In vitro T cell-mediated killing of Pseudomonas aeruginosa. V. Generation of bactericidal T cells in nonresponder mice

We have previously reported that BALB/c mice immunized with 10 micrograms of a Pseudomonas aeruginosa polysaccharide antigen (PS) and 100 micrograms vinblastine sulfate develop T cell-mediated protective immunity, but fail to generate an antibody response. Vinblastine functions in this system to remove a suppressor cell that normally inhibits expression of this form of immunity after PS immunization. T cells from CB.20 mice immunized with the 10 micrograms of PS and 100 micrograms vinblastine fail to kill P. aeruginosa in vitro. These mice are allotype congenic with BALB/c mice, differing at loci closely linked to the IgH-1 locus. Immunization of CB.20 mice with 10 micrograms PS and 100 micrograms vinblastine results in the appearance of T cells which suppress in vitro bactericidal activity of BALB/c T cells. In the current study we found that T cell-mediated bactericidal activity can be generated in CB.20 mice by increasing the dose of vinblastine given at the time of PS immunization. The phenotype of the CB.20 bactericidal T cell generated by high dose vinblastine is identical to that of the BALB/c bactericidal T cell, and the CB.20 bactericidal T cell can adoptively transfer protective immunity to granulocytopenic mice. After immunization of BALB/c and CB.20 mice with PS alone, approximately one log fewer CB.20 T cells than BALB/c T cells are required to suppress bacterial killing in vitro. Furthermore, the number of CB.20 T cells required to suppress in vitro bacterial killing is directly correlated with the dose of vinblastine administered at the time of immunization. Increasing the immunizing dose of PS overcomes suppressor activity and allows the generation of bactericidal T cells in BALB/c mice without a requirement for vinblastine. CB.20 mice fail to generate bactericidal T cells after immunization with high doses of PS. These results indicate that CB.20 and BALB/c mice both possess the full repertoire of T cells required to express bactericidal T cell activity and that the differences in their responses reflect only quantitative differences in suppressor cell activity.     

In vitro T cell-mediated killing of Pseudomonas aeruginosa. III. The role of suppressor T cells in nonresponder mice

T lymphocytes from immune BALB/c mice can adoptively transfer protection against infection with the extracellular Gram-negative bacterium Pseudomonas aeruginosa to nonimmune recipients, and in vitro, immune T cells are able to kill these bacteria. Earlier studies indicated that this killing is mediated by a bactericidal lymphokine. The current studies demonstrate that T cells from immunized CB.20 mice, a strain congenic with BALB/c, fail to kill Pseudomonas aeruginosa in vitro. This nonresponsiveness is attributable to the activity of suppressor T cells of the Lyt-1-, 2,3+, I-J+ phenotype. CB.20 mice are known to differ from BALB/c mice only at a single locus, which includes the Igh-1 allotype CH genes. These results suggest a critical role for this locus or closely linked genes in the control of T cell killing of this extracellular bacterium.     

T cell subsets regulating antibody responses to L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT) in virgin and immunized nonresponder mice

