Measurement and comparison of the proliferative and antibody response of neonatal, immature and adult murine spleen cells to T-dependent and T-independent antigens.

Mouse spleen cell antigenic responses to the thymic-dependent antigen sheep red blood cells (SRBC), and the thymic-independent antigens, E. Coli lipopolysaccharide (LPS) and pneumococcal polysaccharides Type I and II (SI, SII) were studied as as a function of age, employing both in vitro spleen cell stimulation and plaque-forming cell (PFC) assay systems. Primary spleen cell proliferative and PFC responses to SRBC, were either absent or meager in comparison to adult (8–12 weeks) values for the first 3 weeks of life. Thereafter responses rose achieving adult values between 4 and 8 weeks of age. The inability of young mice to respond to SRBC was not because of a different immunizing dose requirement for SRBC, since immunization with SRBC over a 200-fold range did not enhance their capability to respond. Also, addition of adherent cells or macrophages from adult mice did not enhance the immune responses of young mice. Furthermore, immunization of 2–4 week old mice with SRBC inhibited the secondary response to SRBC. In contrast, young murine spleen cell proliferative and PFC responses to SI, SII, and LPS were approximately the same as the adult by 7–14 days of life. These data suggest that B-cell immunologic activity, as measured by immunologic assays utilized in this study, develops much earlier than does T-cell responsiveness.     

Higher ADCC of murine peritoneal cells after immunization with allogenic tumor cells as compared with stimulation by adriamycin, BCG, and thioglycolate

Normal peritoneal cells or spleen cells from C57BL mice could not lyse SRBC in an ADCC assay. After intraperitoneal injection of Adriamycin, BCG or thioglycolate the ADCC of peritoneal cells toward antibody-coated SRBC was elevated to 30% in contrast to the ADCC of spleen cells. However, peritoneal cells but not spleen cells of mice immunized with allogenic tumor cells (DBA SL2) showed ADCC levels at least two times higher than the levels observed after stimulation by other agents. Maximal ADCC levels (55.8%) were observed 10 to 15 days after immunization. Direct cytotoxicity towards SRBC increased to a maximum of 17.7% at 9 days after immunization. The effector cells in this system are thought to be macrophages, for ADCC activity was only present in the plastic-adherent cell fraction. Cell to cell contact was necessary for ADCC to occur; nonsensitized erythrocytes were not lysed when added to a mixture of effector cells and sensitized erythrocytes. Concentrations of antibody of 1 pg/ml were sufficient to induce ADCC, and effector cell to target cell ratios could be as low as 0.05. The finding that macrophages of mice immunized with allogenic tumor cells exhibit higher ADCC levels than macrophages elicited in other ways can contribute to the investigation of combined cancer therapy with antibodies and biological response modifiers.     

Monoclonal antibodies against human beta-glucocerebrosidase

Monoclonal antibodies were obtained against the membrane-bound lysosomal enzyme beta-glucocerebrosidase (acid beta-glucosidase), which is deficient in Gaucher's disease. BALB/c mice were immunized with homogeneous enzyme protein extracted from a sodium dodecyl sulphate/polyacrylamide gel. The mice were subsequently hyperimmunized with partially purified enzyme prior to fusion of spleen cells with myeloma cells. After fusion, 32 primary hybrid cell populations were obtained which continued to produce antibodies against beta-glucocerebrosidase after prolonged time of culture. All antibodies reacted with both native and denatured enzyme. Four primary cell populations were subcloned and the antibodies produced were characterized. The antibodies were all four of the IgG1 subclass. Three of these antibodies bind to protein A whereas one does not. The results of binding assays indicated that three of the antibodies react with the same antigenic domain (epitope 1), but the fourth with a different one (epitope 2). Probably two antigenic determinants are present in epitope 1 since one of the antibodies with specificity for epitope 1 is inactivated after iodination by the chloramine-T procedure whereas a second one is not.     

Deficiency in immunocompetence of mice cured from large MOPC-315 plasmacytomas by melphalan therapy

