Lipopolysaccharide-induced suppression of the primary immune response to a thymus-dependent antigen.

The immune response to a thymus-dependent antigen was depressed in vivo and in vitro in spleen cells from mice injected with LPS i.p. a few days before challenge with the antigen. Spleen cells from LPS-injected mice could, however, respond with increase DNA synthesis after activation with polyclonal B and T cell activators in vitro. The LPS-activated spleen cells could actively suppress normal cells in their response to the antigen sheep red blood cells. The suppressor cells contained in the LPS-activated spleens were most likely B lymphocytes, and the possible mechanism for their inhibitory function is discussed.     

Suppressor T cells and suppressor macrophages induced by Corynebacterium parvum

Corynebacterium parvum, injected intravenously into C57B1/6 mice (H-2^b) previously alloimmunized with P815 (H-2^d) mastocytoma cells, generated splenic suppressor cells that inhibited the development of primary cytotoxic lymphocytes in vitro. These suppressor cells differed from those generated by intravenous C. parvum injection of naive C57B1/6 mice. The former suppressor cells were effectively induced by administration of 700 μg of C. parvum whereas the latter suppressor cells were dependent upon higher doses (1400 μg) of adjuvant for their activation. Furthermore, suppressor cells generated in alloimmunized mice could only suppress C57B1/6 anti-P815 in vitro cytotoxic responses whereas suppressor cells generated in naive mice could suppress C57B1/6 anti-CBA (H-2^k) responses as well. Suppressor cells were not H-2 restricted in their action. Fractionation of spleens from alloimmunized, C. parvum-treated mice revealed the presence of suppressor T cells and suppressor macrophages. We were unable, however, to determine which cell was responsible for “antigen specificity” of suppression since the fractionation procedures seemed to trigger both suppressor cell types prior to adding them to the primary culture.     

Immunologic significance of nonspecific suppressor cells in spleens of tumor-bearing mice.

Spleen cells from mice bearing a progressively growing syngeneic tumor failed to respond to stimulation with mitogens in vitro. This lack of reactivity was due to the presence of nylon wool-adherent cells in the population that could inhibit the mitogen response of normal lymphocytes. Paradoxically, at times when strong suppressor cell activity could be detected in tumor-bearing mice, the animals responded normally to in vivo immunization with sheep erythrocytes and allogeneic tumors, and to in vitro sensitization with allogeneic tumor cells. Regression of a highly antigenic syngeneic tumor also was unaffected by the presence of these suppressor cells. Thus, the occurrence of nonspecific suppressor cells in the spleens of tumor-bearing mice did not influence the overall immunologic competence of these animals.     

In vivo and in vitro effects of monoclonal antibody to Ly antigens on immunity to infection

Injection of CBA mice with Brucella abortus strain 19 leads to chronic infection during which both cell-mediated immunity (delayed hypersensitivity and macrophage activation) and antibody production occur. Protection was efficiently transferred to naive mice using spleen cells from mice infected 5 or 12 weeks earlier. Selective lysis in vitro of these cells by antibody to cell surface antigens showed that Thy-1⁺ Ly-1⁺2⁺ T lymphocytes were required for transfer. Treatment with anti-Ia serum neither suppressed nor enhanced adoptive transfer. Thus Ia⁺ B lymphocytes were not required, and Ia⁺ suppressor T cells were not active in the response. Three injections per week of anti-Ly-1 monoclonal antibody beginning 5 days before infection led to a 10-fold increase in bacterial numbers 25 days after infection when acquired immunity was well established in untreated mice. The delayed hypersensitivity response was unaffected. In addition cells from these in vivo treated mice were unable to transfer resistance. Beginning the treatment on the day of infection abolished the IgG antibody response without affecting bacterial numbers. The studies emphasize the unique role of Ly-1⁺2⁺ T cells in immunity to Brucella and indicate the usefulness of these techniques in dissecting out those components of the immune response which contribute to recovery from infection.     

