CTLA-4 down-regulates the protective anticryptococcal cell-mediated immune response

Cell-mediated immune (CMI) responses defined by delayed-type hypersensitivity (DTH) reactivity to cryptococcal culture filtrate antigen (CneF) can be either protective or nonprotective against an infection with Cryptococcus neoformans. The protective and nonprotective anticryptococcal DTH responses are induced by different immunogens and have differing activated-T-cell profiles. This study examined the effects of blockade of the interaction between cytotoxic T lymphocyte antigen 4 (CTLA-4) and its ligands B7-1 (CD80) and B7-2 (CD86) on the anticryptococcal DTH responses and protection. We found that CTLA-4 blockade at the time of immunization with the immunogen that induces the protective response, CneF, in complete Freund's adjuvant (CFA) or the immunogen that induces the nonprotective response, heat-killed cryptococcal cells (HKC), enhanced anticryptococcal DTH reactivity. In contrast, blocking CTLA-4 after the immune response was induced failed to enhance responses. Blockade of CTLA-4 in an infection model resulted in earlier development of the anticryptococcal CMI response than in control mice. Concomitant with increases in DTH reactivity in mice treated with anti-CTLA-4 Fab fragments at the time of immunization, there were decreases in cryptococcal CFU in lungs, spleens, and brains compared to controls. Blockade of CTLA-4 resulted in long-term protection, as measured by significantly increased survival times, only in mice given the protective immunogen, CneF-CFA. Anti-CTLA-4 treatment did not shift the response induced by the nonprotective immunogen, HKC, to a long-term protective one. Our data indicate that blockade of CTLA-4 interactions with its ligands may be useful in enhancing host defenses against C. neoformans.     

Induction of antigen-specific suppression by circulating Cryptococcus neoformans antigen.

Immunoaffinity chromatography of sera from mice infected with Cryptococcus neoformans (Inf-MS) on a column with rabbit anti-cryptococcal antibody as the ligand resulted in the adsorption of the component(s) that induce suppression of the cryptococcal delayed-type hypersensitivity (DTH) response. In contrast, immunoaffinity chromatography of Inf-MS on columns coupled with cryptococcal antigen or goat anti-mouse IgM, IgG, and IgA did not adsorb the suppressive component(s). Quantification of cryptococcal antigen and anti-cryptococcal antibody in Inf-MS and column fractions established a direct correlation between cryptococcal antigen levels and suppressive activity; no correlation was observed between anti-cryptococcal antibody levels and suppressive activity. The suppression induced by Inf-MS was shown to be specific in that suppressive sera did not affect the induction of DTH responses to Listeria monocytogenes or dinitrofluorobenzene. These collective results provide evidence that cryptococcal antigen is the component in Inf-MS that induces antigen-specific suppression of the cell-mediated immune response to C. neoformans.     

Characterization of cellular infiltrates and cytokine production during the expression phase of the anticryptococcal delayed-type hypersensitivity response.

Cryptococcosis, an increasingly important opportunistic infection caused by the encapsulated yeast-like organism Cryptococcus neoformans, is limited by an anticryptococcal cell-mediated immune (CMI) response. Gaining a thorough understanding of the complex anticryptococcal CMI response is essential for developing means of controlling infections with C. neoformans. The murine cryptococcosis model utilizing footpad swelling to cryptococcal antigen (delayed-type hypersensitivity [DTH]) has proven to be a valuable tool for studying the induction and regulation of the anticryptococcal CMI response, but this technique has limitations with regard to evaluating the role of the final effector cells recruited by an ongoing CMI response. The purpose of this study was to assess the types of cells and cytokines induced into the site of cryptococcal antigen deposition in C. neoformans-infected and -immunized mice compared with those for control mice. We used a gelatin sponge implant model to examine the cells and cytokines present at the site of an anticryptococcal DTH response. Sponges implanted in infected mice and injected with cryptococcal culture filtrate antigen (CneF) 24 h before assessment had significantly increased numbers of infiltrating leukocytes compared with saline-injected sponges in the same animals. Exaggerated influxes of neutrophils and mononuclear cells were the major contributors to the increase in total numbers of cells in the DTH-reactive sponges. The numbers of CD4+ and LFA-1+ cells were found to be significantly increased in the CneF-injected sponges of infected and immunized mice over the numbers in control sponges. The numbers of large granular lymphocytes were also increased in DTH-reactive sponges compared with control sponges. Gamma interferon, interleukin 2 (IL-2), and IL-5 are clearly relevant cytokines in the anticryptococcal CMI response, since they were produced in greater amounts in the CneF-injected sponges from C. neoformans-infected and -immunized mice than in control sponges. IL-4 was not associated with the expression of DTH to cryptococcal antigen. The gelatin sponge model is an excellent tool for studying cells and cytokines involved in specific CMI responses.     

