Mixed lymphocyte reactivity in spleen cells from F-9 tumor-bearing mice. II. Functional cross-reactivity between F-9 cells and testicular cells

Previous serological analysis has revealed cross-reactive antigens on F-9 cells and mouse germ cells. Therefore, we investigated whether suppressor activity in spleen cells from F-9 tumor-bearing mice can be restimulated in vitro by adding F-9 cells or testicular cells to mixed lymphocyte cultures. We found equal potentiation of suppressor T-cell activity with F-9 cells and with syngeneic testicular cells; as shown by sensitivity to anti-Lyt 2.2 plus complement treatment. Suppressor activity of spleen cells from other tumor systems tested was not enhanced. The data suggest that the same or cross-reactive antigens on F-9 teratocarcinoma cells and testicular cells may have similar regulatory functions.     

Fractionation of lymphocyte subpopulations which regulate mixed lymphocyte reactions.

Four days after injection of allogeneic lymphocytes BALB/c splenic T cells suppress proliferation of syngeneic cells in mixed lymphocyte reactions (MLR). Conversely, lymph node cells from the same mice amplify MLR responses. To further characterize these functional subpopulations, alloantigen-primed lymphocyte suspensions from both organs were fractionated by velocity sedimentation at unit-gravity. After fractionation MLR suppressor cells from spleens localized exclusively in rapidlly sedimenting fractions of large cells. MLR suppressor activity of cells from these fractions, as well as that of unfractionated spleen cell suspensions, was abolished by treatment with anti-Thy-1.2 serum and complement. Spleen cell fractions of similar sedimentation velocity also secreted a soluble MLR suppressor into culture supernatants. Although inhibitory of MLR, spleen cells of rapid sedimentation velocity did not suppress responses to T cell mitogens. In marked contrast with the effects of spleen cells, large 4-day-alloantigen-primed lymph node cells had no suppressive activity in MLR. MLR amplifier cells of uncertain derivation were found in fractions of medium sedimentation velocity from both spleens and lymph nodes. Fractionation of alloantigen-primed lymph node cell suspensions did reveal, however, a subpopulation of small cells with MLR suppressor acitivty which was unaffected by treatment with anti-Thy-1 serum and complement. The data thus indicate that large alloantigen-activated lymphocytes are not intrinsically suppressive nor are cells which suppress MLR necessarily large. We consequently conclude that regulation of MLR responses by alloantigen-primed lymphocytes involves a complex interaction between distinct functional subpopulations of cells which are separable both by physical and biologic properties.     

Suppression of cytolytic T-cell activity by staphylococcal enterotoxin B-induced suppressor cells: Role of interleukin 2

We have previously shown that staphylococcal enterotoxin B (SEB) is a potent inducer of suppressor T cells which function to inhibit antibody production in vitro. In the present paper we extend these studies and show that the SEB-induced suppressor cells also inhibit the development of cytotoxic lymphocytes in mixed-lymphocyte reaction (MLR) cultures. Since further analysis also showed that the level of interleukin 2 (IL-2) in cultures of SEB-primed cells was significantly reduced, experiments were carried out to determine the role of IL-2 in the inhibition of cytotoxic cell activity. Attempts to neutralize the suppression by supplementing MLR cocultures with delectinated supernatants from concanavalin A (Con A)-stimulated rat splenocytes were not successful. In addition, MLR cocultures supplemented on Day 0 with 50 units of affinity-purified IL-2 were also suppressed. Further analysis showed that the IL-2 activity in the supplemented MLR cocultures containing suppressor cells were significantly reduced by Day 3. However, repeated supplementation of the MLR cocultures with exogenous IL-2 was successful in achieving (and maintaining) “normal” levels of IL-2. The cytotoxic cell activity in these MLR cocultures remained suppressed. These results suggest that the inhibition of cytotoxic cell activity by SEB-induced suppressor cells is independent of IL-2 levels in the MLR coculture.     