Bcl10 is an essential regulator for A20 gene expression

A20, a tumor suppressor in several types of lymphomas, has been suggested to be an nuclear factor kappa B (NF-κB) target gene; conversely, the deubiquitylation activity of A20 is required for inhibition of Bcl10-mediated activation of NF-κB. BCL10, which is activated in a recurrent chromosomal translocation that causes human mucosa-associated lymphoid tissue lymphomas, is known to be essential for NF-κB activation in B cells. We report here that Bcl10 upregulates endogenous A20 gene expression in B lymphocytes upon B-cell receptor engagement of anti-IgM. Transient transfection assays in HEK 293 cells indicate that Bcl10 can activate the A20 promoter, which contains NF-κB-binding sites. We also construct a theoretical structure of mouse Bcl10 and analyze the structure by molecular modeling and molecular dynamics simulation. Lastly, we found that marginal zone B cells from BCL10-transgenic mice proliferate more readily than wild-type B cells, whereas, surprisingly, the transgenic follicular B cells from these mice proliferate comparably to wild-type cells. Collectively, our results indicate that Bcl10 is an essential regulator of A20 gene expression and B-cell proliferation mediated by B-cell receptor signaling.     

Mechanism of histamine-induced inhibition of lymphocyte response to mitogens in mice

Histamine induced, in mice, an inhibition of lymphocyte response to PHA and LPS, at molar concentrations ranging from 10^?3 to 10^?9M. This inhibition occurs as a specific interaction between histamine and T lymphocytes bearing H2-type receptors for this hormone (H + cells) and Ly 2 membrane antigens. Two features of the suppressive activity of this T-cell subpopulation were observed: (i) when histamine is added at the beginning of the culture period with PHA or LPS, it activates the suppressor activity of H + cells which act on the lymphocyte population responding to PHA and LPS; (ii) preincubation of spleen lymphocytes with histamine for 24 hr induces suppressor cells which inhibit the response to PHA, but not to LPS, of syngeneic lymphocytes in a coculture system, and which are radiosensitive. The role of PHA as a second stimulus of histamine-induced suppressor cells, and the relation between these cells and PHA or Con A-induced suppressor cells, are discussed.     

Suppressor T cells in thymus-reconstituted nude mice: regulation of mitogen-induced transformation

A population of glass-wool-adherent splenic cells which could suppress the response of other spleen cell populations to T-cell mitogens was isolated from thymus-reconstituted nude mice. Such adherent cells were characterized as sensitive to anti-Thy 1.2 and complement treatment. Glass-wool-adherent cells from athymic mice do not have suppressor activity to self or normal littermate NAC; however, these mice possess precursor suppressor cells as demonstrated by isolation of glass-wool-adherent T regulatory cells in thymus-grafted nude mice. Such cells are generated in either freshly obtained or in vitro cultured thymus. Evidence for suppressor T cells of host genotype was supported by their sensitivity to host-specific anti-Thy serum treatment as well as their generation in alymphoid thymus grafts. Prior anti-Thy 1.2 treatment of GAC partially removed the suppressor activity: however, macrophages and B lymphocytes were shown not to be secondary regulatory cells or suppressor mediators, thus mature T lymphocytes with low amounts of Thy 1.2 antigen may be responsible for this residual suppression. Further characterization of GAC indicates that active cell growth is required for their regulatory function, as irradiation removed the suppressor activity. This report provides evidence for the presence of a T-lymphocyte subpopulation which has a regulatory function and requires a thymus in the generation of these cells.     

Lymphocyte and macrophage adenyl cyclase activity in animals with enhanced cell-mediated resistance to infection and tumors.