Effects of immunization with Cryptococcus neoformans cells or cryptococcal culture filtrate antigen on direct anticryptococcal activities of murine T lymphocytes.

Immunizing CBA/J mice with intact Cryptococcus neoformans cells or with a cryptococcal culture filtrate antigen (CneF) induces an anticryptococcal delayed-type hypersensitivity response. Recently, it has been shown that two phenotypically different T-cell populations are responsible for delayed-type hypersensitivity reactivity in mice immunized with intact cryptococcal cells, whereas only one of those populations is present in mice immunized with soluble cryptococcal antigens in complete Freund's adjuvant (CFA). The purpose of this study was to determine if differences occur with regard to direct anticryptococcal activity between T-lymphocyte-enriched populations from mice immunized with intact viable or dead cryptococcal cells and similar cell populations from mice immunized with the soluble cryptococcal culture filtrate antigen, CneF, emulsified in CFA. The percentage of lymphocytes which form conjugates with C. neoformans and the percentage of cryptococcal growth inhibition in vitro are greater with T-lymphocyte-enriched populations from mice sublethally infected with C. neoformans or from mice immunized with intact heat-killed cryptococcal cells in the presence or absence of CFA than with lymphocyte populations from mice immunized with CneF-CFA. Enhanced anticryptococcal activity of T lymphocytes could be induced by immunizing mice with heat-killed C. neoformans cells of serotype A, B, C, or D as well as by immunizing with a similar preparation of an acapsular C. neoformans mutant but not by immunizing with CFA emulsified with CneF prepared from any one of the C. neoformans isolates. These data indicate that the soluble cryptococcal culture filtrate antigens do not induce the same array of functional T lymphocytes as whole cryptococcal cells.     

Characterization of a cell population which amplifies the anticryptococcal delayed-type hypersensitivity response.

Cell-mediated immunity to Cryptococcus neoformans can be detected by delayed-type hypersensitivity (DTH) to a culture filtrate antigen of C. neoformans. Recently, we have identified a population of cells in spleens of mice immunized with cryptococcal antigen that, when transferred to recipient mice at the time of immunization, amplifies the anticryptococcal DTH response. If the cell donor mice are treated with cyclosporin A during induction of the anticryptococcal DTH response, the amplifier cells are not induced, whereas the cells which transfer DTH (TDH cells) are induced. The purpose of this study was to characterize the amplifier cells with respect to their surface and functional properties and, in so doing, determine whether or not the amplifier cells are analogous to long-lived memory cells. We demonstrated that the amplifier cells were nylon-wool-nonadherent, antigen-specific, CD4 (L3T4+ Lyt-2-) T lymphocytes which appear in the spleens of mice 5 days postimmunization with cryptococcal culture filtrate antigen in complete Freund adjuvant. The amplifier T (Tamp) cells are not considered to be memory cells because they are relatively short-lived, being present 14 but not 18 days after the stimulating immunization. Moreover, the amplified anticryptococcal DTH response does not fulfill the criteria of the typical secondary immune (anamnestic) response in that the amplified response does not appear early relative to the appearance of the primary anticryptococcal DTH response, and it does not persist longer than the primary DTH response. We speculate that Tamp cells are not long-lived memory cells but rather act in a T-helper cell capacity to amplify the anticryptococcal DTH response.     

Suppression of the delayed-type hypersensitivity and cell-mediated immune responses to Listeria monocytogenes induced by Pseudomonas aeruginosa.