T cell subsets from virgin and immunized mice, which are Ir gene controlled nonresponders to GAT, which regulate antibody responses to GAT have been characterized. Virgin nonresponder B10.Q B cells develop GAT-specific antibody responses to GAT, B10.Q GAT-M phi, and GAT-MBSA when cultured with virgin or GAT-primed Lyt-1+, I-J-, Qa1- B10.Q helper T cells. Virgin T cells are radiosensitive, whereas immune T cells are radioresistant (750 R); qualitatively identical helper activity is obtained with T cells from mice immunized with soluble GAT, B10.Q GAT-M phi, and GAT-MBSA. Responses to GAT and GAT-M phi are not observed when virgin or GAT-primed Lyt-1+, I-J+, Qal+ T cells are added to culture of virgin or GAT-primed Lyt-1+, I-J-, Qa1- helper T cells and virgin B cells; the GAT-specific response to GAT-MBSA is intact. The Lyt-1+, I-J+, Qa1+ T cells from mice primed with GAT, GAT-M phi, and GAT-MBSA were qualitatively identical in mediating this suppression. Virgin Lyt-2+ T cells have no suppressive activity alone or with virgin Lyt-1+, I-J+, Qa1+ T cells, whereas responses to GAT, GAT-M phi, and GAT-MBSA are suppressed in cultures of GAT-primed helper T cells containing GAT-primed Lyt-2+ T cells (with or without GAT-primed Lyt-1+, I-J+, Qa1+ T cells). Suppression of responses to GAT-MBSA in cultures of GAT-M phi-primed helper T cells requires both GAT-M phi-primed Lyt-1+, I-J+, Qa1+ T cells and Lyt-2+ T cells; the Lyt-1+, I-J+, Qa1+ T cells appear to function as inducer cells in this case. In cultures containing GAT-MBSA-primed helper T cells, either GAT-MBSA-primed Lyt-1+, I-J+, Qa1+ or Lyt-2+ T cells suppress responses to GAT and GAT-M phi; under no circumstances are responses to GAT-MBSA suppressed by GAT-MBSA-primed regulatory T cells. This regulation of antibody responses to GAT by suppressor T cells is discussed in the context of the involvement of suppressor T cells in responses to antigens under Ir control, and of the evidence that nonresponsiveness to GAT is not due to a defect in the T cell repertoire, but rather is due to an imbalance in the activation of suppressor vs helper T cells.     

T cells recognizing polysaccharide-specific B cells function as contrasuppressor cells in the generation of T cell immunity to Pseudomonas aeruginosa

The cellular interactions involved in the development of T cell-mediated immunity to Pseudomonas aeruginosa have been examined. T cell immunity can be generated by immunizing mice with 10 micrograms of P. aeruginosa polysaccharide (PS) plus the antimitotic agent vinblastine sulfate. Vinblastine is required to inactivate a population of Ts cells generated by immunization with 10 micrograms of PS alone. Immunization with either live bacteria or with higher dose (50 micrograms) of PS without vinblastine also generates T cell immunity; these protocols activate a population of Lyt-1+, 2-, I-J+ T cells which, like vinblastine, counteract the effect of Ts cells. Immunization with 10 micrograms PS alone fails to activate this T cell subpopulation. When administered at the time of immunization, this subpopulation can render the tolerogenic 10-micrograms immunization protocols immunogenic. Like previously described contrasuppressor T cells, this T cell subpopulation exhibits an affinity for the lectin Vicia villosa. We have determined, however, that the T cells that act as contrasuppressor cells in this system are directly activated by PS-immune B cells and not by PS Ag. Furthermore, their activity can be removed by adsorption to PS-specific B cell hybridomas. Our studies indicate an important role for B cells in the development of T cell immunity to P. aeruginosa and suggest that a complex idiotype network controls the development of this response.     

In vitro T cell-mediated killing of Pseudomonas aeruginosa. II. The role of macrophages and T cell subsets in T cell killing

T lymphocytes from immune mice can adoptively transfer protection against infection with the extra-cellular Gram-negative bacterium Pseudomonas aeruginosa to nonimmune recipients, and in vitro, immune T cells are able to kill these bacteria. Earlier studies indicated that this killing is mediated by a bactericidal lymphokine. Those studies also showed that macrophages enhance this in vitro T cell killing but do not directly participate in the bacterial killing, nor do macrophages function to present antigen to T cells. The current studies demonstrate that the ability of macrophages to enhance T cell killing can be replaced by macrophage culture supernatants or by purified recombinant interleukin 1 (IL 1). In addition, the macrophage supernatant-induced enhancement can also be blocked by antibody to purified IL 1. These studies also demonstrate that the T cell subset that serves as the final effector cell in the killing process is the Lyt-1-, 2,3+, I-J+ phenotype.     