As cyclic AMP has been associated with the inhibition of lymphocyte cytotoxicity, studies were performed to investigate adenyl cyclase activity in lymphocytes and macrophages of Toxoplasma-infected mice in which the efferent limb of the cell-mediated immune response had previously been found to be activated. In peritoneal or splenic lymphocytes from $\text{Balb}\text{c}$ mice chronically infected with Toxoplasma in which growth of an isogeneic bladder tumor was found to be inhibited, adenyl cyclase activity was significantly less than in lymphocytes from uninfected control mice. Stimulation by prostaglandin E₁ or NaF in vitro led to higher levels of adenyl cyclase activity in lymphocytes from unifected animals than in cells from Toxoplasma-infected animals. Similar observations were made with peritoneal macrophages from Toxoplasma-infected and uninfected mice. Lower levels of adenyl cyclase activity were also found in lymphocytes from tumor-bearing mice than in lymphocytes from nontumor-bearing controls. These data suggest that production of cyclic AMP by lymphocytes is inhibited with activation of certain cell-mediated immune functions.     

Adjuvant-induced nonspecific supressor cells: in vitro and in vivo studies

The in vitro mitogen responses of spleen cells from mice injected ip with the nonantigenic adjuvant, Al(OH)₃, are markedly depressed. This depressed reactivity was found to be mediated by a population of nylon wool adherent, Fc-receptor-bearing suppressor cells. Suppressor cells were detected only in the spleens of the adjuvant-treated mice, as the response of lymph node cells to mitogenic stimulation in vitro was found comparable to that of normal controls. Moreover, elevated levels of suppressive activity could be detected in sera of Al(OH)₃-treated mice during the first week after adjuvant administration, which, however, did not correlate with either the long-lasting presence of suppressor cells or the in vivo normal immune response of the adjuvant-treated animals. Studies designed to test the effect of suppressor cells on the generation of splenic PFC in vivo revealed that both the direct and indirect PFC responses against SRBC inoculated iv were enhanced rather than suppressed, as compared to those of the normal controls. Furthermore, the level of cytotoxic lymphocytes generated in spleens of Al(OH)₃-treated mice immunized with allogeneic tumor cells was equal to or higher than that of the normal controls. In view of the present results, we feel that the concept that splenic, nonspecific suppressor cells (macrophages) are immunosuppressive in vivo as well as the in vivo relevance of in vitro findings should be carefully reevaluated.     

In vitro immune blastogenesis during contact sensitivity in tumor-bearing mice: I. Description of progressive impairment and demonstration of splenic suppressor cells

T-cell responsiveness was measured by the DNA response of disassociated spleen and lymph node cells when exposed to antigen in vitro. Sensitized splenic lymphocytes from fibrosarcoma-bearing mice immunized with 2,4-dinitro-1,5-difluorobenzene (DN2FB) demonstrated a progressive decrease in T-cell responsiveness to the haptenprotein conjugate DNP-BSA. Hyporesponsiveness to the dinitrophenylated-protein conjugate appeared in the spleens but not lymph nodes of tumorous animals. Normal host lymph node cells (LNC) responded strongly 24 to 48 h after sensitization and subsequently declined with a corresponding increase in responsiveness in the spleen. Tumor-bearing hosts (TBH) had similar LNC kinetics during immunization, however, spleen cells were significantly suppressed when compared to normal BALB/c mice sensitization kinetics. Spleen cells from TBH were also capable of suppressing the in vitro response of normal primed lymphocytes to DNP-BSA when admixed. Results from these experiments suggest that in vitro measurement of contact sensitivity was affected by suppressor cells/products existing in the spleens but not lymph nodes of fibrosarcoma-bearing mice.     

Suppression of lymphokine production: II. Macrophage-dependent inhibition of production of macrophage activating factor

The ability of different populations of macrophages to affect the production of macrophage activating factor (MAF) by stimulated T lymphocytes was investigated. We found that activated macrophages, infiltrating MSV-induced regressing tumors or macrophages recovered from the peritoneum of mice injected with Corynebacterium parvum, were able to actively suppress the production of MAF. MAF production by antigen-stimulated MSV-immune or -alloimmune spleen cells and by normal spleen cells stimulated by Con A was susceptible to macrophage-dependent suppression to a similar extent. In contrast, resident macrophages or those elicited by light mineral oil or proteose-peptone did not affect MAF production. While suppressor macrophages added at the time of the lymphocyte stimulation inhibited MAF production, the same cells added 4–6 hr after stimulation were ineffective. Therefore, it seems that the macrophages suppressed the early events of lymphocyte activation leading to MAF production. Suppressor macrophages, by inhibiting MAF production, may limit the expansion of the cytotoxic activity. This regulation of macrophage functions, mediated by the effects of suppressor macrophages on T lymphocytes, could be responsible for an insufficient antitumor cytotoxic response by macrophages.     