Pseudomonas aeruginosa-mediated suppression of the immune response to Listeria monocytogenes was investigated in mice. Because delayed-type hypersensitivity (DTH) footpad swelling to L. monocytogenes was suppressed equally in lipopolysaccharide-responsive and -hyporesponsive mouse strains, the lipopolysaccharide component of P. aeruginosa could not have been the suppressive agent. Mucoid P. aeruginosa cells were no more suppressive than their nonmucoid revertants; therefore, mucoid coating was not an additional immunosuppressive element. Interleukin-1 and macrophage inhibitory factor production to L. monocytogenes and clearance of L. monocytogenes from mouse spleens were all decreased by prior Pseudomonas infection, indicating that cell-mediated immunity, as well as DTH, was decreased to a sublethal Listeria dose. The timing of Pseudomonas exposure relative to Listeria sensitization was varied. P. aeruginosa injected 24 or 6 h before or at the same time as L. monocytogenes depressed DTH to Listeria challenge 7 days later. Animals treated in this way could not respond to reinfection with L. monocytogenes at 13 days. P. aeruginosa administered to L. monocytogenes-sensitized mice at the time of footpad challenge was suppressive, but these mice responded normally upon reinfection. It appears that P. aeruginosa induced two types of suppression to L. monocytogenes: a transient suppression, affecting DTH challenge but not resensitization, and a longer lasting suppression that did not permit mice exposed to P. aeruginosa at the time of Listeria sensitization to respond to subsequent Listeria exposure.     

Immunoadsorption of Cryptococcus-specific suppressor T-cell factors.

In the murine cryptococcal suppressor cell circuit, two different T-cell suppressor factors, TsF1 and TsF2, have been identified which specifically suppress the delayed-type hypersensitivity (DTH) response to cryptococcal culture filtrate antigen (CneF). TsF1 is produced by a first-order T suppressor (Ts1) cell population and suppresses the afferent limb of the DTH response, whereas TsF2 is produced by a second-order T suppressor (Ts2) cell population and suppresses the efferent limb of the cryptococcal DTH response. The objective of this study was to ascertain whether TsF1 or TsF2 could bind to cryptococcal antigen. To assess this, adsorption of TsF1 and TsF2 was performed with heat-killed Cryptococcus neoformans cells and by solid-phase immunoadsorption (SPIA) on columns containing cryptococcal antigens, i.e., CneF covalently bound to Sepharose 4B. The suppressive effect of TsF1 was removed by adsorption with intact heat-killed cryptococci and by SPIA on CneF-Sepharose 4B. The binding of cryptococcal TsF1 to the cryptococcal SPIA column was shown to be specific since Sepharose 4B columns either coupled with Saccharomyces cerevisiae mannan or blocked with glycine did not adsorb the suppressor activity. In contrast, the suppressive component of TsF2 did not bind to heat-killed cryptococci, CneF-Sepharose 4B, S. cerevisiae mannan-Sepharose 4B, or glycine-Sepharose 4B columns. These results, together with the finding that cryptococcal antigen, anticryptococcal antibody, and C1q-binding immune complexes were not demonstrated in either TsF1 or TsF2, establish that TsF1 and TsF2 can be differentiated on the basis of their affinity for cryptococcal antigen.     

Cytokine profiles associated with induction of the anticryptococcal cell-mediated immune response.

Previous studies with a murine model have shown that immunization with cryptococcal culture filtrate antigen (CneF) emulsified in complete Freund adjuvant (CFA) induces two populations of anticryptococcal reactive CD4+ T cells. One population (TDH cells) transfers anticryptococcal delayed-type hypersensitivity (DTH), and the other population (Tamp cells) amplifies the anticryptococcal DTH response of given to recipient mice at the time of immunization of the recipient. Treatment of mice with cyclosporin A (CsA) ablates the induction of Tamp cells but not TDH cells. The present study focused on assessing the cytokines produced by spleen cells taken from CsA-treated and control (solvent-treated) mice at days 1, 2, 4, and 6 after immunization. Supernatants from the spleen cells cultured in vitro for 24 or 48 h in medium alone or with CneF, concanavalin A, or phorbol 12-myristate 13-acetate plus calcium ionophore were assessed for the presence of interleukin-2 (IL-2), gamma interferon (IFN-gamma), IL-4, IL-5, and tumor necrosis factor. Spleen cells from CneF-CFA-treated mice produced IL-2 and IFN-gamma, but not IL-4 or IL-5, constitutively and in response to CneF, indicating that CneF-CFA induces a Th1 response. Tumor necrosis factor was not produced. Anticryptococcal TDH cells developed in spleens in which there were low levels of IFN-gamma and IL-2 (CsA-treated, immunized mice), whereas anticryptococcal Tamp cells along with TDH cells matured in spleens in which production of IFN-gamma and IL-2 was high (solvent-treated, immunized mice). The data also suggest that IL-2 and IFN-gamma produced by Tamp cells early after adoptive transfer are influential in the development of the amplified anticryptococcal DTH response that has been observed in Tamp cell-recipient mice.     

