. Splenic T cells from recovered mice, when injected into the footpads of normal recipients together with live promastigotes, were able to retard lesion development; whereas T cells from s.c. immunized mice, when similarly transferred, accelerated disease progression. Antigen-specific culture supernatant of spleen cells from recovered mice also activated normal resident peritoneal macrophages to kill intracellular L. major amastigotes and tumor cells. Culture supernatants of spleen cells from s.c. immunized or normal mice were devoid of such activities. Part of the macrophage-activating potential can be inhibited by antibody specific for IFN-gamma. These results therefore demonstrate that whereas the Jones-Mote reaction is correlated with disease exacerbation, the tuberculin-type of DTH may be protective. Furthermore, in vivo immunity is directly related to the capacity of T cells to produce macrophage-activating factor.     

Vaccination against murine cutaneous leishmaniasis by using Leishmania major antigen/liposomes. Optimization and assessment of the requirement for intravenous immunization

Efficacy of vaccination against cutaneous leishmaniasis in highly susceptible BALB/c mice was assessed comparatively by using radiation-attenuated promastigotes and colloidal Ag mixtures generated from a mixed Leishmania major (LV39) isolate (SLV39) and from a virulent cloned line (SVJ2) derived from the Jericho 2 L. major isolate. Dehydration-rehydration vesicle (DRV) liposomes were used as adjuvants. In optimization experiments phospholipid composition of DRV was varied, and the distearoyl derivative (DSPC) (liquid-crystalline phase transition temperature (Tc) 54 degrees C) of egg lecithin L-alpha-phosphatidylcholine was found to be superior to the dipalmitoyl derivative (DPPC, Tc 41.5 degrees C) and underivatized L-alpha-phosphatidylcholine (Tc -10 degrees C). The criteria studied were in vivo priming for a secondary in vitro proliferative response and the prepatency of lesion onset after L. major challenge of mice immunized once i.v. A single s.c. immunization with SLV39 either free or entrapped within DSPC liposomes primed spleen cells to produce significant levels of IL-3 when stimulated with SLV39 in vitro. In contrast, the i.v. route of immunization with the same Ag preparations led to little or no IL-3 production by the spleen cells. Despite development of significant T cell activation, both SLV39 and SVJ2 administered s.c., either free or entrapped within liposomes, were not protective. However, i.v. immunization four times with SVJ2 entrapped within DSPC liposomes induced a level of resistance comparable with that of 2 x 10(7) gamma-irradiated promastigotes in the stringent BALB/c L. major model. Although significant, protection conferred after i.v. immunization with SLV39/DSPC liposomes was less effective. These data therefore show that DSPC/DRV liposomes, although a good adjuvant for inducing protective immunity to cutaneous leishmaniasis, are not able to overcome the requirement for an i.v. route of immunization with the leishmanial Ag preparation. Additionally, they demonstrate a correlation between IL-3 secretion and non-protection. They also suggest that SVJ2 represents a better source of protective Ag than SLV39.     

Influence of 2'-deoxyguanosine upon the development of DTH effector T cells and suppressor T cells in vivo