Insulin-specific suppressor T cell factors

Murine antibody responses to heterologous insulins are controlled by MHC-linked immune response genes. Although nonresponder mice fail to make antibody when injected with nonimmunogenic variants of insulin, we have recently shown that nonimmunogenic variants stimulate radioresistant, Lyt- 1+2- helper T cells that support secondary antibody responses. However, the helper activity can not be detected unless dominant, radiosensitive Lyt-1-2+, I-J+ suppressor T cells are removed. In this paper we report that extracts of primed Lyt-2+ suppressor T cells contain insulin-specific suppressor factors (TsF) that are capable of replacing the activity of suppressor T cells in vitro. The activity of these factors is restricted by MHC-linked genes that map to the I-J region, and immunoadsorption studies indicated that they bind antigen and bear I-J-encoded determinants. Insulin-specific TsF consists of at least two chains, one-bearing I-J and the other the antigen-binding site. Furthermore, mixing of isolated chains from different strains of mice indicates that the antigenic specificity is determined by the antigen-binding chain and the MHC restriction by the H-2 haplotype of the source of the non-antigen-binding, I-J+ chain. Moreover, mixtures containing antigen-binding chain from allogeneic cell donors and I-J+ chain from responder cell donors have activity in cultures containing responder lymphocytes. This suggests that preferential activation of suppressor T cells, rather than differential sensitivity to suppression, results in the nonresponder phenotype to insulin.     

Identification of suppressor T cells in virgin non-responder spleen cells responsible for primary unresponsiveness to L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT)

T cell subsets that regulate antibody responses to L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT) in mice that are Ir gene non-responders have been further characterized. We previously defined several T cell subsets in GAT-primed non-responder mice. The Lyt-2+ suppressor-effector T cells suppress responses to GAT and GAT complexed to methylated BSA (GAT-MBSA). The Lyt-1+ cell population is complex and can be separated into I-J- Th cells, which support responses to GAT and GAT-MBSA. After priming, the Lyt-1+, I-J+ cell population contains suppressor-inducer cells that activate precursors of suppressor-effector cells to suppress responses to GAT and GAT-MBSA as well as Ts cells that directly inhibit responses to GAT but not GAT-MBSA. By contrast, the Lyt-1+ cells from virgin mice contain only cells that directly suppress responses to GAT but not GAT-MBSA. The major question addressed in the present studies was whether the Lyt-1+, I-J+ Ts cells in virgin and primed mice and the suppressor-inducer cells in GAT-primed mice were functionally and serologically distinct subsets. The studies used mAb and panning procedures to separate cell populations and inhibition of PFC cell responses to functionally define the activity of the cell populations. We used the following two mAb that were raised by immunizing rats with GAT-specific suppressor factors: 1248A4.10 (known to react with suppressor-inducer cells) and 1248A4.3, another reagent from the same fusion. Lyt-1+ cells from virgin spleens contained Ts cells that were A4.10-, A4.3+ and no suppressor-inducer T cells, whereas Lyt-1+ cells from GAT-primed spleens contained Ts cells that were A4.10-, A4.3+ as well as A4.10+, A4.3- suppressor-inducer cells. Thus, the Lyt1+, I-J+ cell subset can be divided into two functionally and serologically distinct subsets, direct Ts cells (1248A4.3+), which suppress responses to GAT but not GAT-MBSA, and GAT-primed suppressor-inducer T cells (1248A4.10+).     

T cell subsets in (responder x nonresponder)F1 mice regulating antibody responses to L-glutamic acid60-L-alanine30-L-tyrosine (GAT)

Immune responses to GAT are controlled by H-2-linked Ir genes; soluble GAT stimulates antibody responses in responder mice (H-2b) but not in nonresponder mice (H-2q). In nonresponder mice, soluble GAT stimulates suppressor T cells that preempt function of helper T cells. After immunization with soluble GAT, spleen cells from (responder x nonresponder: H-2b X H-2q)F1 mice develop antibody responses to responder H-2b GAT-M phi but not to nonresponder H-2q GAT-M phi. This failure of immune F1 spleen cells to respond is due to an active suppressor T cell mechanism that is activated by H-2q, but not H-2b, GAT-M phi and involves two regulatory T cell subsets. Suppressor-inducer T cells are immune radiosensitive Lyt-1 +2-, I-A-, I-J+, Qa-1+ cells. Suppressor-effector T cells can be derived from virgin or immune spleens and are radiosensitive Lyt-1-2+, I-A-, I-J+, Qa-1+ cells. This suppressor mechanism can suppress responses of virgin or immune F1 helper T cells and B cells. Helper T cells specific for H-2b GAT-M phi are easily detected in F1 mice after immunization with soluble GAT; helper T cells specific for H-2q GAT-M phi are demonstrated after elimination of the suppressor-inducer and -effector cells. These helper T cells are radioresistant Lyt-1+2-, I-A+, I-J-, Qa-1- cells. These data indicate that the Ir gene defect in responses to GAT is not due to a failure of nonresponder M phi to present GAT and most likely is not due to a defective T cell repertoire, because the relevant helper T cells are primed in F1 mice by soluble GAT and can be demonstrated when suppressor cells are removed. These data are discussed in the context of mechanisms for expression of Ir gene function in responses to GAT, especially the balance between stimulation of helper vs suppressor T cells.     