Serological, electrophoretic, and biological properties of Cryptococcus neoformans antigens.

We compared a cryptococcal culture filtrate antigen referred to as CneF with chemically defined cryptococcal antigen fractions isolated by Cherniak and co-workers by using double immunodiffusion gels, polyacrylamide gel electrophoresis, immunoblots, and footpad reactivity of immunized mice. The three previously described components of cryptococcal culture filtrates are a high-molecular-weight glucuronoxylo-mannan (GXM), which is the major constituent, a galactoxylomannan (GaIXM), and a mannoprotein (MP). In this study we demonstrated that CneF contained components which were serologically and electrophoretically similar to the three previously described cryptococcal culture filtrate fractions. The MP fraction elicited significantly stronger delayed-type hypersensitivity responses than did the GXM or GaIXM fraction when used in mice immunized either with the CneF in complete Freund adjuvant or whole heat-killed Cryptococcus neoformans yeast cells. These findings were confirmed when the footpads of immunized mice were challenged with GaIXM and MP preparations from a culture filtrate of a C. neoformans acapsular mutant that does not produce GXM. Thus, we concluded that the MP was the primary component recognized by the anticryptococcal cell-mediated immune response in mice.     

Characterization of a third-order suppressor T cell (Ts3) induced by cryptococcal antigen(s).

Previous studies from our laboratory have shown that a high dose of cryptococcal culture filtrate antigen (CneF) administered intravenously induces a complex suppressor cell cascade which down-regulates the cell-mediated immune response to Cryptococcus neoformans antigens. The primary objective of this investigation was to determine whether a suppressor cell induced by immunization is required for efferent suppression of the cryptococcal delayed-type hypersensitivity (DTH) response. Our approach to this problem was to immunize CBA/J mice with CneF emulsified in complete Freund adjuvant and then 6 days later to collect spleen cells from the immunized mice and adoptively transfer these cells along with C. neoformans-specific second-order suppressor T cells (Ts2) to naive syngeneic recipients at the time of footpad challenge of the recipients with CneF. To establish which populations of cells in the spleens of immunized mice play a suppressive role, mass cytolysis with specific antibodies and complement was performed before the spleen cells were transferred to naive animals. Since the phenotype of the cells responsible for the transfer of the cryptococcal DTH response had not been completely determined, we first demonstrated that the cells responsible for DTH were L3T4+ Lyt-2- cells. Subsequently, we established that a Thy-1+ L3T4- Lyt-2+ I-J+ cell population induced by immunization was required along with C. neoformans-specific Ts2 cells for efferent suppression of the cryptococcal DTH response. In addition, we demonstrated that the suppressor cells in the immune cell population were derived from cyclophosphamide-sensitive precursors. These data indicate that a third suppressor cell population is required for efferent suppression of the cryptococcal DTH response. As in the azobenzenearsonate and 4-hydroxy-3-nitrophenyl acetyl hapten suppressor models, the Ts2 cells in the circuit mediate their effects through this third suppressor component. Since the mode of induction and the phenotype of the third C. neoformans-specific suppressor cells are similar to those reported for Ts3 cells in other antigen-specific suppression models, we referred to this third suppressor cell in the C. neoformans-specific suppressor cell cascade as a Ts3 cell.     

Effects of Cryptococcus neoformans-specific suppressor T cells on the amplified anticryptococcal delayed-type hypersensitivity response.