Reversal of macrophage-augmented MLR reactivity by tumor-induced splenic suppressor T cells and their soluble factor(s)

Augmenting concentrations of macrophages or their supernatants failed to reverse T-cell hyporeactivity in tumor-bearing mice (TBM). Serial passaging over nylon wool columns depleted TBM spleen cells of a mildly adherent tumor-induced suppressor cell and restored mixed lymphocyte reaction (MLR) reactivity to the purified TBM T-cell population. The tumor-induced suppressor cell was extensively plated to remove macrophages and characterized as a T cell by its anti-Thy 1 serum sensitivity. This suppressor T cell, when added to normal T cells, abrogated all enhancing effects caused by addition of macrophages. Suppressor T-cell inhibition was non-contact dependent, since suppressor T-cell supernatants inhibited MLR activity in T cells treated with enhancing concentrations of macrophage supernatants. Thus it appears that tumor-induced T-cell debilitation is a reversible phenomenon, mediated not by macrophages but by soluble factor(s) from a nonphagocytic, mildly adherent, suppressor T cell.     

Biological expressions of lymphocyte activation. IV. Concanavalin A-activated suppressor cells in mouse mixed lymphocyte reactions.

Thymus-derived lymphocytes (T cells) from mouse spleen, activated in vitro or in vivo with concanavalin A (Con A), suppress proliferative responses of syngenic lymphocytes in mixed lymphocyte reactions (MLR). Replication in vitro was not required for expression of suppressor activity by Con A-activated cells and was blocked in MLR by treating suppressor cells with mitomycin C or irradiation. Kinetics of MLR responses and viability of cultures were not altered by addition of activated suppressor cells. The data are consistent with a direct inhibitory effect of suppressor T cells on antigen-induced DNA replication. These observations extend a model previously described for regulation of antibody synthesis by Con A-activated T cells to control of cell-mediated immune responses. This model should be particularly useful in further definition of regulatory T cell subpopulations, and in investigation of interactions and relationships between such populations.     

Fate of H2-activated T lymphocytes in syngeneic hosts. III. Differentiation into long-lived recirculating memory cells.

Memory to H2 determinants was studied with an adoptive transfer system using a population of H2-activated blast T cells (T.TDL) obtained from thoracic duct lymph of irradiated F₁ hybrid mice injected with parental strain T cells. CBA T.TDL activated either to DBA/2 or C57BL determinants were transferred to syngeneic “B” mice. Thoracic duct lymphocytes (TDL) were obtained from the recipients 4–6 weeks later and tested for their capacity to produce (a) a graft-versus-host (GVH) reaction, (b) a mixed lymphocyte reaction (MLR) (measured by an in vivo technique) and (c) allograft rejection (suppression of the growth of allogeneic tumour cells in vivo). Control experiments involved testing the function of TDL obtained from “B” mice preinjected with TDL or no cells.TDL from “B” mice injected with TDL (passaged TDL) gave strong MLR and GVH reactions to both DBA/2 and C57BL determinants. Passaged T.TDL activated to C57BL antigens gave intermediate MLR and GVH reactions to the specific (C57BL) determinants but only very low responses to third-party (DBA/2) determinants; reciprocal results were obtained with passaged T.TDL activated to DBA/2 determinants. TDL from “B” mice given no cells failed to respond to either set of determinants.Since the responses by the passaged T.TDL did not exceed those by passaged TDL there was no evidence that adoptive transfer of T.TDL had conferred to the recipients a state of memory to either MLR or GVH determinants. Adoptive transfer did, however, lead to qualitative changes in the properties of T.TDL since, before transfer, they were unable to evoke GVH reactions or produce an MLR of normal kinetics.Passaged T.TDL were far superior to passaged TDL at suppressing the growth of allogeneic tumour cells. The protection was specific since protection against DBA/2 tumour cells was, cell for cell, 5–10 fold more effective with passaged T.TDL activated to DBA/2 determinants than with cells activated to C57BL determinants. No protection was observed with cells treated with anti-θ serum. The protective cells appeared to be precursors of effector cells rather than effector cells per se since they failed to lyse the tumour cells in vitro. These data suggest therefore that the descendants of T.TDL which survived after transfer to “B” mice were highly enriched in long-lived recirculating T lymphocytes reactive to determinants expressed by specific tumour allografts.     

