In vitro generation of K562 killers in human T-lymphocyte subsets

Group A streptococcal pyrogenic exotoxin (SPE) is a potent modulator of the immune system when used experimentally in mice. Typically, a late burst of plaque-forming cells (PFC) follows an early suppression of the antibody response in appropriately immunized and SPE-treated mice or their spleen cells in vitro. This altered response to antigen caused by SPE is termed a deregulated antibody response. The site of action of SPE was studied by use of cellular reconstruction and complementation experiments using the separated subpopulations of immunocytes which are required for full expression of mouse spleen PFC responses to sheep erythrocytes or to trinitrophenylated (TNP) rabbit erythrocytes in vitro. The SPE site was thus localized to the T-cell subpopulation. Recently SPE has been purified to a very high degree, making it possible to ascertain that SPE alone generates the deregulation of the immune system as described before and to limit the role of nondefined components of cruder preparations of SPE. A purified horse anti-scarlet fever antitoxin which recognizes highly purified SPE as being homogeneous also recognized a single component of crude SPE by agar-gel analysis. A rabbit anti-SPE immunoglobulin raised against crude SPE and absorbed with killed, strain NY5, Group A streptococci recognized the pure SPE and a major component of the homologous crude SPE similarly. Both of these antisera neutralized the capacity of SPE to deregulate the in vitro PFC response to TNP almost completely. A third antiserum raised in rabbits against a NY5 Group A streptococcal whole cell vaccine recognized a different component of crude SPE and totally failed to recognize pure SPE. This antiserum also recognized a purified Group A streptococcal peptidoglycan as being related to components contained in the crude SPE preparation. This antiserum, however, totally failed to neutralize the capacity of SPE to deregulate the PFC response to TNP. These results show that SPE-A is the active component of cruder preparations of SPE which deregulates PFC responses.     

Interferon inhibition of the primary in vitro antibody response to a thymus-independent antigen

Partially purified and crude mouse L cell interferon preparations inhibited the in vitro plaque-forming cell (PFC) response of mouse C57B1/6 spleen cells to the T-cell independent lipopolysaccharide antigen of Escherichia coli 0127. PFC responses of 5-day cultures were inhibited approximately 70–90% by 100–200 NIH reference units of interferon/culture. A similar inhibitory effect was obtained with spleen cells from athymic (nude) mice homozygous for the nu/nu allele. Spleen cultures depleted of adherent cells were also inhibited in their anti-0127 PFC response by interferon. Interferon, then, appears capable of inhibiting the PFC response to E. coli 0127 via direct action on B cells. Heating experiments along with the use of interferon preparations of different specific activities suggest that the inhibition was due to the interferon in the preparations.     

Complementation of the anti-TNP PFC response of N:NIH nude mice from nude dams by spleen cells of nude mice from heterozygous dams.

Type I and Type II nude (nu/nu) mice are borne and raised by nu/nu dams and +/nu dams, respectively, under SPF conditions. Splenocytes from Type I nude mice exhibit even smaller in vitro PFC responses to trinitrophenylated rabbit erythrocytes than splenocytes from Type II nude mice. Type II splenocytes complement the magnitude of the PFC response of Type I splenocytes. The helper cell-like activity contained in Type II splenocyte suspensions was increased by treating Type II nude donor mice with dibutyryl cyclic AMP, but was essentially unaffected by pretreatment of Type II donors with endotoxin (LPS). The helper-like activity of Type II splenocytes was suppressed by treatment with a rabbit antiserum (plus C′) raised against a mixture of neonatal mouse thymocytes (RAM-T). We interpret the data to indicate that Type II splenocytes contain a larger number of residual T cells and/or a more fully developed population of T precursor cells that initiate or that are capable of being induced to initiate a helper function.     

Natural T-cell regulation of spontaneous immunoglobulin secretion.