Cell-mediated immunity is an important host resistance mechanism against Cryptococcus neoformans, the etiological agent of cryptococcosis. Previous studies from our laboratory have shown that the anticryptococcal cell-mediated immune response as measured by delayed-type hypersensitivity (DTH) is down-regulated by a cascade of antigen-specific T suppressor (Ts) cells. Recently, we have identified a population of CD4 T cells that up-regulate the anticryptococcal DTH response (Tamp cells). The Tamp cells are found in the spleens of donor mice at 6 days after immunization with cryptococcal antigen, and they amplify the anticryptococcal DTH response when transferred to syngeneic recipients at the time of immunization of the recipients. In this study, we determined the effects of C. neoformans-specific Ts cells on the induction of the Tamp cells in the Tamp cell-donor mice and on the induction and expression of the amplified anticryptococcal DTH response in the Tamp cell-recipient mice. When cryptococcal-specific Ts1 cells were given at the time of immunization of the Tamp cell-donor mice, induction of Tamp cells was inhibited. In contrast, when Ts1 cells were given at the time of adoptive transfer of Tamp cells, the recipients displayed amplified DTH responses, indicating that Ts1 cells do not affect the Tamp cells' function once the Tamp cells have been produced. C. neoformans-specific Ts2 cells given at the time of either immunization or footpad challenge of the Tamp cell-recipient mice did not alter, to any measurable extent, the amplified DTH response. These results indicate that in addition to amplifying the anticryptococcal DTH response, Tamp cells may protect the anticryptococcal TDH cells from suppression by C. neoformans-specific Ts cells, much like contrasuppressor cells do in other systems. However, further characterization of the Tamp cells revealed that they are not adherent to Viscia villosa lectin, indicating that the anticryptococcal Tamp cells do not have this characteristic in common with contrasuppressor cells of other antigen systems.     

Age-related resistance of C57BL/6 mice to Cryptococcus neoformans is dependent on maturation of NKT cells

Conflicting results have been reported regarding the ability of C57BL/6 mice to clear infections due to Cryptococcus neoformans. Examination of the various experimental protocols used suggested that C57BL/6 mice might develop the ability to resist infection as they mature. We analyzed the ability of C57BL/6 mice of different ages to respond to immunization with cryptococcal antigen or to clear a cryptococcal infection. Mice were immunized with a soluble cryptococcal culture filtrate antigen (CneF) emulsified in complete Freund's adjuvant (CneF-CFA). Delayed-type hypersensitivity (DTH) reactions elicited by the immunization were significantly stronger in 15-week-old C57BL/6 mice than in 7-week-old mice. Analysis of cryptococcal CFU 8 weeks following intratracheal infection of 7-week-old mice or 15-week-old mice revealed a relative inability of the younger animals to control the infection. Six-week-old immunized and infected mice cleared cryptococci from brain, spleen, and liver in a manner similar to that of immunized and infected 15-week-old mice. However, the older mice cleared cryptococci much more efficiently from the lungs. The possible role for NKT cells was determined by passive transfer of thymocytes from 10-week-old mice (containing mature NKT cells) or 2-week-old mice (containing immature NKT cells) to 6-week-old mice. The 10-week-old thymocytes significantly enhanced the ability of the mice to develop a DTH response after immunization with CneF-CFA, while animals treated with 2-week-old thymocytes did not improve their DTH response after immunization. The cells in the 10-week-old thymocyte population responsible for improvement of DTH responses were identified as being NK1.1 positive.     

Transfer of immunity to cryptococcosis by T-enriched splenic lymphocytes from Cryptococcus neoformans-sensitized mice.