Suppression of mixed lymphocyte reactions by alloantigen-activated spleen-localizing thymocytes.

Heavily irradiated BALB/c and C57BL/6 mice were injected intravenously with BALB/c thymocytes. At varying times thereafter spleen and lymph node cell suspensions from these animals were treated with mitomycin C and added as regulator populations to mixed lymphocyte reactions (MLR) with syngeneic responder cells. Alloantigen-activated spleen-localizing thymocytes suppressed MLR responses 40 to 95%. Suppressor activitity, manifested as a quantitative reduction in peak proliferative responses, was maximal 4 days after cell transfer. Antigenic specificity for the stimulator cell strain in MLR was not demonstrated. The effect of lymph nodelocalizing thymocytes as regulators in MLR was variable, but in most experiments these cells slightly enhanced responses. We conclude that splenic localization is an intrinsic property of the thymocyte subpopulation capable of suppressing MLR responses, and that the suppressor activity of this subpopulation is substantially enhanced by activation in allogeneic hosts.     

Suppression of cell-mediated immune responses after total lymphoid irradiation (TLI). I. Characterization of suppressor cells of the mixed lymphocyte reaction

Total lymphoid irradiation (TLI) was administered to (BALB/c X C57BL/6)F1 mice in eight daily doses of 200 rad (total 1600 rad). Spleen cells isolated from mice after treatment with TLI do not respond to alloantigens in vitro in a one-way mixed lymphocyte reaction (MLR), but normal reactivity recovers after approximately 2 mo. Radioresistant, antigen-nonspecific suppressor cells are documented in the spleens of TLI-treated mice immediately after radiotherapy, but suppressive capacity gradually disappears within 30 days. After TLI, the spleen is repopulated with large cells, the proportion of which is greatest at a time when theta-bearing cells are still depleted. Radioresistant suppression is mediated predominantly by the large cell subset and is thymus independent. Suppressor function can be abolished by lethal physicochemical procedures including formaldehyde fixation, multiple freeze-thawing, and heating to 56 degrees C, and it cannot be conferred by supernatants of TLI-suppressed MLR suspensions. Suppression cannot be overcome by adding various cell factors including T cell growth factor (TCGF) and lymphocyte-activating factor (LAF), nor is it affected by a prostaglandin inhibitor. Equally potent radioresistant suppressive activity is documented by co-culturing cells derived from other sources enriched in large, immature hematopoietic cells, including fetal liver cells and bone marrow cells obtained from normal and congenitally athymic mice. The presence of a large cell population and MLR suppressor function is also documented in the spleens of mice treated with single dose or fractionated doses of lethal whole body irradiation, followed by reconstitution with bone marrow cells obtained from normal mice. The data suggest that MLR suppressor cells, which are large, immature and predominantly radioresistant, can be induced after a short and well-tolerated TLI regimen.     

In vitro propagation and cloning of murine natural suppressor (NS) cells

During a short period of time after birth or after radiotherapy, the spleens of neonatal and adult TLI-treated mice contain suppressor cells of the mixed leukocyte reaction (MLR) and of graft-vs-host disease. The present report shows that the MLR suppressive activity of spleen cells from TLI-treated adult BALB/c mice can be maintained in long-term tissue culture by using conditioned medium. The suppressor cells can be cloned by limiting dilution, and reproducibly inhibit the [3H]TdR incorporation in the MLR at responder-to-suppressor cell ratios of 50:1. There is no antigen specificity or H-2 haplo-type restriction of the MLR suppression. The suppressor cells do not inhibit [3H]TdR per se, because no inhibition was observed in co-culture experiments with the EL4 tumor line or the IL 2-dependent HT-2 cell line. By using immunofluorescent staining techniques, the surface phenotype of the suppressor cells was found to be similar to that reported previously for cloned NK cells (Thy-1+, Lyt-1-, Lyt-2-, Ig-, Ia-, MAC-1-, asialo-GM1+). However, the suppressor lines showed no natural killer activity when YAC-1 target cells were used. Thus, the suppressor lines have been termed "natural suppressor" cells to indicate surface marker similarities to NK cells, both in vivo and in vitro, but different effector functions.     