Subcutaneous (s.c.) immunization of mice with allogeneic spleen cells can induce delayed-type hypersensitivity (DTH) to both major and minor histocompatibility antigens. Intravenous immunization with allogeneic spleen cells, however, induces a poor state of DTH. Furthermore, i.v. immunization with allogeneic spleen cells, especially if they have been irradiated, induces suppressor T lymphocytes. These suppressor T cells are capable of suppressing the host-vs-graft (HvG) DTH reactivity that normally arises after s.c. immunization. Moreover, they can suppress the development of anti-host DTH effector T cells during graft-vs-host (GvH) reactions. These models for HvG and GvH DTH reactivity were used to study the influence of 2'-deoxyguanosine (dGuo) and guanosine (Guo) on the generation of DTH-reactive T cells and suppressor T cells in vivo. It was found that daily i.p. administration of 0.01 mg dGuo to mice immunized i.v. partially prevented the generation of suppressor T cell activity, whereas daily administration of 0.1 or 1 mg dGuo resulted in a complete abolition. Administration of dGuo has no effect on the anti-host DTH reactivity by spleen cells from nonsuppressed donors except for when a daily dose of 10 mg is administered. This dose proved to be toxic for precursors of DTH effector T cells. Daily i.p. injection of Guo had no effect on the generation of suppressor T cells nor on the generation of DTH effector T cells. The effect of dGuo was found to be due to a direct effect on suppressor T cells and not to the induction of contrasuppressor cells. These data suggest a differential sensitivity of DTH-reactive T cells and suppressor T cells for dGuo. Because suppressor T cells and DTH-reactive T cells require proliferation for expressing maximal functional activity in the systems used, both cell types probably have different enzyme activities involved in the purine metabolism and similar deoxycytidine kinase activities, but have different nucleotidase (5'NT) activities, those in suppressor T cells being the lowest. If so, suppressor T cells will accumulate deoxyguanosine triphosphate, which causes an inhibition of the ribonucleotide reductase activity and thus of the DNA synthesis by these cells.     

Protective immunity against the protozoan Leishmania chagasi is induced by subclinical cutaneous infection with virulent but not avirulent organisms

Protective immunity against Leishmania major is provided by s.c. immunization with a low dose of L. major promastigotes or with dihydrofolate-thymidylate synthase gene locus (DHFR-TS) gene knockout L. major organisms. Whether these vaccine strategies will protect against infection with other Leishmania species that elicit distinct immune responses and clinical syndromes is not known. Therefore, we investigated protective immunity to Leishmania chagasi, a cause of visceral leishmaniasis. In contrast to L. major, a high dose s.c. inoculum of L. chagasi promastigotes was required to elicit protective immunity. Splenocytes from mice immunized with a high dose produced significantly greater amounts of IFN-gamma and lower TGF-beta than mice immunized with a low dose of promastigotes. The development of protective immunity did not require the presence of NK cells. Protection was not afforded by s.c. immunization with either attenuated L. chagasi or with L. major promastigotes, and s.c. L. chagasi did not protect against infection with L. major. Subcutaneous immunization with DHFR-TS gene knockouts derived from L. chagasi, L. donovani, or L. major did not protect against L. chagasi infection. We conclude that s.c. inoculation of high doses of live L. chagasi causes a subclinical infection that elicits protective immune responses in susceptible mice. However, L. chagasi that have been attenuated either by long-term passage or during the raising of recombinant gene knockout organisms do not elicit protective immunity, either because they fail to establish a subclinical infection or because they no longer express critical antigenic epitopes.     

Cell-mediated responses and protection elicited by a carbohydrate-lipid-containing fraction extracted from Leishmania major promastigotes

Carbohydrate-lipid-containing fractions (CLF) extracted from Leishmania major promastigotes and recognized by sera from immune but not from normal human donors were evaluated for their capacity to elicit cell-mediated responses. It was found that one of these fractions, CLF-1, stimulated the in vitro response of lymphocytes from immune but not from normal human donors. A similarly extracted fraction from L. donovani parasites also elicited an in vitro response by cells from donors immune to L. major. The response was mediated by antigen-presenting cells, and specific Leu 3+ Leu 2- T cells from a human T-cell line responded to the antigen. In vivo, the CLF-1 elicited delayed-type hypersensitivity (DTH) response in L. major-immunized C3H mice, which was comparable to the DTH response elicited by freeze-thawed and sonicated L. major promastigotes. C3H mice were vaccinated with CLF-1 prior to challenge with live L. major promastigotes. Mice vaccinated with CLF-1-containing liposomes showed a significant degree of protection to challenge. These results suggest that the carbohydrate-lipid-containing fraction described here may represent a functional antigenic entity from Leishmania parasites.     