Selective impairment of B cell function by Neisseria meningitidis

Spleen cells from CBA/J mice infected with Neisseria meningitidis displayed depressed in vitro plaque-forming cell (PFC) responses to T-dependent (sheep red blood cell; SRBC) and T-independent (TNP-LPS, TNP-Ficoll) antigens. The inhibition was observed over a wide range of antigen concentrations. The decreased responsiveness of splenocytes from infected mice was due to a selective impairment of B-cell function since helper-T-cell activity was intact in infected mice as shown by the ability of T-enriched lymphocytes to cooperate with normal B-enriched lymphocytes in the generation of an anti-SRBC response, accessory macrophage function was preserved since adherent spleen cells from bacteria-injected mice were shown to produce normal or increased levels of IL-1 and were able to cooperate with normal non-adherent spleen cells in the generation of PFC against SRBC. Addition of peritoneal cells from normal animals or extraneous IL-1 both failed to restore normal PFC responses in cultures of splenocytes from infected mice. Finally, B-enriched lymphocytes from infected mice produced poor anti-SRBC responses when cultured with either Con A supernatant or T-enriched lymphocytes from normal or infected mice. Cell-mixing experiments failed to detect the presence of suppressor cells in cultures of unfractionated spleen cells or B-enriched lymphocytes from infected mice. Therefore, the immunological unresponsiveness associated with a Neisseria meningitidis infection was attributed to a meningococcus-induced defect(s) in B-cell function. In vivo polyclonal B-cell activation leading to clonal exhaustion did not play a major role in the depression of humoral responses since meningococcal infection induced little or no polyclonal Ig secretion.     

Depressive effect of silica particles on F1 hybrid anti-parent cell-mediated lympholysis induced in vitro.

The role of macrophage-like cells in the in vitro generation of specific B6D2F₁ hybrid anti-parental B6 cytotoxic T lymphocytes (CTL) was investigated by means of silica particles (SIL). Depression of this cell-mediated response resulted from the addition of 12.5 or 25 μg of SIL to mixed F₁/parent spleen cell cultuers, and full abrogation resulted from the addition of 125 or 250 μg of SIL. The treatment was effective if applied during the first 48 hr of culture. When treatment was delayed, responsiveness did not decline nor did the lytic function of mature CTL exposed to SIL. Moreover, no depression of the anti-allogeneic cell mediated response resulted from the addition of 250 or 500 μg of SIL to mixed F₁/allogeneic instead of F₁/parent spleen cell cultures. Abrogation of the F₁ hybrid anti-parent response was attributed to SIL-induced impairment of an accessory function presumably exerted by macrophage-like cells during the early phases of responder T cell activation. If so, the F₁ anti-parent response was considerably more dependent than the allogeneic response on the integrity of accessory cells. Injection of 5 mg of SIL to donors of responder cells likewise resulted in loss of F₁ anti-parent and occasionally of anti-allogeneic in vitro responsiveness. This in vivo effect of SIL was prevented by pretreating mice with the lysosomal stabilizer poly-2-vinylpyridine N-oxide. Because unresponsiveness induced in vivo was not selective for F₁ anti-parent responses and lasted for up to 10 days, it may be attributable not only to depletion of accessory macrophages by SIL but also to the induction of suppressor macrophages.     

