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.     

Plasmodium berghei: Reduction of the mouse's specific lymphoproliferative response in relation to corticosterone and pregnancy

Spleen cells from mice immune to Plasmodium berghei exhibited a significantly increased in vitro proliferative response to parasitized reticulocytes compared to spleen cells from normal mice. The specific response to malaria antigen was decreased in spleen cells from pregnant immune mice in contrast to the nonspecific response to the mitogen phytohemagglutinin. Addition of mouse serum to spleen cell cultures of immune mice depressed both the phytohemagglutinin and the specific proliferative response, whereas serum of pregnant mice exerted an even stronger inhibition than serum of nonpregnant mice. Charcoal adsorption of mouse sera for the elimination of steroid hormones removed the serum dependent immunosuppression from normal as well as pregnant serum. Corticosterone added to the spleen cell cultures depressed also the proliferative response. These findings demonstrate that the response to malaria antigen is decreased in immune mice during pregnancy. The possible effect of serum corticosterone on the depression of the immune response is discussed.     

In vitro studies of the rabbit immune system: I. Hemolytic plaque-forming response of dissociated spleen cells from normal and primed rabbits

The conditions for the in vitro generation of primary and secondary immune responses by rabbit spleen cells to sheep red blood cell (SRBC) antigen have been examined. Spleen cells from many normal and all previously immunized rabbits are capable of producing in vitro plaque-forming cell (PFC) responses when cultured as dissociated cell suspensions in the presence of antigen. Primed spleen cells generate approximately 100 times the number of PFCs obtained in normal cultures with a shorter lag period. Both types of cultures demonstrate a period of exponential increase in PFCs during which the doubling time is 12–14 hr. This increase occurs after 1 day of culture of spleen cells from primed rabbits and after 4 days of culture of spleen cells from unprimed rabbits. The PFCs which arise in cultures of primed cells appear not to be the progeny of those generated in vivo but to be derived from an increased number of PFC precursors. Repeated immunization of the spleen cell donor is required to produce significant numbers of indirect (IgG) PFC or indirect precursors; most of the PFC found after a single immunization in vivo or in vitro are direct (IgM). There is no evidence for conversion of IgM to IgG PFC in vitro. This system should provide a means for further identification of the cellular interactions involved in the immune response of the rabbit.     

Production of thymocyte-stimulating factor by murine spleen lymphocytes: cellular and biochemical mechanisms.

Cultures of murine spleen lymphocytes treated with Thy 1.2 antiserum plus complement do not produce thymocyte-stimulating factor (TSF). The population of thymocytes composed of immunocompetent, low-density cells produces only small amounts of TSF. Experiments with cyclophosphamide-injected mice and with spleen cells treated in vitro with antiserum to the murine B lymphocyte antigen plus complement and experiments using spleen cells stimulated in vitro with Sepharose-bound phytohemagglutinin indicate that B lymphocytes neither cooperate with T lymphocytes for the production of TSF nor produce TSF. Some lectins (pokeweed mitogen, Lens culinaris hemagglutinins A and B) have been found to induce the production of TSF by spleen cells. Other lectins (wheat germ agglutinin, Agaricus bisporus agglutinin) and sodium periodate do not. Spleen cells of mice immunized in vivo with keyhole limpet hemocyanin bound to bentonite particles or with BCG produce TSF when challenged in vitro with the specific antigen. Experiments using inhibitors of the macromolecular metabolism showed that DNA synthesis is not required for the production of TSF by spleen lymphocytes, whereas RNA and protein synthesis are required. Resolution of spleen lymphocytes on a discontinuous albumin gradient into six subpopulations showed that the TSF activity was rather uniformly distributed among the various subpopulations of cells.     