Immunologic regulation of experimental cutaneous leishmaniasis. V. Characterization of effector and specific suppressor T cells

Resistant CBA mice infected with Leishmania tropica promastigotes develop concomitant and convalescent immunity against reinfection. This can be adoptively transferred by splenic and lymph node T cells with a threshold dosage of 1 to 2.5 x 10(7). The effector cells are of Thy-1+, Lyt-1+2- phenotype. The same immune cell population also adoptively transfers specific DTH to L. tropica, which is restricted by the major histocompatibility complex. On the other hand, highly susceptible BALB/c mice infected with L. tropica develop antigen-specific suppressor T (Ts) cells (previously shown to inhibit the induction and expression of DTH), which are capable, on transference, of reversing the healing of lesions induced by prior sublethal irradiation of BALB/c mice. As few as 10(6) of these T cells are effective in abrogating the potent prophylactic effect of 550 rad. The Ts cells are of Thy-1+, Lyt-1+2-, and I-J- phenotype. Sublethally irradiated and infected BALB/c mice produce antibody responses quantitatively and isotypically similar during the critical first 40 days after infection whether or not they are injected with 10(7) Ts cells (nonhealing vs healing). Thus, impairment of DTH and curative immune responses in BALB/c mice cannot be attributed to a helper function of these Thy-1+, Lyt-1+2- cells for the formation of suppressive antibody.     

Generation of suppressor T cells after local immunization with histocompatibility antigens

Subcutaneous (sc) hind-foot immunization (HFI) of mice with allogeneic spleen cells can induce a state of delayed-type hypersensitivity (DTH) as well as a state of suppression of DTH. This paper deals with the suppression induced by HFI. The state of suppression could be adoptively transferred by spleen cells and lymph node cells between Days 3 and 7 after HFI only. However, in the hind-foot-immunized mice the state of suppression lasted at least 25 days. The suppressor cells expressed the Thy-1+, Lyt-1-2+ phenotype and suppressed DTH antigen-specifically. The suppressor cells, however, also suppressed DTH responses to unrelated third-party alloantigens, provided the latter were administered during the induction of DTH together with the same alloantigens that were used for HFI. The HFI-induced T-suppressor cells suppressed the induction phase of DTH (i.e., the proliferative activity of the draining lymph node cells after secondary sc immunization), but not the expression phase of DTH (i.e., the activity of previously activated DTH effector T cells). H-2D compatibility between the donors of the HFI-induced T-suppressor cells and the recipients was required for the adoptive transfer of suppression. The differences in effect of local immunization versus systemic immunization on the induction and functional activity of T-suppressor cells are discussed.     

Vaccination against cutaneous leishmaniasis in a murine model. I. Induction of protective immunity with a soluble extract of promastigotes

BALB/c mice can be protected against a fatal Leishmania major infection by immunization with whole radio-attenuated promastigotes; however, neither the antigens responsible for protection nor the protective immunologic mechanisms have been defined. In this study, the ability of promastigote fractions to elicit similar immunity to that obtained with whole organisms, and the immune responses associated with such protection were analyzed. Intraperitoneal immunization with a soluble, membrane-free parasite extract was found to induce protection against L. major challenge equal to that obtained with whole organisms. Induction of immunity (89% protection in seven experiments) was most effective with 100 micrograms of the soluble leishmanial antigen (SLA) and required concomitant injection of the bacterial adjuvant, Corynebacterium parvum (CP), followed by an i.p. boost of SLA alone 1 wk later. Vaccinated animals exhibited Leishmania-specific cell-mediated immunity, as assessed both by lymphocyte transformation and the production of macrophage-activating factors (MAF). In addition, although SLA + CP-immunized mice failed to exhibit delayed-type hypersensitivity (DTH) before challenge, splenic lymphocytes from these mice could transfer a local DTH reaction to naive recipients. Immunization also induced the production of antibodies against two major metabolically labeled proteins of m.w. 30,000 and 53,000, but failed to stimulate a detectable humoral response against promastigote surface antigens. Thus, these experiments demonstrate that vaccine-induced immunity against cutaneous leishmaniasis is strongly associated with the induction of cell-mediated immunity, but does not require the development of an antibody response to promastigote surface antigens. In addition, these studies establish the feasibility of employing soluble, nonmembrane-derived parasite material as a source of protective immunogens.     