Murine interstitial nephritis. V. The auto-induction of antigen-specific Lyt-2+ suppressor T cells diminishes the expression of interstitial nephritis in mice with antitubular basement membrane disease

We observed the emergence of an antigen-specific Lyt-2+ suppressor T cell after the i.v. injection of tubular antigen-derivatized lymphocytes into mice already immunized to produce interstitial nephritis. The auto-induction of these suppressor T cells effectively attenuated both the expression of renal injury and a delayed-type hypersensitivity response to tubular antigen. This suppressive effect was also genetically restricted by gene products in I-J and Igh-1. Although this suppressor system had a marked inhibitory effect on the nephritogenic effector cell repertoire, there was no diminution of titers of antibodies to the tubular basement membrane. Our results demonstrate a protective role for antigen-specific suppressor cells in autoimmune renal injury, and the strategy for their induction may have important therapeutic implications for other immune-mediated disorders.     

Regulation of immune responses by T cell subsets. Role of helper and suppressor T cells in the development and expression of MHC-restricted antibody responses to L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT) by (responder X responder)F1 spleen cells

The roles of helper and suppressor T cells in the development and expression of antibody responses to GAT were studied in (responder X responder)F1 mice immunized with parental GAT-M phi. Spleen cells from (B10 X B10.D2)F1 mice primed in vivo with B10 or B10.D2 GAT-M phi developed secondary in vitro plaque-forming cell (PFC) responses only when stimulated by GAT-M phi syngeneic with the GAT-M phi used for in vivo priming. By contrast, virgin F1 spleen cells developed comparable primary PFC responses to both parental GAT-M phi Co-culture of T cells from (B10 X B10.D2)F1 mice primed in vivo by B10 GAT-M phi with virgin (B10 X B10.D2)F1 spleen cells demonstrated the presence of suppressor cells that inhibited the primary response of virgin spleen cells stimulated by B10.D2 GAT-M phi. Spleen cells from (B10 X B10.D2)F1 mice primed in vivo with B10.D2 GAT-M phi had suppressor T cells that suppressed primary responses stimulated by B10 GAT-M phi. The suppressor T cell mechanism was composed of at least two regulatory T cell subsets. Suppressor-inducer T cells were Lyt-2-, I-J+ and must be derived from immune spleen cells. Suppressor-effector T cells can be derived from virgin or immune spleens and were Lyt-2+ cells. When the suppressor mechanism was disabled by treatment with 1000 rad gamma irradiation or removal of Lyt-2+ cells, Lyt-2-helper T cells from (B10 X B10.D2)F1 mice primed with B10 GAT-M phi provided radioresistant help to virgin F1 B cells stimulated by B10 but not B10.D2 GAT-M phi. Suppressor inducer Lyt-2-,I-J+ cells from B10 GAT-M phi-primed (B10 X B10.D2)F1 mice were separated from the primed Lyt-2-,I-J-helper T cells. In the presence of Lyt-2+ suppressor effector cells, the Lyt-2-,I-J+ suppressor-inducer suppressed the primary response of virgin spleen or virgin T plus B cells stimulated by both B10 and B10.D2 GAT-M phi. Therefore, suppressor T cells were able to suppress primary but not secondary GAT-specific PFC responses stimulated by either parental GAT-M phi. These results showed that immunization of (responder X responder)F1 mice with parental GAT-M phi results in the development of antigen-specific helper and suppressor T cells. The primed helper T cells were radioresistant and were genetically restricted to interact with GAT in association with the major histocompatibility complex antigens of the M phi used for in vivo priming.(ABSTRACT TRUNCATED AT 400 WORDS)     