Splenic enriched T-cells and sera were obtained from inbred CBA/J mice injected 7 or 35 days earlier with either 10(3) viable Cryptococcus neoformans or sterile physiological saline. The transfer of enriched T-cells collected 7 days after immunization or of normal enriched T-cells did not transfer immunity to C. neoformans or delayed-type hypersensitivity responsiveness to cryptococcal culture filtrate (CneF) antigen to the recipients. However, enriched T-cells harvested 35 days after immunization, when transferred to recipient mice, were able to confer immunity as indicated by the reduction in numbers of C. neoformans cells in the tissues, and they also transferred delayed-type hypersensitivity responsiveness to CneF antigens. Sera from either sensitized or normal mice were unable to transfer immunity to recipient animals. These results suggested that there was a time requirement for development of the immune response in the donor mice and that T-cells were crucial in the host defense against a cryptococcal infection. Culturing of day-35 C. neoformans-sensitized T-cells in the presence of homologous antigen (CneF) but not in the presence of heterologous antigen (purified protein derivative or 2, 4-dinitro-1-fluorobenzene) induced the production of migration inhibition factor, thus indicating that lymphocytes from C. neoformans-injected mice were specifically sensitized to CneF antigen.     

Antigen-Induced Protective and Nonprotective Cell-Mediated Immune Components against Cryptococcus neoformans

Mice immunized with two different cryptococcal antigen preparations, one a soluble culture filtrate antigen (CneF) in complete Freund’s adjuvant (CFA) and the other heat-killed Cryptococcus neoformans cells (HKC), develop two different profiles of activated T cells. CneF-CFA induces CD4⁺ T cells responsible for delayed-type hypersensitivity (DTH) reactivity and for amplification of the anticryptococcal DTH response, whereas HKC induce CD4⁺ and CD8⁺ T cells involved in anticryptococcal DTH reactivity and activated T cells which directly kill C. neoformans cells. The main purpose of this study was to assess the level of protection afforded by each of the two different T-cell profiles against challenge with viable C. neoformans cells, thereby identifying which activated T-cell profile provides better protection. CBA/J mice immunized with CneF-CFA had significantly better protective responses, based on better clearance of C. neoformans from tissues, on longer survival times, and on fewer and smaller lesions in the brain, than HKC-immunized mice or control mice similarly infected with C. neoformans. Both immunization protocols induced an anticryptococcal DTH response, but neither induced serum antibodies to glucuronoxylmannan, so the protection observed in the CneF-CFA immunized mice was due to the activated T-cell profile induced by that protocol. HKC-immunized mice, which displayed no greater protection than controls, did not have the amplifier cells. Based on our findings, we propose that the protective anticryptococcal T cells are the CD4⁺ T cells which have been shown to be responsible for DTH reactivity and/or the CD4⁺ T cells which amplify the DTH response and which have been previously shown to produce high levels of gamma interferon and interleukin 2. Our results imply that there are protective and nonprotective cell-mediated immune responses and highlight the complexity of the immune response to C. neoformans antigens.     

Host-Etiological Agent Interactions in Intranasally and Intraperitoneally Induced Cryptococcosis in Mice

Inbred CBA/J mice were used in developing a defined in vivo model for studying host-parasite relationships in cryptococcosis. Mice were infected either intranasally or intraperitoneally with 10³ viable Cryptococcus neoformans cells. At weekly intervals over a 92-day period, C. neoformans growth profiles in the lungs, spleens, livers, and brains of the infected animals were determined. In addition, humoral and delayed-type hypersensitivity responses and cryptococcal antigen levels were assayed in these mice. Intranasally infected mice developed strong delayed-type hypersensitivity reactions in response to cryptococcal culture filtrate (CneF) antigen, and there was good correlation between acquisition of delayed-type hypersensitivity and the reduction of C. neoformans cell numbers in infected tissues. In contrast, intraperitoneally infected mice displayed greater numbers of C. neoformans cells in tissues and had somewhat suppressed delayed-type hypersensitivity responses to CneF antigen. Anticryptococcal antibodies were not detected in intranasally or intraperitoneally infected mice, but cryptococcal polysaccharide antigen titers were relatively high in both groups. The transfer of sensitized spleen cells from intranasally infected mice to syngeneic naive recipient mice resulted in the transfer of delayed-type hypersensitivity responsiveness to cryptococcal antigen in the recipients. The intranasally induced infection in mice was similar to the naturally acquired infection in humans; therefore we are proposing that this murine-cryptococcosis model would be useful in gaining a greater understanding of host-etiological agent relationships in this disease.     

Intravascular cryptococcal culture filtrate (CneF) and its major component, glucuronoxylomannan, are potent inhibitors of leukocyte accumulation.