Heterogeneity of antibodies produced by single hemolytic foci

Lethally irradiated male BDF₁ mice were injected with 10⁷ bone marrow cells, 8 × 10⁵ spleen cells, and sheep or goat red blood cells as antigens. The cross-reactivity between these red blood cells is approximately 40%, as determined by injecting normal mice with either sheep or goat red blood cells, removing their spleens 4 days later, and assaying all spleens for both antisheep and antigoat plaque-forming cells. Eight days after injection of bone marrow, spleen, and antigen, the spleens of the irradiated recipients were removed and assayed for the presence of hemolytic foci by the Playfair technique, and were found to contain an average of 0.7 foci/spleen. Earlier studies had demonstrated that such foci could contain plaque-forming cells derived from more than one precursor cell. The positive pieces comprising a single hemolytic focus were removed, pooled, and aliquots were assayed for direct and indirect plaque-forming cells to the immunizing antigen. Several foci were found to contain 17–82% as many plaque-forming cells lysing the cross-reacting antigen as lysed the immunizing antigen. These data indicate that these foci contained plaque-forming cells of two specificities: (1) plaque-forming cells which responded to determinants on the immunizing antigen only, and (2) plaque-forming cells which responded to determinants on both the immunizing and cross-reacting antigens. In addition, single foci were found which contained both direct and indirect plaque-forming cells lysing the immunizing antigen. Sixteen of 39 foci assayed contained more than twice as many indirect as direct plaque-forming cells. We concluded that a single hemolytic focus, probably derived from more than one precursor cell, could contain plaque-forming cells producing antibodies of more than one set of specificities and immunoglobulins of more than one type.     

The nature of the suppressive effect of interferon and interferon inducers on the in vitro immune response

Viral-induced interferon inhibition of the primary in vitro plaque-formong cell (PFC) response in the mouse (C57B1/6) involves a dynamic relationship between the nature of the antigen, the concentration of interferon added to antigen-stimulated cultures, and the time of addition of interferon relative to antigen addition. The PFC response to a thymus-dependent antigen (sheep red blood cells) was more easily suppressed by viral-induced interferon than was that to a thymus-independent antigen (E. coli 0127 LPS), both in terms of inhibitory concentrations of interferon and the time at which the interferon could be added to cultures after antigen and still inhibit the PFC response. These differential effects of interferon could be related to the difference in cellular requirements (B and T lymphocytes) of the two antigens. Interferon was effective in inhibiting the in vitro PFC response of antigen-primed spleen cells, indicating that it can block the response of memory lymphocytes. By using interferon inducers as inhibitors of the in vitro PFC response, it was possible to show that at least two antigenically distinct interferons may be involved in suppressing the immune response. It is known that one type of interferon is induced by virus and synthetic double-stranded polyribonucleotides. The other type is stimulated by antigen and T cell mitogens. A model is proposed to explain the nature of these interferon inhibitory effects in terms of mediation of immune suppressor cell effects.     

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.     

Biochemical characterization of lymphocyte regulatory molecules. II. Purification of a class of rat and human lymphokines

Rat spleen cells activated in vitro by concanavalin A produce lymphokine molecules that possess biologic activity in a number of murine lymphocyte response assays. A single class of lymphokine most adequately described as T cell growth factor (TCGF, Interleukin-2) with a m.w. of 15,000 as estimated from gel filtration studies and with an isoelectric range of 5.4 to 5.6 stimulates i) the growth of established T cell lines in culture, ii) the proliferation of thymocytes in the presence of Con A under culture conditions where Con A alone is non-mitogenic, iii) the induction of antibody responses to heterologous erythrocyte antigens in athymic (nude) mouse spleen cell cultures, and iv) the generation of cytotoxic T lymphocytes (CTL) in thymocyte cultures and in nude mouse spleen cell cultures. We suggest that in each of the assay systems tested, this class of rat lymphokine acts directly on activated T cells. Nonactivated T cells must be stimulated by either mitogen or antigen before becoming responsive to lymphokine, but do not require antigen or mitogen for continued lymphokine-dependent proliferation. Similarly, human peripheral blood mononuclear cells activated by phytohemagglutinin (PHA) produce a class of lymphokines of identical size with an isoelectric point of 6.0 to 6.5 that possess the same biologic properties as measured in murine lymphocyte response systems.     