Effect of polysaccharides from Ganoderma applanatum on immune responses. I. Enhancing effect on the induction of delayed hypersensitivity in mice.

Prior intraperitoneal (i.p.) or oral administration of the polysaccharide preparation from a kind of mushroom, Ganoderma applanatum (Pers.) Pat. of Basidiomycetes, exerted an enhancing effect on the induction of delayed hypersensitivity (DH) to protein antigen as measured by the footpad reaction (FPR), and expanded the size of T cell memory for the IgG antibody response. One of the active principles was partially purified and found to be associated with a polysaccharide-rich fraction. The induction of DH was enhanced by treatment with an appropriate dose of the mushroom extract, whereas increasing the dose resulted in almost complete loss of the enhancing activity. The mechanism for the enhancing effect of the mushroom extract on the induction of DH was explored by the adoptive cell transfer technique. Although an i.p. injection of methylated bacterial α-amylase (M-BαA) in incomplete Freund's adjuvant (IFA) has been found to generate in the spleen the antigen-specific suppressor T cells capable of inhibiting the induction of DH 5 days after immunization, the same treatment of mice given prior injections of the mushroom extract did not raise the suppressor cell activity, but transfer of these spleen cells (6 × 10⁷) into syngeneic recipient mice which had been primed with a subcutaneous (s.c.) injection of M-BαA in complete Freund's adjuvant (CFA) resulted in substantial amplification of the expression of DH. The absence of effector T cells for DH in the transferred spleen cells was confirmed by the failure to transfer DH into cyclophosphamide (CY)-treated mice with the amplifying cells. The amplifying activity was antigen-nonspecific and mediated by cells sensitive to treatment with anti-θ antiserum plus complement. Therefore, the nonspecific enhancing effect of the mushroom extract could not be explained by the possibility that pretreatment with the extract eliminated the antigen-specific suppressor T cells. Other adoptive cell transfer experiments revealed that nylon wool-passed cells from mice unprimed but treated with the mushroom extract were able to exert an enhancing activity on the expression of effector T cells in DH. The results indicate that the treatment with an appropriate dose of the extract enhances the induction of DH by activation of the nonspecific amplifier T cells.     

Discrimination of suppressor T cells of humoral and cell-mediated immunity by anti-Ly and anti-Ia sera.

Evidence is presented which demonstrates that the T lymphocytes which suppress humoral and cell-mediated immunity in CBA/H mice differ in the cell surface structures they express. The suppressor T cells of delayed-type hypersensitivity are Ly-1⁺, Ly-2^? and Ia^?, whereas the suppressor T cells of antibody formation are Ly-1^?, Ly-2⁺ and Ia⁺.     

Chronic alcohol consumption enhances myeloid-derived suppressor cells in B16BL6 melanoma-bearing mice

We previously found that chronic alcohol consumption decreases the survival of mice bearing subcutaneous B16BL6 melanoma. The underlying mechanism is still not completely understood. Antitumor T cell immune responses are important to inhibiting tumor progression and extending survival. Therefore, we examined the effects of chronic alcohol consumption on the functionality and regulation of these cells in C57BL/6 mice that chronically consumed 20% (w/v) alcohol and subsequently were inoculated subcutaneously with B16BL6 melanoma cells. Chronic alcohol consumption inhibited melanoma-induced memory T cell expansion and accelerated the decay of interferon (IFN)-γ producing T cells in the tumor-bearing mice. Foxp3⁺CD4⁺CD25⁺ regulatory T cells were not affected; however, the percentage of myeloid-derived suppressor cells (MDSC) was significantly increased in the peripheral blood and spleen. T cell proliferation as determined by carboxyfluorescein succinimidyl ester labeling experiments in vitro was inhibited by alcohol consumption relative to control water-drinking melanoma-bearing mice. Collectively, these data show that chronic alcohol consumption inhibits proliferation of memory T cells, accelerates the decay of IFN-γ producing CD8⁺ T cells, and increases MDSC, all of which could be associated with melanoma progression and reduced survival.     