Splenic lymphocytes from nude (nu/nu), heterozygous/nude (+/nu), or wild type (+/+) mice were examined for their capacity to secrete immunoglobulin (Ig) in the absence of exogenous antigenic stimulation. Using the reverse hemolytic plaque assay, which measures spontaneous Ig secretion in vitro, whole spleen populations from both heterozygous/nude (+/nu) and nude (nu/nu) mice were found to have significantly fewer numbers of plaque-forming cells when compared with spleen cells from +/+ mice. Analysis of highly purified populations of T and B lymphocytes showed that increased numbers of B cells from +/+ mice were stimulated to secrete Ig when as few as 10% syngeneic +/+ T cells were added in vitro. In contrast, the same number of thymocytes suppressed the identical B-cell function. A comparison of splenic T cells obtained from either +/+ or +/nu mice revealed that T cells from +/nu animals stimulated additional plaque-forming activity by B cells from wild type or nude mice. The cellular mechanism underlying enhanced help by T cells from +/nu mice is unclear but may reflect a functionally restricted population of T cells inherited by heterozygous/ nude mice.     

Nude mice--a model system for studying the cellular basis of the humoral immune response

Mice homozygous for the nu gene fail to develop a thymus. In comparison to spleen cells from +/nu mice spleen cells from nu/nu mice have a deficient 19S PFC response to SRBC when tested in culture or in vivo. This deficiency is due to a lack of “helper” T cells in nu/nu spleen; A cells and B cells appear to be normal. The capacity of nu/nu spleen cells to produce a PFC response in culture can be corrected by the addition of T cells obtained from either the thymuses or the spleens of +/nu mice. In contrast to “helper” T cells obtained from the spleen, “helper” T cells obtained from the thymus appear to require the capacity for proliferation during the response to SRBC.     

Effect of immune heterozygous spleen cell transfer on resistance to mouse hepatitis virus infection in nude mice

The role of cell mediated immune response to mouse hepatitis virus (MHV) infection in mice was studied by transferring spleen cells from immune heterozygous littermates (nu/+). A suppressive effect on viral growth was seen in infected nude (nu/nu) mice, whereas immune nu/+ serum transfer had no effect. The protective effect of immune nu/+ spleen cells was significantly reduced by treatment with anti-theta serum plus complement but not with anti-Ig serum. In infected nu/nu mice which received transfers of immune nu/+ cells, neutralizing antibody appeared although the titer was not high enough to protect nu/nu mice from fatal infection. Histopathologically, lymphocyte infiltration in hepatic lesions was evident in infected nu/nu mice with nu/+ cell transfer, while it was slight without nu/+ cell transfer.     

Effect of allogeneic cell interaction and graft-versus-host reaction on the antibody response to Escherichia coli 0127 antigen.

The influence of allogeneic cell interaction and GVH reaction on the immune response to Escherichia coli antigen was investigated. Addition of CBA/J spleen cells to cultures of nu/nu spleen cells stimulated a significant increase in the nude PFC response to SRBC but had no significant effect on the immune response to E. coli antigen. Similarly, the induction of a GVH reaction in F₁ mice by the injection of parental spleen cells also had no significant effect on the immune response to the bacterial antigen. These results suggest that the immune response to E. coli is not affected by products of thymus-derived cells.     

Plasmodium yoelii: the thymus-dependent lymphocyte in mice immunodepressed by malaria

Euthymic mice, athymic nude mice, and mice treated with antithymocyte serum were infected with Plasmodium yoelii and immunized 10 days postinfection with pneumococcal polysaccharide (SSSIII). As a control, uninfected mice were also immunized with SSSIII. Splenic plaque-forming cells as well as serum antibody titers to SSSIII were measured 5 days after immunization. In infected euthymic mice, both plaque-forming cells (PFC) and serum antibody were severely depressed. In contrast, plaque-forming cells and serum antibody were approximately normal in infected nude mice and in infected mice treated with antithymocyte serum. Splenic adherent cells from infected euthymic mice failed to function as accessory cells in the in vitro antibody response to a second antigen, the sheep erythrocyte. Moreover, they lacked suppressor activity when cultured with spleen cells from uninfected mice. In contrast, adherent spleen cells from infected mice treated with antithymocyte serum displayed accessory cell function.     