Antigen-induced in vitro inhibition of immune responsiveness

Addition of the dinitrophenyl derivative of the copolymer of d-glutamic acid and d-lysine (DNP-d-GL) or dinitrophenyl bovine γ-globulin (DNP-BGG) to spleen cell cultures specifically inhibited their capacity to produce an anti-DNP plaque-forming cell (PFC) response to the T-independent antigen dinitrophenylated polyacrylamide beads (DNP-PAA) or to the T-dependent antigen TNP-burro erythrocytes. The degree of unresponsiveness was dependent upon the tolerogen concentration and the duration over which the tolerogen was present in the culture. Treatment with rabbit anti-mouse brain antiserum and complement did not alter the induction of unresponsiveness suggesting a state of B-cell tolerance. Culture of spleen cells for 4 days in the absence of antigen led to the appearance of nonspecific suppressor activity which was demonstrable by its effect on the response of fresh spleen cells to antigen. Preculture in the presence of the immunogen DNP-PAA induced both nonspecific and specific suppressor activities. Induction of specific suppressor activity was not prevented by the presence of the tolerogen DNP-D-GL in the culture. The suppressor activity resided in an adherent T-cell population and did not appear to require macrophages for its induction.     

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.     

Secretion of IgM antibodies by glass-adherent fraction of immune mouse spleen cells. II. Characteristics of glass-adherent plaque-forming cells.

Further studies have been carried out on the nature and the behaviour of the anti-SRC plaque-forming cells from the adherent fraction of mouse spleen cells. In this fraction many phagocytic, acid phosphatase-positive cells were observed in the center of the plaques. The glass-adherent PFC were found to be highly radioresistant in vitro, compared to the nonadherent fraction. In both primary and secondary immune responses, only the direct PFC showed the tendency to adhere to glass. The phenomenon of the glass adherence of a fraction of direct PFC is also apparent in mouse spleen cells stimulated in vitro with SRC.     

Time and dosage dependence of immunoenhancement by murine type II interferon preparations.

Preparations of Type II immune induced Interferon enhanced the plaque forming cell response of mice to sheep red blood cells both in vivo and in vitro. The enhancement of the antibody response was dependent on the dosage of interferon used and the time of administration of interferon. The expression of the antiviral and immuno-enhancing activities of Type II interferon preparations shared several physical-chemical properties, including pH 2 lability and heat stability. The plaque forming cell response to lipopolysaccharide, a T-independent antigen, could not be enhanced by treatment with Type II interferon. In addition, treatment of spleen cell cultures of nude thymic deficient mice with Type II interferon could not cause an enhancement of the plaque forming cell response to lipopolysaccharide. These data suggest that the immunoenhancing effect of Type II interferon on antibody responses is produced by an effect on T lymphocytes in contrast with the immunosuppressive effect which appears to be mediated through an effect on B lymphocytes.     

Production of an antiviral factor by murine spleen cells after treatment with Corynebacterium parvum.

We have previously shown that injection of Corynebacterium parvum (CP) in mice protected them against lethal encephalitis induced by herpes simplex virus, (HSV). It is shown here that spleen cells of CP-injected mice in vitro produce a factor capable of inhibiting the replication of HSV in mouse embryo fibroblasts (MEF). A similar activity was produced after in vitro exposure of spleen cells from untreated mice to CP. CP was only slightly mitogenic in contrast to phytohemagglutinin (PHA), concanavalin A (Con A), and bacterial lipopolysaccharide (LPS) which were strongly mitogenic but did not induce antiviral activity high enough to be detected in the HSV-MEF system. The activity produced by CP-treated spleen cells appeared to be interferon since it was trypsin sensitive and species specific and not virus specific, and since preincubation of the cells was required to demonstrate an antiviral effect. However, the identity of CP-induced interferon with any of the previously described subclasses of interferon remains to be determined.     