Erratum to: Chronic alcohol consumption enhances myeloid-derived suppressor cells in B16BL6 melanoma-bearing mice

We previously found that chronic alcohol consumption decreases the survival of mice bearing subcutaneous B16BL6 melanoma. The underlying mechanism is still not completely understood. Antitumor T cell immune responses are important to inhibiting tumor progression and extending survival. Therefore, we examined the effects of chronic alcohol consumption on the functionality and regulation of these cells in C57BL/6 mice that chronically consumed 20% (w/v) alcohol and subsequently were inoculated subcutaneously with B16BL6 melanoma cells. Chronic alcohol consumption inhibited melanoma-induced memory T cell expansion and accelerated the decay of interferon (IFN)-γ producing T cells in the tumor-bearing mice. Foxp3⁺CD4⁺CD25⁺ regulatory T cells were not affected; however, the percentage of myeloid-derived suppressor cells (MDSC) was significantly increased in the peripheral blood and spleen. T cell proliferation as determined by carboxyfluorescein succinimidyl ester labeling experiments in vitro was inhibited by alcohol consumption relative to control water-drinking melanoma-bearing mice. Collectively, these data show that chronic alcohol consumption inhibits proliferation of memory T cells, accelerates the decay of IFN-γ producing CD8⁺ T cells, and increases MDSC, all of which could be associated with melanoma progression and reduced survival.     

Un vivo depletion of murine CD8 positive T cells impairs survival during infection with a highly virulent strain ofCryptococcus neoformans

Cell-mediated immunity plays an important but incompletely understood role in host defense againstCryptococcus neoformans. Because of their multiple capacities as cytokine-secreting cells, cytotoxic cells, and antigen-specific suppressor cells, CD8 positive T lymphocytes could potentially either enhance or impair host defense againstC. neoformans. To determine whether CD8 T cells enhance or inhibit host defence during an infection with a highly virulent strain ofC. neoformans, we examined the effect of in vivo CD8 cell depletion on suNival and on the number of organisms in mice infected by either the intratracheal or intravenous routes. Adequacy of depletion was confirmed both phenotypically and functionally. Regardless of the route of infection, we found that survival of mice depleted of CD8 T cells was significantly reduced compared to undepleted mice. Surprisingly, however, CD8 depletion did not alter organism burden measured by quantitative CFU assay in mice infected by either route. These data demonstrate that CD8 positive T cells participate in the immune response to a highly virulent strain ofC. neoformans. By contrast to minimally virulent isolates that do not cause a life threatening infection, the immune response to a highly virulent isolate does not alter the burden of organisms, but does enhance host defense as it is necessary for the optimal survival of infected mice.Abbreviations ³H-TdR ³H-thmidine - CFU colony forming units - FITC Fluorescein isothiocyanate - MLR mixed lymphocyte reaction - PBS phosphate buffered saline     

Induction by an immunogenic immunomodulating agent of nonspecific T cell suppression of lymphocyte responsiveness in MLR but not of antibody production