Partial characterization of a prostaglandin-induced suppressor factor

Glass adherent splenic T cells, cultured in the presence of prostaglandin E₂ (10^?5M), were found to elicit a factor capable of nonspecifically suppressing PHA- and LPS-induced mitogenesis. Cells from C57B1/6J, Balb/C, and C3H/He mice were all capable of producing this suppressor factor, although some degree of variability in the response of cells from C3H mice to the factor was observed. The suppressor (designated prostaglandin-induced T-cell derived suppressor, PITS) was characterized biochemically and it was found that the activity was resistant to boiling, and treatment with RNase and DNase, yet was sensitive to treatment with proteinase K, trypsin, and Pronase. Further, PITS supernatants were found to contain at least two suppressors with approximate molecular weights of 35,000 (PITS_α) and 5000 (PITS_β). Results from experiments with cycloheximide-treated glass-adherent T cells indicate that prostaglandin E₂ may function by inducing the release rather than de novo synthesis of the PITS. These results indicate that the reported overall suppressive effect of prostaglandin E₂ on lymphocytes may in part be due to the release by certain T cells of a suppressive factor.     

Leishmania tropica: pathogenicity and in vitro macrophage function in strains of inbred mice.

Of seven strains of inbred mice and one hybrid that were infected intracutaneously with 5, 10, or 20 × 10⁶ active promastigotes of Leishmania tropica major, two strains (CBA/Ca and C₃H/He) recovered from the infection and their lesions healed within 3 to 5 months. The other strains, with the possible exception of C57B1/6 animals, remained infected, carrying large cutaneous ulcers throughout their lives. These included DBA/2, A/Jax, Balb/c, athymic nude mice of Balb/c origin (nu/nu) and the heterozygote Balb/c (nu⁺). The responses of C57B1/6 animals were of intermediate type with a tendency toward nonhealing at higher doses of the parasite. The cutaneous infection of athymic nude mice invariably gave rise to fulminating visceral infections and death. This condition was never observed in the other strains tested. Concanavalin A (Con A)-stimulated syngeneic or allogeneic lymphocytes of intact mice activated peritoneal macrophages of both healer and nonhealer mice, resulting in complete destruction of phagocytosed L. enriettii within 24 to 48 hr. The destruction of ingested L. tropica was confined to macrophages of healer mice and required 72 to 96 hr to reach completion. However, removal of Con A-stimulated lymphocytes from macrophage cultures and regular pulsing of the cells with a lymphokine-rich supernatant produced a state of sustained activation, resulting in destruction of L. tropica inside macrophages of both healer and nonhealer mice. The ability of Con A-stimulated lymphocytes of nonhealer animals to induce effective levels of activation in healer macrophages on one hand, and eventual destruction of L. tropica in macrophages of nonhealer mice under condition of sustained activation on the other, had indicated that so far as the in vitro situation is concerned, there is no inherent defect in lymphocytes or macrophages of nonhealer animals, although the threshold of activation necessary for killing of the parasite seems to be higher for cells of nonhealer origin.     

Suppressor factor from tumor-allosensitized spleen cells--its effect on in vitro proliferation of tumor cells and in vivo skin allograft survival

C57BL/6 mice are sensitized ip with allogeneic P-815 mastocytoma cells. Fifteen days later the spleen cells of the sensitized mice are used in the production of suppressor factor or treated with mitomycin and used as suppressor cells. Sensitized spleen cells incubated with the specific alloantigen (DBA/2 m-treated spleen cells) release suppressor factor (SF)² which inhibits cell proliferation in mixed lymphocyte culture (MLC) as well as the in vitro generation of cytotoxic cells (CML). SF is most effective when added eary during MLC. SF also inhibits mitogen responsiveness of normal spleen cells. In addition to inhibiting lymphocyte function in vitro, suppressor cells as well as SF inhibit the in vitro proliferation of tumor cells. This inhibition is specific for the tumor to which the suppressor cells are induced. The inhibition of tumor cell proliferation is not due to the presence of cytotoxic cells in the spleen of the tumor-allosensitized mice. Suppressor cells from neonatal mice do not inhibit the in vitro proliferation of tumor cells. SF injected iv into C57BL/6 mice decreases the mixed lymphocyte reactivity of the host spleen cells and decreases the ability of the host to reject skin allografts. We interpret these data to suggest that tumor-allosensitized spleen cells, and the SF they produce, not only affect lymphocyte function but also inhibit tumor cell proliferation. This dual effect of suppressor cells could be an important part of the immune surveillance against tumors.     