Classification of interferons with antibody to immune interferon

Mouse immune Interferon, induced by the T-cell mitogen staphylococcal enterotoxin A (SEA), was partially purified and used to immunize rabbits. The resulting antiserum neutralized all immune interferon preparations tested, including interferon induced in vitro by SEA, concanavalin A, phytohemagglutinin P, and pokeweed mitogen, and in mixed lymphocyte cultures. Interferon produced in vivo with specific antigen was also neutralized. The antiserum was equally potent against all these interferon preparations. The serum did not neutralize any virus-type interferon preparation tested, but immune interferon induced by SEA in athymic nude mouse spleen cells was neutralized. The neutralizing activity was precipitable by 33% ammonium sulfate, and was not removed by absorption of the serum with mouse cells. The data suggest that immune interferons produced under diverse conditions are antigenically the same or closely related.     

Biochemical relationship of thymocyte mitogenic factor and factors enhancing humoral and cell-mediated immune responses.

Supernatants from concanavalin A-induced mouse spleen cells contain soluble factors which: 1) augment the anti-sheep erythrocyte hemolytic plaque-forming cell response of nude mouse spleen cells, 2) facilitate the generation of antigen-specific cytotoxic cells by alloantigen-stimulated thymocytes, and 3) enhance the mitogenic response of thymocytes in the presence or absence of phytohemagglutinin. The uninduced control spleen cell supernatants contained variable but significantly less biologic activity within the difference assay systems. The principle enhancing activity (apparent m.w. 35,000 to 38,000) in each of the assay systems was found to be inseparable after a multiple step purification scheme involving ammonium sulfate precipitation, two-cycle gel filtration, hydroxylapatite chromatography, and hydrophobic chromatography on Phenyl Sepharose. These results indicate that either a single factor (designated thymocyte mitogenic factor) augments both humoral and cell-mediated immune responses or, alternatively, the different biologic activities are mediated by different factors that share a common core structure.     

Primary anti-trinitrophenyl memory cells investigated by plaque-forming cells and ELISA.

Primary anti-trinitrophenyl antibody production was investigated from spleen cells of mice immunized with trinitrophenylated-keyhole limpet hemocyanin, using the plaque-forming cell method and ELISA. Cells taken 5 days after antigen injection do not produce IgE, but do produce IgM and IgG1 anti-trinitrophenyl antibodies as demonstrated by plaque-forming cells. Substantial increase of IgM, IgG1, and IgE antibody production was seen from cells taken 7 days after immunization, followed by a rapid decline. By ELISA it was seen that cells taken 3 days after immunization already produce small amounts of anti-trinitrophenyl antibodies. Presence of antigen from the start of the cultures did not increase antibody production from cells taken 3 days after immunization, but potentiated antibody secretions from cells taken 5 days or later after immunization. This potentiation was interpreted as recruitment of antibody-forming cells from early memory B cells. The presence of IL-4 from the start of the cultures had no appreciable effect. Cell sorting with specific antibody-coated magnetic beads showed that plaque-forming cells from nonsorted cells, membrane IgE+ or membrane IgE- cells secreted similar amounts of anti-trinitrophenyl IgG1 and IgE antibodies. No difference in anti-trinitrophenyl IgM, IgG1, or IgE production was found in controls; cells sorted negatively or positively for CD23. The data show that memory B cells can be demonstrated already on Day 5 after immunization, and their antigen-induced antibody secretion is IL-4 dependent.     

Suppression of in vitro antibody responses by Listeria primed spleen cells.