Summary Spleen cells derived from BALB/c mice that had been repeatedly immunized with the methanol extraction residue (MER) fraction of tubercle bacilli exhibited a depressed capacity to act as responder cells in allogeneic and syngeneic mixed lymphocyte reactions (MLR). Previously reported studies revealed that such spleen cells are also defective in the in vitro generation of antibodies. In order to determine the nature of the cells responsible for the depressed MLR reactivity, purified populations of splenic macrophages, B lymphocytes, T lymphocytes originating from normal and from MER-immunized mice, and cell culture supernatants were added to MLR mixtures consisting of normal mouse splenocytes. Macrophages originating from MER-immunized mice and their culture supernatants exerted a significantly higher suppressive effect on MLR than that of corresponding preparation from normal mice. Splenic T cells originating from MER-immunized mice and their supernatants also significantly suppressed the MLR response. However, the same T cell populations that were inhibitory in MLR failed to suppress the in vitro generation of antibodies against sheep red blood cells in the presence of either MER or 2-mercaptoethanol. These and previously reported findings indicate that a nonspecific immunomodulating agent, MER, can, under certain conditions of treatment, elicit the induction of nonspecific suppressor T cells for MLR but not for antibody production, and, accordingly, can inhibit cellular and humoral immunological responsiveness by different mechanisms.     

Marker and function analysis of natural killer and alloreactive T cells during early stages of dimethylbenzanthracene carcinogenesis. The immunity system during the precancer period

The effect of the chemical carcinogen dimethylbenzanthracene (DMBA) on cellular immunity was studied at a 6-mg dose which induces adenocarcinomas and adenoacanthomas in more than 70% of BalB/c mice within 1 year after administration. DMBA caused a significant reduction of splenic natural killer (NK) activity and responsiveness to alloantigens in mixed lymphocyte reactions (MLR). These activities decreased soon after the carcinogen treatment and remained suppressed during the entire tumor induction period. There was a linear correlation between the reduction in NK activity and a selective decrease in the number of asialo GM1 positive cells in the spleen. However, cell sorting experiments using the flow cytometer have shown that the lytic activity per cell of asialo GM-1 positive cells in untreated mice and in DMBA-treated ones was similar. There was no correlation between the suppressed response of the T cells in MLR and the percentage of T cell subpopulations residing in the spleen of the DMBA-treated mice. The decrease in the number of NK cells and the reduced MLR activity in the spleen occurred simultaneously with a decrease in the potential of bone marrow precursor cells to reconstitute NK and MLR activity in the spleen of lethally irradiated mice. These results indicate that the carcinogen DMBA effects the immune system at various levels and either eliminates or inactivates precursor cells as well as mature lymphoid cells.     

Defective activation of T suppressor cell function in nonobese diabetic mice. Potential relation to cytokine deficiencies

Nonobese diabetic (NOD) is an inbred mouse strain susceptible to development of T cell-mediated autoimmune diabetes. The strain is characterized by high percentages of T lymphocytes in lymphoid organs. The syngeneic mixed lymphocyte reaction (SMLR), a T cell response to self MHC class II Ag, is reportedly involved in the generation of a number of immunoregulatory cells, including suppressor inducers. A severely depressed SMLR characteristic of certain other autoimmune strains was found in NOD but not in nonautoimmune SWR/Bm mice. Moreover, IL-2 produced by NOD T cells at day 6 in an SMLR was at least one hundredfold reduced compared with SWR, and NOD T cells harvested from an SMLR at day 6 were functionally defective when tested for ability to induce suppression of an allogeneic MLR. However, functionally competent suppressor T cells were generated in NOD splenic leukocyte cultures in response to Con A, and IL-2 release from these was equivalent to that released by Con A-stimulated SWR splenocytes. A deficiency in cytokine release was not limited to IL-2, because peritoneal exudate cells from NOD exhibited a greatly diminished sensitivity to LPS-stimulated IL-1 release in comparison to SWR mice. IL-2 supplementation both in vitro and in vivo restored the ability of NOD T cells to respond in a SMLR, with production of cells capable of inducing suppression. Like SMLR-activated T cells from untreated SWR controls, SMLR blasts from IL-2-treated NOD mice were enriched for the L3T4 phenotype. IL-1 supplementation in vitro resulted in partial restoration of T suppressor activation in a SMLR. The depressed SMLR exhibited by NOD mice was apparently a stimulator cell dysfunction, because NOD stimulator cells failed to activate T cells from (SWR x NOD)F1 mice, whereas stimulators from SWR or F1 mice were capable of doing so. Collectively, these results suggest a defect in suppressor cell activation rather than an absence of this immunoregulatory cell population.     