Distinct IL-3 activation profile induced by intravenous versus subcutaneous routes of immunization

Lymphoid cells from mice immunized i.v. or s.c. with Leishmania major antigens were analyzed for their capacity to produce lymphokines when stimulated with specific antigens in vitro. Spleen cells from BALB/c mice immunized by the s.c. route produced significantly higher levels of IL-3 and IL-3 mRNA than those from mice immunized by the i.v. route. The differential production of IL-3 was maintained at a wide range of antigen concentrations tested in vitro and for different culturing times. T cell enrichment procedures and treatment with CD4+ mAb in vitro confirmed the T cell nature of the IL-3 producer population. However, the IL-3 production in the two populations of spleen cells was equally high after Con A stimulation in vitro. The IL-2 production by the two populations of cells was also not significantly different after antigen or mitogen stimulation in vitro. To our knowledge, this is the first report of a differential synthesis of IL-3 mRNA and secretion of IL-3 induced by different routes of immunization followed by specific-antigen stimulation in vitro. These findings may also explain earlier observations that i.v. immunization with leishmanial antigen induces protection, whereas s.c. immunization leads to exacerbation of L. major infection, since IL-3 has been previously shown to promote leishmanial infection. The fact that the phenomenon also extends to other antigen systems suggests that this finding may have a broader implication in immune regulation and vaccine development.     

Mechanisms of acquired immunity in leishmaniasis

Self-curing cutaneous leishmaniasis depends on T cell-mediated immune activation of infected macrophages. Failure of immune control in inbred mouse models of metastasizing mucocutaneous and visceralizing forms of the disease involves, respectively, insusceptibility of the parasite and the generation of T cells that suppress a potentially curative response. Prophylactic immunization in man has so far been restricted to cutaneous leishmaniasis and based on inducing infection under controlled conditions with virulent Leishmania tropica major promastigotes. The feasibility of immunization against visceral leishmaniasis merits reconsideration. BALB/c mice are genetically vulnerable to L. tropica major, which produces a fatal visceralizing type of disease involving specific suppression of cell-mediated immunity. Potent and lasting protection can be induced by repeated intravenous immunization with irradiated promastigotes. The efficacy of this 'vaccine' is relatively heat-stable (1 h at 56 degrees C). Immunity is not attributable to antibody but to the generation of Lyt-1+2- T cells which, although possessing helper and macrophage-activating functions, do not express classical delayed-type hypersensitivity. The immunological features of this system and its relevance to the possibility of protection against human Leishmania donovani infection are considered.     

Delayed-type hypersensitivity (DTH) in BCG-sensitized mice I. Lack of suppressor T cell activity on DTH to sheep red blood cells.

Mice pretreated with an intravenous (i.v.) injection of BCG (BCG-sensitized mice) and then immunized intravenously with a high dose (10(8)--10(9)) of sheep red blood cells (SRBC) 2 weeks later developed strong delayed-type hypersensitivity (DTH) to SRBC, as in mice pretreated with cyclophosphamide (CY) (CY-treated mice) and then immunized with SRBC 2 days later; normal mice given the same dose of SRBC did not show such DTH. The mechanism of this strong DTH to SRBC which developed in BCG-sensitized mice was studied, by comparing it with that in CY-treated mice. The transfer of either whole spleen cells or thymus cells, but not serum, obtained from mice immunized with i.v. injections of 10(9) SRBC 4 days previously (hyperimmune mice) did not suppress either the induction or the expression of DTH to SRBC in BCG-sensitized mice, but suppressed those in CY-treated mice. The suppressor cells were SRBC-specific T cells. Adoptive transfer of DTH to SRBC by spleen cells from either BCG-sensitized mice of CY-treated mice to hyperimmune recipients failed. The adoptive transfer of DTH from BCG-sensitized mice to normal recipients also failed if the spleen cells from hyperimmune mice were cotransferred. Whole body irradiation (600 rad) of mice 2 hr before or after the time of immunization with SRBC reduced significantly DTH to SRBC in both BCG-sensitized and CY-treated mice. It was noticed that the total number of spleen cells in BCG-sensitized mice was 3--4 times larger than that in CY-treated mice. From these results, we conclude that the entity of effector T cells of DTH to SRBC induced in BCG-sensitized mice and in CY-treated mice was not different in terms of susceptibility to suppressor T cells and irradiation, but that the total numbers of effector T cells generated in these mice differed remarkably, resulting in the above-described different responsiveness to suppressor T cells transferred passively.     