Spleen cells from mice primed with virulent Listeria monocytogenes do not develop an anti-SRBC plaque forming cell response to SRBC in culture. Furthermore, when Listeria primed spleen cells are co-cultured with normal spleen cells and SRBC, the anti-SRBC response of the normal cells is suppressed. Listeria primed spleen cells from T cell depleted donors are equally effective at immunosuppression. The immunosuppressive effect does not appear to be due to the presence of the bacterium or its products per se in the cultures. Furthermore, the effect cannot be transferred across a 0.45 μm pore membrane. Kinetic studies show that the immunosuppressive effect develops by 2 days post-Listeria inoculation and peaks by Day 6. Low doses of Listeria are not immunosuppressive and produce some enhancement effect. From these results, it is suggested that a population of non-T cell dependent cells develop in Listeria primed hosts that nonspecifically suppress the response of B cells to an unrelated antigen in culture.     

Suppression of in vitro antibody response by ribosome-associated factor(s) from interferon-treated cells.

Initiation factor preparation (eIF-IF) from mouse L cells treated with virus-type interferon suppressed the in vitro plaque-forming cell (PFC) response to sheep red blood cells. The eIF-IF preparation had previously been shown to block formation of the ternary complex Met-tRNA_f-eIF-GTP. The formation of this complex is a necessary step in initiation of protein synthesis. Initiation factor preparation (eIF) from untreated L cells affected neither the PFC response nor the participation of eIF in the formation of ternary complex. The induced factor was shown not to be Interferon by antibody neutralization experiments with anti-interferon. The factor must be present in the PFC cultures during the early stages of antigen induction in order to suppress the immune response. Speculatively, eIF-IF may act at the level of the macrophage, perhaps entering the cell by pinocytosis. This may account for its inability to inhibit virus replication in L cells. The production of the inhibitory factor is blocked or partially blocked by actinomycin D. It is possible that this factor is a mediator of the immunosuppressive effects of virus-type interferon. This is the first report of biological activity on cells, which is associated with a ribosome-associated factor induced by interferon.     

Expression of IgG memory response in vitro to thymus-dependent and thymus-independent antigens

A model is described in which expression of IgG secondary antihapten responses of large magnitude can be initiated in vitro without resorting to in vivo boosting prior to culture. The number of IgG plaque-forming cells (PFC) is frequently as much as 100-fold greater than that of IgM PFC. Spleen cells from mice primed with trinitrophenylated keyhole limpet hemocyanin (TNP-KLH) several months earlier are stimulated in vitro to produce an anti-TNP plaque-forming cell response 7–10 days later. The in vitro IgG response can be elicited with either a thymus-dependent antigen (TNP-KLH) or thymus-independent antigens (TNP-T₄ bacteriophage or DNP-dextran). The kinetics of the responses to these two forms of antigen differ in that the thymus-independent response peaks two days earlier. The IgG response to both forms of antigen requires the presence of 2-mercaptoethanol (2-ME) even though macrophages are not depleted prior to culture. In the absence of the reducing agent both thymus-dependent and thymus-independent IgG responses were diminished ≥90%. The magnitude of the response to thymus-independent antigens emphasizes the ability of these materials to elicit IgG expression in memory B cells provided optimal conditions for memory development and in vitro expression exist.     

Composition of the immune system of allophenic mice.

Mice were immunized with antigen (Rabbit Fab' fragments) attached to syngeneic, or f₁ (semi-syngeneic) irradiated spleen cells. Specific anti-rabbit Fab' plaque forming cell numbers showed that the response towards antigen on syngeneic or F₁ cells, was significantly lower than that towards the same antigen on allogeneic cells. By subsequent in vitro incubation of immune spleen cells with antigen followed by plaque assay, it was found that those spleen cells exhibiting lowered plaque forming cell numbers initially, (i.e., those mice immunized with antigen on syngeneic or F₁ cell surfaces) showed, after incubation, a response equal to or greater than those cells which initially (before in vitro incubation) demonstrated a larger response (i.e. those mice immunized with antigen on allogeneic cells).