Suppressor T lymphocyte induction by a factor released from cultured blastocysts

For the analysis of immunologic escape mechanisms of embryos during the implantation period in mice, the effects of culture supernatant of blastocysts on in vitro responsiveness to alloantigen of mice was investigated. Blastocyst-cultured conditioned medium was prepared by culturing late blastocysts of outbred ICR mice for 5 days. The addition of culture supernatant containing four or eight blastocysts to allogeneic mixed lymphocyte culture inhibited both the MLR responses and the generation of cytotoxic T lymphocytes (CTL). Preincubation of the culture supernatant with lymphocytes syngeneic to the responder cells of MLR induced potent suppressor cell activity in the MLR. The supernatant did not inhibit the activity of CTL at the effector phase, but preinduced suppressor cells obtained by incubation of splenocytes with the supernatant showed almost complete suppression of CTL activity at the effector phase. Both of the suppressor cells, active on MLR and at the generation phase of CTL as well as active at the effector phase, had a surface phenotype of Thy-1+ and Ig-. The suppressive material could be extracted from the eight-cell stage of fertilized ova or blastocysts but not from unfertilized ova, indicating that the production of the factor(s) is dependent on the stages of early embryogenesis. These results suggest that the active induction of suppressor T lymphocytes by the factor(s) released from implanted embryos is one of the protective mechanisms from maternal immunologic attack.     

Possible role of neuraminidase in activated T cells in the recognition of allogeneic Ia

In a primary MLR, predominant stimulators in spleen cells are adherent cells and not B cells, although B cells are one of the cell types expressing a large amount of Ia molecules. Our previous experiments showed that T cells treated with neuraminidase (Nase) responded to an allogeneic Ia on B cells. In our experiments, the relationship between the responsiveness to the allogeneic Ia molecules on B cells and Nase activity of T cells was examined. The results showed that T cells increased in Nase activity with the acquisition of the reactivity to Ia on B cells. T cells from normal mice increased in Nase activity after the incubation for 3 days or more in MLR, and these T cells responded to allogeneic Ia on B cells. However, T cells from mice genetically deficient in Nase responded poorly to the Ia on allogeneic B cells even after the incubation in MLR for 3 days. T cells incubated for 3 days in MLR decreased in electrophoretic mobility, indicating the decrease of net negative charge of the cells, and increased in their binding of peanut agglutinin which has been reported to bind to galactosyl residues exposed on T cell surface by removing sialic acids. These results suggest that Nase in T cells was activated by the cultivation in MLR for 3 days, and sialic acids of some molecules on T cell surface were removed by the enzyme and, in turn, T cells acquired the responsiveness to allogeneic B cells in a secondary MLR. Thus, Nase was suggested to play a regulatory role in the recognition of Ia molecules in T cells.     

Regulatory mechanisms in cell-mediated immune responses. II. Comparison of culture-induced and alloantigen-induced suppressor cells in MLR and CML.

Two antigen-nonspecific T cell-dependent suppressor systems were compared for their effects upon CML and MLR. Suppressor cells generated by an in vitro culture of spleen cells were compared with suppressor cells generated by in vivo priming with alloantigen. Culture-induced suppressor cells were themselves unable to respond in CML or MLR; were able to suppress actively the CML and MLR responses of untreated responding cells; were mitomycin-sensitive; and, produced no easily demonstrable suppressive supernatant. Alloantigen-primed cells were able to respond in CML and LR; could suppress proliferation in MLR, but were able to suppress CML only after mitomycin treatment; and, produced suppressive supernatants active in suppressing both CML and MLR. In addition to cataloging the differences and similarities between these suppressor populations, the data have been employed to analyze the mechanisms by which suppression occurs in CML and MLR.