BCG expressing LCR1 of Leishmania chagasi induces protective immunity in susceptible mice

Cellular immune responses are required for protective immunity against Leishmania chagasi. Immunization strategies using live intracellular bacteria (e.g., bacille-Calmette Guerin strain of Mycobacterium bovis) expressing recombinant antigens can induce cellular immune responses to these antigens. Previous studies demonstrated that the L. chagasi antigen LCR1 stimulates IFN-gamma production from T cells of infected BALB/c mice, and immunization with recombinant LCR1 partially protects against L. chagasi infection. To determine whether live bacteria could enhance the immunization potential of LCR1, we engineered BCG expressing LCR1 (BCG-LCR1). Subcutaneous immunization with BCG-LCR1, but not with BCG containing plasmid only (BCG-pMV261), elicited better protective immunity against L. chagasi infection than LCR1 protein alone. BCG-LCR1 administered intraperitoneally did not protect. Splenocytes from mice immunized s.c. with either BCG-LCR1 or BCG-pMV261 and then infected with L. chagasi promastigotes had increased antigen-induced IFN-gamma and reduced IL-10 production compared to splenocytes of control mice. We propose that BCG-LCR1 promotes a Th1-type protective immune response, and it may be a useful component of a Leishmania vaccine.     

Do sugar residues contribute to the antigenic determinants responsible for protection and/or abolition of protection in Leishmania-infected BALB/c mice?

Intravenous inoculation of irradiated virulent promastigotes of Leishmania mexicana, or intradermal inoculation of avirulent temperature-sensitive clones of the same parasite, can protect BALB/c mice from progressive disease when challenged with parental organisms. However, if animals are prechallenged s.c. with irradiated parental parasites before (or shortly after, i.e., within 10 days) any other immunization regime is used, the s.c. challenge effectively suppresses development of protective immunity. The role of N-linked sugars on promastigotes in providing the determinants responsible for protection and/or suppression of protection in these assays has been examined. Growth of parasite in 2 micrograms/ml tunicamycin has no effect on incorporation of [3H]leucine but decreases incorporation of [3H]mannose by some 40 to 50%. Such tunicamycin-treated avirulent clones or irradiated virulent organisms are now unable to induce a protective response. However, tunicamycin-treated parental parasites given s.c. could still suppress the protection seen when irradiated parasites were given i.v. as immunogen. Tunicamycin-treated avirulent organisms given s.c. subcutaneously unlike the untreated avirulent clones, now also caused suppression of protection. These data suggest that the determinants responsible for development of protective immunity to L. mexicana in BALB/c mice are dependent on N-linked glycoproteins for their expression, unlike the determinants responsible for suppression of that protection. By using swainsonine as an alternative inhibitor of N-linked glycoprotein synthesis, the data additionally suggest that no complex processing of N-linked sugars takes place to reveal the immunogenic determinants in this system.     