Disseminated cryptococcosis is characterized by high titers of cryptococcal polysaccharides in serum and minimal cellular infiltrates in infected tissues of patients. The main objective of this study was to determine whether the circulating cryptococcal polysaccharides could contribute to the lack of cellular infiltration into infected tissues. To assess this possibility, a gelatin sponge implantation model was used. We found that intravenous (i.v.) injection of mice with cryptococcal culture filtrate antigen (CneF) inhibited migration of leukocytes (neutrophils, lymphocytes, and monocytes) into the intrasponge sites of acute inflammation induced by CneF, tumor necrosis factor alpha, or formylmethionyl leucyl phenylalanine. In addition, i.v. administration of CneF inhibited leukocyte migration into the intrasponge sites of a cell-mediated immune reaction irrespective of whether the delayed-type hypersensitivity response was to CneF or the mycobacterial antigen purified protein derivative. Glucuronoxylomannan, a major constituent of CneF and a major cryptococcal antigen detected in the sera of patients with disseminated cryptococcosis, when given i.v. to mice, inhibited leukocyte migration into the sponges. Our results suggest that the minimal cellular infiltrates observed in infected tissues of cryptococcosis patients may be due, in part, to the circulating cryptococcal polysaccharide functioning as we have demonstrated in the mouse model. Furthermore, the high titers of cryptococcal antigen in the sera of patients may diminish leukocyte migration in response to stimuli other than Cryptococcus neoformans, a point that may be relevant in AIDS patients with cryptococcosis.     

Effects of first-order Cryptococcus-specific T-suppressor cells on induction of cells responsible for delayed-type hypersensitivity.

Cell-mediated immunity is an important aspect of host resistance against Cryptococcus neoformans. Using a CBA/J murine model, we demonstrated that injection of cryptococcal antigen (CneF) at dosages sufficient to stimulate the antigenemia observed in cryptococcosis patients induces specific T-cell-mediated suppression of the cryptococcal delayed-type hypersensitivity response. The purpose of this study was to establish whether Lyt 1+, first-order T-suppressor (Ts1) cells block the induction of T cells responsible for delayed-type hypersensitivity (TDH cells) or whether they function by inducing Lyt 2+, efferent suppressor (Ts2) cells. In one set of experiments, suppression was observed when Ts1 cells were adoptively transferred to recipient animals the day before, the day of, or the day after immunization; however, when Ts1 cells were transferred after TDH cells were present, no suppression occurred. In other experiments, putative TDH cells from lymph nodes (LN) or spleens were adoptively transferred from mice after immunization or after a suppressive dose of CneF or adoptive transfer of Ts1 cells and immunization. Delayed-type hypersensitivity could not be transferred with LN or spleen cells from mice receiving the suppressive dose of CneF or the Ts1 cells, even when the LN or spleen cells were treated with anti-Lyt 2.1 antibody and complement to remove any Ts2 cells. Delayed-type hypersensitivity was readily transferred with LN or spleen cells from immunized mice whether the cells were or were not treated with anti-Lyt 2 and complement. Furthermore, the cells in the tolerized LN cell pools responsible for suppression of TDH cell induction were Lyt 1+ 2-, I-J+ cells, which is the phenotype of the Ts1 cells. Taken together, these data indicate that Ts1 cells inhibit the induction of TDH cells. This finding, coupled with the previous demonstration that Ts1 cells or a Ts1 cell-derived soluble factor (TsF1) induces Ts2 cells, establishes that the cryptococcal Ts1 cells are bifunctional in the suppressive pathway.     

Effects of cyclosporin A on the cells responsible for the anticryptococcal cell-mediated immune response and its regulation.