Contrasuppressor cells that break oral tolerance are antigen-specific T cells distinct from T helper (L3T4+), T suppressor (Lyt-2+), and B cells

Continuous gastric intubation of mice with the T cell-dependent antigen sheep erythrocytes (SRBC) leads to a state of systemic unresponsiveness to parenteral SRBC challenge, a state termed oral tolerance. The systemic unresponsiveness of mice rendered orally tolerant to SRBC, however, is converted to humoral immune responsiveness by adoptive transfer of effector T contrasuppressor (Tcs) cells. In this study, the authors have isolated and characterized the Tcs cell subset, from the spleens of orally immunized mice, which abrogates oral tolerance. This Tcs cell is a novel cell type, which can be separated from functional T suppressor (Lyt-2+) and T helper (L3T4+) cells, and the effector Tcs cell exhibits a Lyt-1+, 2-, L3T4- phenotype. Furthermore, contrasuppression is not mediated by B cells, including those of the Lyt-1+ phenotype. Adoptive transfer of splenic Lyt-1+, 2-, L3T4- T cells from C3H/HeJ mice given oral SRBC for 21 to 28 days and splenic Lyt-1+, 2-, L3T4- T cells of C3H/HeN mice orally immunized for a shorter interval abrogated oral tolerance. Furthermore, separation of Lyt-1+ T cells into L3T4+ and L3T4- subsets by flow cytometry resulted in Lyt-1+, L3T4+ T cells with helper but not contrasuppressor function, whereas the Lyt-1+, L3T4- T cell fraction abrogated oral tolerance even though it was without helper activity. This Tcs cell subset was also effective when added to cultures of tolerized spleen cells derived from SRBC-fed mice. The effector Tcs cells are antigen-specific, because Tcs cells from SRBC-immunized mice reverse tolerance to SRBC but not to horse erythrocytes (HRBC), and Tcs cells from HRBC-immunized mice reverse tolerance to HRBC but not to SRBC. When splenic T3 (CD3)-positive T cells (Lyt-1+, 2-, and L3T4-) were separated into Vicia villosa-adherent and nonadherent subpopulations, active contrasuppression was associated with the T3-positive and Vicia villosa-adherent T cell fraction. Thus, a distinct Lyt-1+, 2-, L3T4- T cell subset that contains a T3-T cell receptor complex, which can regulate oral tolerance, is present in spleens of orally immunized mice.     

IgE-binding factors from mouse T lymphocytes. III. Role of antigen-specific suppressor T cells in the formation of IgE-suppressive factor

BDF1 mice were given three i.v. injections of ovalbumin (OA) to induce antigen-specific suppressor T cells. Incubation of spleen cells of OA-treated mice with homologous antigen resulted in the formation of IgE-suppressive factor. This factor was not derived from antigen-specific suppressor T cells, but suppressor T cells were essential for determining the nature of IgE-binding factors formed. In the spleen cells of OA-treated mice, antigenic stimulation of antigen-primed Lyt-1+ (helper) T cells resulted in the formation of inducers of IgE-binding factor, whereas Lyt-2+, I-J+ T cells released glycosylation-inhibiting factor (GIF), and these two factors, in combination, induced unprimed Lyt-1+ T cells to form IgE-suppressive factor. The role of GIF is to inhibit the assembly of N-linked oligosaccharides on IgE-binding factors during their biosynthesis, and thereby provide them with a biologic activity: suppression of the IgE response. Under the experimental conditions employed, GIF was released spontaneously from antigen-specific suppressor T cells. However, antigenic stimulation of the cells enhanced the release of the factor. GIF from antigen-specific suppressor T cells has a m.w. of 25,000 to 30,000, as estimated by using gel filtration, binds to anti-I-J alloantibodies and to a monoclonal antibody specific for lipomodulin, and has affinity for specific antigen. The possible relationship between antigen-specific GIF and antigen-specific suppressor factors is discussed.     