The T-cell receptor: just another hypothesis.

Functional activities of T and B lymphocytes and the kinetics of hematopoietic stem cells were studied in mice with inoculated or spontaneous tumors. The development and growth of the tumor inhibited B cells and helper T cells, while the activity of killer T cells and spleen suppressor cells was markedly enhanced. The processes of stem cell migration from the bone marrow were considerably intensified and altered in tumor-bearing mice. Data were obtained suggesting that helper T cells and killer T cells represent nonidentical compartments within the population of thymus-dependent lymphocytes. Immunosuppression during tumor bearing is probably due to an impairment of T lymphocytes cooperating in immune responses, B-lymphocytes and their precursors.     

Inhibition of memory cell-mediated cytotoxic response by systemic administration of Corynebacterium parvum.

Intravenous administration of Corynebacterium parvum to mice during a developing immune response to alloantigens resulted in the marked inhibition of the generation and expression of memory cell-mediated cytotoxic response in the spleen. The inhibition was observed following rechallenge in vivo or by in vitro culturing with the same alloantigen. The impairment in vitro was due, in part, to the generation of regulatory cells which were non-T phagocytic cells, probably macrophages activated by C. parvum administration. These suppressor macrophages appear to act by inhibiting proliferation and clonal expansion of memory cytotoxic cells.     

Mechanisms of corticosteroid action on lymphocyte subpopulations. IV. Effects of in vitro hydrocortisone on naturally occuring and mitogen-induced suppressor cells in man.

The effects of in vitro hydrocortisone (OHC) on human peripheral blood (PB) suppressor cell function were investigated. Two types of suppressor cells were studied: (i) the naturally occurring PB suppressor cell seen in 10% of normal people whose lymphocytes do not respond to in vitro PWM stimulation with direct anti-SRBC PFC responses, and (ii) Con A-generated suppressor cells. The addition of OHC to PWM-stimulated cultures from nonresponders reconstituted the PFC response in two of three individuals. The addition of OHC to allogenic cocultures of nonresponder and responder lymphocytes completely inhibited the ability of the naturally occurring suppressor cell of the nonresponder cultures to inhibit the PFC responses of normal responders. Preincubating the nonresponder cultures in 10^?5M OHC for 30 min followed by washing did not inhibit suppressor function, whereas readdition of OHC to cocultures did inhibit nonresponder suppressor cell function. The addition of up to 10^?4M OHC to previously generated Con A-activated suppressor cell-fresh cell cocultures in vitro did not prevent or inhibit mitogen-activated suppressor cell function. However, preincubation of PB cells for 6 hr prior to the addition of Con A prevented the generation of suppressor cells and in two of eight experiments generated a population of cells which were in and of themselves mitogenic for autologous fresh PB. Thus, the function of naturally occurring suppressor cells as well as the induction but not the function of Con A-activated suppressor cells is sensitive to pharmacologic levels of OHC. The effect of OHC on naturally occurring suppressor cell function or on the generation of suppressor cells by Con A did not involve cell lysis, but rather was a reversible phenomenon requiring the continued presence of OHC in culture.     

Inhibition of rat mixed lymphocyte cultures by suppressor macrophages.

Normal rat spleens contain suppressor cells which can inhibit proliferative and cytotoxic responses of lymphocytes to alloantigens in vitro. The suppressor cells are adherent, phagocytic, resistant to treatment with ATS and C, radioresistant, resistant to treatment with mitomycin C, apparently absent from the thymus, and found in very high concentrations in peritoneal exudates. These characteristics indicate that the suppressor cell is a macrophages and not a T cell. When suppressor cells were removed from spleen cell suspensions, strong in vitro proliferative and cytotoxic responses to alloantigens could consistently be observed.