Tumor bearer T cells suppress Bacillus Calmette-Guérin-potentiated antitumor responses. III. Identification of an auxiliary efferent suppressor-T-cell population

T cells (Ts-eff) induced in BALB/c mice by subcutaneous (sc) growth of syngeneic Meth A tumors can adoptively suppress the effector phase of delayed-type hypersensitivity (DTH) in Bacillus Calmette-Guérin (BCG)-primed and unprimed recipients which have been sensitized with irradiated Meth A cells but they do not inhibit the augmented DTH response in recipients inoculated with cyclophosphamide (CY) 2 days prior to sensitization. By reconstituting CY-treated immunized recipients with selected spleen cell populations, it has been demonstrated that Ts-eff suppress DTH by interacting with a second or auxiliary suppressor cell population present in immune but not normal spleens. These auxiliary suppressor cells (Ts-aux) are Thy+, Lyt 1-2+ and I-J+, phenotypically similar to Ts-eff. Their activity is not influenced by B-cell depletion. Unlike Ts-eff, Ts-aux do not bear receptors specific for Meth A cells. Ts-aux and Ts-eff share similar sensitivity to irradiation and high dose (100 mg/kg) CY but unlike Ts-eff, Ts-aux are cortisone sensitive, nondividing, nonadherent cells which are absent from the thymus. The phenotype and mechanism of action of Ts-aux resemble those of the auxiliary or Ts3 cells defined in models of contact sensitivity, DTH to simple haptens, and in vitro antibody responses.     

A role for Lyt-2+ T cells in resistance to cutaneous leishmaniasis in immunized mice

The role of Lyt-2+ T cells in immunologic resistance to cutaneous leishmaniasis was analyzed by comparing infection patterns in resistant C57BL/6 mice and susceptible BALB/c mice induced to heal their infections after sub-lethal irradiation or i.v. immunization, with similar mice treated in vivo with anti-Lyt-2 antibodies. Administration of anti-Lyt-2 mAb resulted in a dramatic reduction in the number of lymphoid cells expressing the Lyt-2+ phenotype. Such treatment led to enhanced disease in both resistant C57BL/6 and irradiated BALB/c mice, as assessed by lesion size, but did not affect the capacity of these mice to ultimately resolve their infections. In contrast, anti-Lyt-2 treatment totally blocked the induction of resistance in i.v. immunized mice. These results suggest, that Lyt-2+ T cells may play a role in immunity to a Leishmania major infection and that their relative importance to resistance may depend on how resistance is induced.     

Suppression of antigraft immunity by preimmunization. III. Characterization of suppressor T cells involved in suppression of the efferent phase of DTH against alloantigens

Suppressor T (Ts) cells that can suppress delayed type hypersensitivity (DTH) against histocompatibility (H) antigens can be isolated from spleen and lymph nodes a few days after i.v. immunization of mice with irradiated allogeneic spleen cells. In this paper we investigated the suppression of the efferent phase of DTH to characterize the Ts cells involved, and to compare them with the afferent phase Ts cells that have been characterized in a previous paper of this series. The DTH against third party alloantigens that were not used for the i.v. suppressive immunization could be suppressed by presenting the third party alloantigens together with the original alloantigens in the challenge inoculum for eliciting the DTH reaction. Thus the ultimate suppressive effect by the Ts cells that are active during the efferent phase of DTH is nonspecific. This non-specific suppression of DTH to alloantigens has previously been found for the afferent phase Ts cells as well. For suppression of the efferent phase of DTH to alloantigens, a population of Lyt-1+2+ Ts cells appeared to be essential, just like in the suppression of the afferent phase of DTH to alloantigens. We did not find evidence for the involvement of cyclophosphamide-sensitive auxiliary Ts cells in suppression of the efferent phase of DTH. Also no evidence was found for H-2 or Igh-restricted activation and function of the Ts cells that were active during afferent and efferent phases of the DTH response to H antigens. In view of these similarities between afferent phase and efferent phase Ts cells we conclude that there are no arguments as yet to suppose that there is more than one type of T cells involved in the suppression of the afferent and efferent limb of DTH against H antigens.