Enterically induced regulation of systemic immune responses. II. Suppression of proliferating T cells by an Lyt-1+, 2- T effector cell

Peripheral lymph node cells from C3H mice that were fed and injected with bovine serum albumin (REG cells) demonstrate an impaired proliferative response to antigenic stimulation in vitro compared to cells from mice only injected with BSA. To determine whether suppressor cells contributed to this enterically induced impairment of systemic T cell responses, REG cells were pretreated with various monoclonal antibodies and complement (C), and were then co-cultured with antigen-reactive indicator T cells (IND) from parenterally immunized mice. Proliferation of IND cells [( 3H]thymidine uptake) was suppressed only if REG cells were treated with anti-Lyt-2 and C before co-culture. The ability of anti-Lyt-1 plus anti-Lyt-2 and C treatment to abrogate suppression suggested that the suppressor effect was due to an Lyt-1+, 2- REG cell. Suppression was independent of Lyt-2+ IND cells, and was observed at different antigen concentrations, cultivation times, and cell densities. The cells responsible for suppressor activity were radiosensitive, nylon wool nonadherent, and antigen specific. These data suggest that an Lyt-1+, 2- T cell could be an important component in mediating enterically induced regulation of systemic T cell responses.     

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.     

The role of tumor-specific Lyt-1+2- T cells in eradicating tumor cells in vivo. I. Lyt-1+2- T cells do not necessarily require recruitment of host's cytotoxic T cell precursors for implementation of in vivo immunity

The present study determines the Ly phenotype of T cells mediating tumor cell rejection in vivo and investigates some of cellular mechanisms involved in the in vivo protective immunity. C3H/HeN mice were immunized to syngeneic X5563 plasmacytoma by intradermal (i.d.) inoculation of viable X5563 tumor cells, followed by the surgical resection of the tumor. Spleen cells from these immune mice were fractionated by treatment with anti-Lyt antibodies plus complement, and each Lyt subpopulation was tested for the reconstituting potential of in vivo protective immunity in syngeneic T cell-depleted mice (B cell mice). When C3H/HeN B cell mice were adoptively transferred with Lyt-1-2+ T cells from the above tumor-immunized mice, these B cell mice exhibited an appreciable cytotoxic T lymphocyte (CTL) response to the X5563 tumor, whereas they failed to resist the i.d. challenge of X5563 tumor cells. In contrast, the adoptive transfer of Lyt-1+2- anti-X5563 immune T cells into B cell mice produced complete protection against the subsequent tumor cell challenge. Although no CTL or antibody response against X5563 tumors was detected in the above tumor-resistant B cell mice, these mice were able to retain Lyt-1+2- T cell-mediated delayed-type hypersensitivity (DTH) responses to the X5563 tumor. These results indicate that Lyt-1+2- T cells depleted of the Lyt-2+ T cell subpopulation containing CTL or CTL precursors are effective in in vivo protective immunity, and that these Lyt-1+2- T cells implement their in vivo anti-tumor activity without inducing CTL or antibody responses. The mechanism(s) by which Lyt-1+2- T cells function in vivo for the implementation of tumor-specific immunity is discussed in the context of DTH responses to the tumor-associated antigens and its related Lyt-1+2- T cell-mediated lymphokine production.     

Nonspecific inhibitor of DNA synthesis elaborated by T acceptor cells. I. Specific hapten- and I-J-driven liberation of an inhibitor of cell proliferation by Lyt-1-2+ cyclophosphamide-sensitive T acceptor cells armed with a product of Lyt-1+2+-specific suppressor cells