Primary in vitro antibody response of rabbit lymphoid cells and T-B cell collaboration in the absence of detectable mitogens

To investigate whether the antibody response and T-B-cell collaboration in vitro can be obtained in the absence of mitogens, a method of obtaining an in vitro primary anti-sheep red blood cell antibody response by rabbit spleen and lymph node cells was developed. We used Marbrook culture vessels and a specially prepared medium containing 10% autologous serum and maintained at pH 7.4–7.6. The system was shown to be devoid of any polyclonal mitogens as assessed by [³H]thymidine incorporation and by direct examination for blast cells in stained smears. The primary response increased continuously over the 5-day cultivation period and only IgM but not IgG plaque-forming cells (PFC) were detected. In over 20 experiments, the response ranged from 357 ± 17 to 4425 ± 110 PFC/10⁷ cultured cells with a median stimulation index of 52. The spleen cells required less antigen than the lymph node cells and 2-mercaptoethanol inhibited the response of the spleen cells but not that of the lymph node cells. Lymphocytes were separated into highly pure T- and B-cell populations by negative selection using antibody-coated human erythrocytes to rosette either T or B cells and Ficoll-Hypaque centrifugation to remove rosetted cells. Upon cultivation, B cells alone gave a low IgM response, whereas B cells reconstituted with T cells gave a response similar to that obtained with unseparated lymphoid cells. We concluded that: (a) optimal conditions for obtaining primary in vitro antibody responses using rabbit spleen and lymph node cells were established, (b) T-B-cell collaboration was demonstrated in the rabbit primary antibody response to sheep erythrocytes, and (c) the primary antibody response in vitro and T-B-cell collaboration may occur in the absence of detectable polyclonal mitogens.     

Polyclonal Antibody Production in Murine Spleen Cells Induced by Staphylococcus

Polyclonal plaque-forming cell (PFC) responses in murine spleen cells induced by Staphylococcus aureus and S. epidermidis were studied. Injection of Balb/c mice with S. aureus strain 248βH resulted in the generation of anti-trinitrophenyl (TNP) and anti-sheep red blood cell PFC in their spleens. Cultures of Balb/c spleen cells in the presence of S. aureus 248βH, Cowan I, or a protein A-deficient mutant yielded many anti-TNP PFC. The larger the number of organisms that were added to the cultures, the better was the PFC response. Both living and killed organisms, were capable of inducing the response, but an excess of living 248βH organisms in the cultures abrogated the response. All of the organisms (12 strains of S. aureus and 11 strains of S. epidermidis) freshly isolated from patients had the ability to induce the polyclonal PFC response in cell cultures. These organisms stimulated cultured C3H/HeJ mouse spleen cells, which were unresponsive to bacterial lipopolysaccharide (LPS). Cultured cells from the spleens of athymic nu/nu mice also responded to these organisms, and the number of PFC in nu/nu cell cultures was always greater than that in nu/+ cells prepared from a haired litter mate. Moreover, the responses of nu/nu spleen cell cultures to which nylon wool column-filtered splenic nu/+ T cells were added were lower than expected. These findings suggest that the polyclonal PFC response to staphylococci is thymus independent, but that the magnitude of the response is regulated by mature T cells. Cultures of macrophage-depleted spleen cells responded to the organisms to an extent similar to that of the control. The 248βH organisms were less capable of stimulating spleen cells of 2-week-old mice (i.e., early maturing B cells) than LPS. However, spleen cells from adult (7-week-old) and aged (9-month-old) mice responded well to both the organisms and LPS. Previous sensitization with the organisms in vivo did not affect any polyclonal responses of spleen cells in vitro to either the organisms or LPS. The role of staphylococcal protein A in the polyclonal PFC response to staphylococci is discussed.     

Thymus-independent anti-DNP antibody responses to DNP-casein and DNP-gelatin.