Cyclosporin A (CsA), a potent immunosuppressive drug, was used to explore further the induction, expression, and regulation of lymphoid cells involved in the delayed-type hypersensitivity (DTH) response to cryptococcal antigen(s). We found that the induction of the cells responsible for DTH (TDH cells) was not affected by CsA, but their expression was inhibited in CsA-treated mice. The inhibition of expression of the TDH cells could not be attributed to the Cryptococcus neoformans-specific suppressor T (Ts) cells, even though the Ts cells were induced in CsA-treated mice. Instead, the suppressed expression of the TDH cells in CsA-treated mice was a direct effect of CsA or its products. Our studies with CsA also resulted in the first identification of a population of cells that significantly amplify the anticryptococcal DTH response. The amplifier cells were induced in mice that were given a primary immunizing dose of cryptococcal antigen in complete Freund adjuvant, and they amplified the anticryptococcal DTH response in recipient mice when they were transferred at the time of immunization of the recipient. The amplifier cell population was distinct from the TDH cells in that CsA inhibited the production of the amplifying cells but did not affect the induction of TDH cells. Amplification of the DTH response was a cell-mediated event, since cells but not serum from immunized mice mediated the amplified response in recipient mice. Thus, CsA enabled us to characterize anticryptococcal TDH and Ts cells further and to add to the immune cell circuit of the cryptococcal system a distinct population of cells that amplifies the anticryptococcal DTH response.     

Differences in components at delayed-type hypersensitivity reaction sites in mice immunized with either a protective or a nonprotective immunogen of Cryptococcus neoformans.

Cell-mediated immunity is the major protective mechanism against Cryptococcus neoformans. Delayed swelling reactions, i.e., delayed-type hypersensitivity (DTH), in response to an intradermal injection of specific antigen are used as a means of detecting a cell-mediated immune (CMI) response to the antigen. We have found previously that the presence of an anticryptococcal DTH response in mice is not always indicative of protection against a cryptococcal infection. Using one immunogen that induces a protective anticryptococcal CMI response and one that induces a nonprotective response, we have shown that mice immunized with the protective immunogen undergo a classical DTH response characterized by mononuclear cell and neutrophil infiltrates and the presence of gamma interferon and NO. In contrast, immunization with the nonprotective immunogen results in an influx of primarily neutrophils and production of tumor necrosis factor alpha (TNF-alpha) at the DTH reaction site. Even when the anticryptococcal DTH response was augmented by blocking the down-regulator, CTLA-4 (CD152), on T cells in the mice given the nonprotective immunogen, the main leukocyte population infiltrating the DTH reaction site is the neutrophil. Although TNF-alpha is increased at the DTH reaction site in mice immunized with the nonprotective immunogen, it is unlikely that TNF-alpha activates the neutrophils, because the density of TNF receptors on the neutrophils is reduced below control levels. Uncoupling of DTH reactivity and protection has been demonstrated in other infectious-disease models; however, the mechanisms differ from our model. These findings stress the importance of defining the cascade of events occurring in response to various immunogens and establishing the relationships between protection and DTH reactions.     

Presentation of cryptococcal capsular polysaccharide (GXM) on activated antigen-presenting cells inhibits the T-suppressor response and enhances delayed-type hypersensitivity and survival.

A hallmark of infection with Cryptococcus neoformans is depression of the immune system characterized by poor inflammatory responses and loss of delayed-type hypersensitivity (DTH) and antibody responses. T-suppressor cell (Ts) responses, elicited by the capsular polysaccharide (GXM) of the organism, are known to develop during infection. This study was undertaken to develop a method to inhibit the anti-GXM Ts response and thereby study the influence of the Ts response on immune responsiveness and survival in cryptococcosis. Antigen-presenting cells (APC), elicited with complete Freund's adjuvant (CFA), were treated in vitro with GXM (GXM-APC). The GXM-APC were injected intravenously into normal mice. These mice were resistant to induction of anti-GXM Ts cells when soluble GXM was administered in tolerogenic doses or when animals were infected with C. neoformans. Inhibition of the anti-GXM Ts response was specific to GXM as levan-APC did not inhibit induction of anti-GXM Ts cells. Inhibition of the anti-GXM Ts response could not be attributed to increased clearance of GXM due to induction of anti-GXM antibodies or other mechanisms. Anti-cryptococcal DTH responses were lost in mice by the second week of infection. However, treatment with GXM-APC, but not levan-APC, allowed mice to maintain their DTH response. GXM-APC pretreatment enhanced survival of infected mice compared with mice pretreated with levan-APC. These results show that GXM-APC induces immune responses that inhibit the induction of Ts responses and enhances DTH responses in infected mice. These responses correlate with enhanced survival after cryptococcal infection.