Lyt-1+2+ hapten-specific T suppressor cells (Ts) from mice injected and then painted with picryl or oxazolone derivatives produce hapten-specific T suppressor factors (TsF) in vitro. Stimulation by painting with contact sensitizer (which need not be specific) gives rise to Lyt-1-2+, I-J+, cyclophosphamide-sensitive T acceptor cells (Tacc). When the Tacc population is armed with TsF and then is exposed to specific antigen in the context of I-J-controlled determinants (antigen-presenting, haptenized spleen cells and Ts sharing the same I-J subregion), a nonspecific inhibitor of DNA synthesis (nsINH) appears in the supernatant. This inhibitor suppresses the primary DNA synthetic response to concanavalin A, lipopolysaccharide, and alloantigens in both syngeneic and allogeneic lymphocytes. The nsINH is only effective when added to lymphocyte cultures less than 8 hr after the stimulation with concanavalin A. The nsINH, however, affects neither primary nor secondary cytotoxicity in vitro. These data suggest the mouse immune system is capable of selective regulation of the response to specific antigen by the production of nonspecific soluble suppressor factor(s).     

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.     

Effect of depletion of L3T4+ cells on resistance to early primary infection of mice with Taenia taeniaeformis

The role of L3T4+ T lymphocytes in early primary infection with the metacestode of T. taeniaeformis was investigated by selective removal of these cells in vivo by parenteral injections with the rat monoclonal antibody (MAb) GK1.5 directed against the L3T4 molecule. Comparisons between treated and non-treated BALB/cByJ mice, normally resistant to infection with T. taeniaeformis, demonstrated that the treated mice had a greater percentage of viable parasites in the livers. Eosinophils were prominent in the region immediately surrounding parasite larvae in control mice, whereas treated mice showed virtually no eosinophil infiltration. Additionally, fewer tissue macrophages were evident near parasite larvae in the treatment group when compared to controls. The more susceptible C3H/HeDub strain mice demonstrated similar responses following treatment with the MAb, including diminished parasite killing and limited inflammatory cell infiltration. When C3H/HeDub mice were injected with the cytotoxic agent vinblastine sulfate, which has been shown to diminish Lyt-2+ suppressor cell activity, these mice remained unable to mount a strong local cellular response to the larval parasite. It is suggested that L3T4+ T lymphocytes play a crucial role in the innate resistance to T. taeniaeformis infection during the first 6 days post-infection. Effects seen following vinblastine treatment may be a result of drug-induced alterations in leukocyte chemotaxis, toxicity to other effector T cell populations, or a specific depletion of a functional Lyt-2+ T cell population that is required in addition to L3T4+ T cells for the expression of resistance to primary infection with T. taeniaeformis.     

Hapten-specific T cell responses to 4-hydroxy-3-nitrophenyl acetyl. XIII. Characterization of a third T cell population involved in suppression of in vitro PFC responses

The involvement of a third-order suppressor T cell population (Ts3) in the suppression of in vitro PFC responses was analyzed. It was shown that Ts2 effector-phase suppressor cells, induced by the i.v. injection of NP-coupled syngeneic spleen cells, require a third suppressor T cell population to effect NPb idiotype-specific suppression of an in vitro B cell response. This Ts3 population was shown to be present in NP-primed but not unprimed donors. The Ts3 population specifically binds NP and is Lyt-1-, Lyt-2+, I-J+ and bears NPb idiotypic determinants. The involvement of the Ts3 population in a suppressor pathway that requires recognition of idiotypic determinants is discussed.     

T cells subsets responsible for clearance of Sendai virus from infected mouse lungs

T cell subsets responsible for clearance of Sendai virus from mouse lungs determined by adoptive transfer of immune spleen cell fractions to infected nude mice. T cells with antiviral activity developed in spleens by 7 days after intranasal infection. Spleen cell fractions depleted of Lyt-2+, Lyt-1+, or L3T4+ cells showed antiviral activity in vivo, although the degree of the activity was lower than that of control whole spleen cells. The antiviral activity of the Lyt-2+ cell-depleted fraction was consistently higher than that of L3T4+ (Lyt-1+)-depleted cells. In vitro cytotoxic activity against Sendai virus-associated, syngeneic lipopolysaccharide-blast cells was detected in stimulated cells from intraperitoneally immunized mice but was lost after depletion of Lyt-2+ cells. Multiple injection of anti-Sendai virus antibody into infected nude mice had no effect on lung virus titer. These results indicate that L3T4+ (Lyt-1+) and Lyt-2+ subsets are cooperatively responsible for efficient clearance of Sendai virus from the mouse lung.