Although studies on the molecular nature of thymus-independent antigens suggested that the polymeric structure with repeated antigenic determinants and slow metabolism are responsible for thymus-independence, we found that anti-DNP antibody responses to DNP-casein and DNP-gelatin were thymus-independent as well as macrophage-independent. These antibody responses were not affected by in vivo treatment with carrageenan or anti-thymocyte serum. In addition, responses of athymic nude mice to both antigens did not show any significant differences when compared with heterologous nu/+ mice. The findings were confirmed by in vitro experiments; non-adherent spleen cells or T cell-depleted spleen cells responded well to both antigens to the same extent as normal spleen cells. Since both casein and gelatin are polyclonal B cell activators and are not presumed to be high polymer or slow-metabolizing substances, we suggest that thymus-independence in many kinds of antibody response should be reconsidered.     

Interleukin 2 production by lymphoid cells from congenitally athymic (nu/nu) mice

The ability of lymphoid cells from congenitally athymic (nu/nu) mice to produce interleukin 2 (IL 2) was investigated. Spleen or lymph node cells (superficial or mesenteric) from nude mice on an N:NIH(S)II or BALB/c genetic background were stimulated with concanavalin A (Con A) or with irradiated allogeneic (DBA/2) spleen cells that had been depleted of T cells by treatment with monoclonal anti-Thy-1.2 antibody plus complement. After 24 hr, supernatants were harvested and assayed for their ability to support the proliferation of a cloned IL 2-dependent cytolytic T cell line. With this quantitative microassay, IL 2 production was not detectable in spleen and lymph nodes of 6-wk-old N:NIH(S)II nude mice; however, by 12 mo of age, IL 2 production increased more than 100-fold to reach levels comparable to control (nu/+) animals. Con A was more potent than alloantigen in the induction of IL 2 in either nude or control (nu/+) animals. Furthermore, differences in the genetic background of nude mice resulted in corresponding differences in both numbers of T cells (defined by monoclonal anti-Thy-1 antibody) and IL 2 production. By using negative selection with monoclonal antibodies plus complement, IL 2 production in aged nude mice was shown to depend upon a subpopulation of cells that expressed Thy-1 but not Lyt-2. These data thus demonstrate that a subpopulation of IL 2-producing cells with a Thy-1+ Lyt-2- surface phenotype can develop in the apparent absence of thymic influence.     

Studies of immune responses in mice prone to autoimmune disorders. II. Decreased down-regulation by auto-anti-idiotype antibody in autoimmune-prone mice

Three lines of evidence are presented which suggest that autoimmune-prone mice are deficient in the production of auto-anti-idiotype antibody during their immune response to trinitrophenylated Ficoll (TNP-F). NZB, MRL lpr/lpr and older BXSB male mice have no hapten-augmentable plaque-forming cells (PFC). Hapten-augmentable PFC have been previously shown to be cells whose secretion of antibody has been inhibited by the binding of auto-anti-idiotype antibody to cell surface idiotype. Sera from TNP-F immunized NZB mice lack PFC inhibiting activity (anti-idiotype antibody). Spleen cells from TNP-F immune NZB mice fail to transfer anti-idiotype antibody-mediated suppression to naive mice as do spleen cells from immune non-autoimmune-prone mice. Taken together these data suggest that autoimmune-prone mice are deficient in auto-anti-idiotype antibody-mediated downward regulation of their immune responses. It was further shown that the immune response of NZB mice to TNP-F shows a slower decline in splenic PFC and a greater heterogeneity of PFC affinity than do the responses of non-autoimmune-prone strains. Since athymic (nude) mice, which were previously shown to be defective in the production of auto-anti-idiotype antibody, also show a slower decline in splenic PFC and an increased heterogeneity of PFC affinity, it is suggested that these peculiarities of the immune responses of autoimmune-prone and athymic mice are also the consequences of the lack of auto-anti-idiotype antibody-mediated down-regulation.     

Corticosteroids and the humoral immune response of mice. II. Enhancement of bone marrow antibody formation to lipopolysaccharide by high doses of corticosteroids.

The effect of injection of the synthetic corticosteroid dexamethasone sodium phosphate upon the primary response to Escherichia coli lipopolysaccharide (LPS) was studied in mouse spleen and bone marrow. Daily corticosteroid injections, starting 1 day before immunization with LPS, could suppress the anti-LPS plaque-forming cell (PFC) response in the spleen. The higher the dose of corticosteroids, the more the splenic PFC response was suppressed. On the other hand, the bone marrow PFC response showed a dose-dependent enhancement after corticosteroid injections. This effect was maximal when tested 7 days after antigen injection, and constituted a 3- to 15-fold increase after daily injection of 16 mg dexamethasone/kg body wt. The same effect was found in genetically athymic nude mice, showing that the corticosteroid-mediated enhancement of the anti-LPS PFC response in the bone marrow is not due to elimination of T suppressor cells. Probably the differential effect of corticosteroids upon antibody formation in spleen and bone marrow is due to a redistribution of B-lineage cells, with a resulting accumulation in the bone marrow.     

Leishmania tropica: Association of a B-cell mitogen with hypergammaglobulinemia in mice

Infection of BALB/c mice with Leishmania tropica NIH S strain resulted in splenic enlargement, hypergammaglobulinemia, and polyclonal activation of B lymphocytes as measured by the splenic plaque-forming cell response (PFC) to trinitrophenyl (TNP) and sheep erythrocytes (SRBC). The peak anti-SRBC PFC response occurred 5 weeks after infection; both direct and indirect (facilitated) plaques were significantly increased. The in vitro primary immune response to trinitrophenyl haptenated lipopolysaccharide (TNP-LPS), as enumerated by the anti-TNP PFC response, was also increased on a per-spleen basis beginning 3 weeks after infection. The properties of a lysate of L. tropica promastigotes (LTL) was studied to determine whether polyclonal B-cell activation was related to a parasite-derived mitogen. A B-cell mitogen was identified in LTL which stimulated the proliferation of spleen cells in vitro from uninfected control and congenitally athymic (T-cell-deficient) but not from μ-suppressed (B-cell-deficient) animals. Preliminary characterization of the mitogen material indicated that it was a nonpyrogenic, heat-labile peptide or protein and was probably not bacterial lipopolysaccharide (LPS).     

The effects of cortisol on the primary response of mouse spleen cell cultures to heterologous erythrocytes

Cell viability and the production of direct PFC were studied in mouse spleen cell cultures after cortisol treatment in vivo or in vitro at various times relative to primary stimulation with SRBC in vitro.Cortisol treatment in vivo reduced spleen cell numbers by 88% after 48 hr, but cultures of the remaining cells produced as many PFC in vitro as did cultures of equal numbers of normal spleen cells.In normal spleen cell cultures incubated with cortisol for 4 hr prior to the addition of antigen, peak responses of PFC/culture and PFC/10⁶ cells occurred 24 hr later than in controls and averaged, respectively, 27% and 141% of control values. Minimum viable cell numbers were observed in cortisol-treated cultures after 3 days; thereafter cell numbers gradually increased. These results were not significantly altered when cultures were treated simultaneously with cortisol and antigen.The response was not suppressed if the addition of antigen preceded that of cortisol by more than 4 hr. Suppression was also considerably reduced if fetal calf serum was used when preparing cells for culture.     

Role of self carriers in the immune response and tolerance. III. B cell tolerance induced by hapten-modified-self involves both active T cell-mediated suppression and direct blockade.

The induction of B cell unresponsiveness with hapten-modified syngeneic murine lymphoid cells (hapten-modified self, HMS) can be achieved in vivo and in vitro. Tolerance in vivo in mice required a latent period of 3 to 4 days. Moreover, B cell unresponsiveness could not be induced by HMS in athymic nude mice, although their nu/+ littermates were rendered hyporesponsive by HMS. Pretreatment of normal mice with cyclophosphamide (cyclo) prevented their susceptibility to tolerance induction by haptenated lymphoid cells. Nude mice became sensitive to HMS-induced suppression if they were first reconstituted with spleen cells from normal (but not cyclo-treated) donors.Interestingly, labeling of H-2 antigens was not necessary for tolerance induction by HMS since haptenated teratoma cells (lacking H-2) were tolerogenic in normal recipients.In contrast, suppression of the in vitro response to haptenated flagellin occurred equally well with nude, nu/+ and anti-Ly 2 + C-treated spleen cells. These data suggest that cyclo-sensitive modified self-reactive (T) cells may regulate the immune response and mediate tolerance to HMS in vivo. However, the in vitro “blockade” of B cell reactivity may be directly mediated on hapten-specific PFC precursors.     

Migration and differentiation of bone marrow lymphocytes: development of surface immunoglobulin, Fc receptor, complement receptor, and functional responsiveness as studied with anti-allotype serum

Immunofluorescent studies using fluorescein isothiocyanate-conjugated mouse anti-allotype antibody were carried out to study the migration pattern and the development of surface Ig (SIg), Fc receptor for IgG (FcR gamma), and complement receptor (CR) or mouse bone marrow lymphocytes following intravenous injection into congenic mice. After transfer of bone marrow cells from CSW mice into untreated congenic CWB mice, the absolute number of donor-type SIg-bearing (SIg+) cells and the proportion of either FcR gamma- or CR-bearing (FcR gamma+ or CR+) cells in donor-type SIg+ cells were evaluated in the recipient spleen and the results were compared with those obtained after the transfer of CSW spleen cells. After injection of donor bone marrow cells, detectable donor-type SIg+ cells, although few initially, increased from day 1 to Day 2 and reached a plateau thereafter. The proportion of FcR gamma+ cells in donor-type SIg+ cells, although very low in the donor marrow inoculum, increased progressively after 1 day to reach a maximum at Day 5 (90%). On the other hand, following the transfer of spleen cells, the proportion of FcR gamma+ cells remained at high levels (90%) for 5 days after transfer. Likewise, the proportion of CR+ cells in donor-type SIg+ cells was very low (less than 1%) in the original donor bone marrow cells but high (60%) in the donor spleen cells. However, in transferring bone marrow cells this proportion also increased in the recipient spleen to reach a maximum (49%) at Day 5 although it was lower compared to the percentage of FcR gamma+ cells in donor SIg+ cells. Furthermore, the ability of functional responsiveness to antigen was also examined in the same system by detecting plaque-forming cells (PFC) from donor origin. In transferring donor bone marrow cells into recipient, the participation of donor cells in the PFC response was very low when the recipients were primed with sheep red blood cells at Day 3 after transfer. However, when the recipients were primed at Days 7 to 21 after transfer, increasing numbers of the donor marrow-derived cells were involved in the PFC response. Thus, the present study demonstrates that the bone marrow-derived lymphocytes, albeit lacking both distinctive surface receptors (IgM, FcR gamma, CR) and the functional responsiveness to antigen, continue their development along the B-cell lineage after migrating into the spleen, as evidenced by the surface receptor expression and participation in the antibody response.     

Induction of tolerance in athymic mice with an antigen which is highly immunogenic in euthymic mice.

Adult congenitally athymic (nu/nu) mice were found to be unable to respond to aggregated human γ-globulin (AHGG), the normally immunogenic form of HGG, unless first reconstituted with specific T cells. However, pretreatment of nude mice with AHGG prior to T-cell reconstitution resulted in the induction of unresponsiveness. This state of tolerance was specific since pretreated animals responded normally to the noncross-reacting antigens turkey γ-globulin or DNP-Ficoll. Transfer of spleen cells from nude mice pretreated with AHGG into normal littermates did not significantly affect a subsequent anti-HGG response of the recipients. Conversely, nude mice pretreated with AHGG and reconstituted with normal littermate spleen cells were hyporesponsive to challenge with AHGG. The results of these experiments are discussed in reference to various models for the induction of B-cell unresponsiveness.