Summary Mice cured from large MOPC-315 tumors by a single dose of melphalan, 7.5 mg/kg, were examined for up to 60 days after the drug treatment (71 days after the tumor inoculation) for their ability to respond to mitogenic stimulation, specific and nonspecific antigenic stimulation and for their susceptibility to inoculation with an unrelated tumor, L10 lymphoma. The response of spleen cells from cured mice to mitogenic stimulation by phytohemagglutinin or concanavalin A was slightly depressed at an early stage after the drug treatment. The allogeneic response against C57BL spleen cells and the antibody response against sheep red blood cells (SRBC) of spleen cells from cured mice remained below normal levels during the whole observation period. The deficiency in response to antigenic stimulation was found to be due to impairment in T-cell function. Cured mice were also deficient in their response to SRBC immunization (antibody and delayed-type hypersensitivity responses) and were more susceptible to inoculation with an unrelated tumor, L10 lymphoma, than normal, noninoculated mice. On the other hand, spleen cells of cured mice developed a highly specific cytotoxic response against target MOPC-315 tumor cells and the cured mice were resistant to challenge with an otherwise highly tumorigenic dose of MOPC-315. Thus, cured mice remained deficient for a long period of time in their response to MOPC-315-unrelated antigens but, at the same time, they showed a potent specific antitumor immunity potential in vivo and in vitro.Presented in part at the Ninth European Immunology Meeting, September 14–17, 1988, Rome, ItalyThe contribution of S. Shoval is in partial fullfillment of a PhD Thesis     

Supressor activity of spleen cells during medically induced immunologic tolerance]

SRBC tolerance was induced in mice (CBA X C57BL/6) F1 by single intraperitoneal injection of 6 X 10(9) SRBC and of cyclophosphamide (100-200 mg/kg) in 44-46 hours. Spleen cells of tolerant mice obtained at various periods after the tolerance induction (in 12-26 days) failed to decrease their immune response to SRBC after administration to intact syngeneic recipients. Contrary to intact mice, tolerant animals were incapable of producing suppressor cells after a single SRBC immunization. Only when 3 additional injections of high SRBC doses (6 X 10(9)) were given to tolerant mice the spleen cells in them acquired the capacity to inhibit the immune response after administration to normal mice. It is supposed that the absence of suppressor cells in induction of the immunological tolerance by means of cyclophosphane was caused by the processes of clone elimination. Suppressor cells can originate in tolerant animals under the effect of intensive antigenic stimulation, this leading to enhancement of the tolerance state as a result of additional SRBC injections.     

Suppressive effect of nonviable Mycobacterium paratuberculosis on the delayed-type hypersensitivity reaction to sheep erythrocytes in mice.

The effect of nonviable Mycobacterium paratuberculosis on the delayed-type hypersensitivity reaction to sheep erythrocytes (SRBC) in mice was evaluated by means of delayed-type footpad swelling. Intraperitoneal (i.p.) injection with nonviable M. paratuberculosis into mice from 28 days before to 1 day after immunization with SRBC resulted in a significant suppression of foot-pad swelling to SRBC. The suppressive effect could be transferred by i.p. injection of spleen cells or peritoneal exudate cells from mice which had been pre-treated with nonviable M. paratuberculosis into non-treated recipient mice. The suppressive effect of spleen cells was retained even after passing them through a nylon wool column. The suppressive effect of spleen cells was abolished by treatment with anti-Thy 1.2 monoclonal antibody plus complement or anti-Lyt 2.2 monoclonal antibody plus complement. However, treatment of spleen cells with anti-mouse gamma globulin antiserum plus complement or anti-Lyt 1.2 monoclonal antibody plus complement did not affect the suppressive effect of spleen cells. The suppression of footpad swelling to SRBC induced by pre-treatment with nonviable M. paratuberculosis could be reversed by i.p. administration of cyclophosphamide. Serum antibody response to SRBC in mice was not affected by pre-treatment with nonviable M. paratuberculosis. These findings indicate that T cells appear to be involved in the suppression of delayed-type hypersensitivity reaction to SRBC in mice by pre-treatment with nonviable M. paratuberculosis.     

In vitro activation of suppressor cells from spleens of mice treated with radioactive strontium

Mice were treated with two 100-muCi injections of 89Sr to deplete marrow-dependent (M) cells. Mice so treated responded normally to immunization with sheep red blood cells (SRBC) in vivo; moreover, spleen cells from 89Sr-treated mice were able to respond to SRBC after infusion into irradiated recipient mice. However, spleen cells from mice treated with 89Sr did not respond to SRBC in vitro and mixtures of normal spleen cells with the latter were also not able to respond in vitro. The discrepancy between in vivo and in vitro responses was abolished by culturing spleen cells for 24 hr before testing their ability to respond to SRBC in the adoptive transfer in vivo. Pretreatment of spleen cells from 89Sr-treated mice with 1000 R of gamma-radiation lessened their suppressive activity. The suppressor cells were detected in spleens of athymic nude mice treated with 89Sr. The suppressive activity, after the 24-hr culture period, was not abolished by irradiation and was active in vivo as well as in vitro. Thus, depletion of M cells by 89Sr results in the appearance within the spleen of thymus-independent suppressor cells, which require a short period of in vitro cultivation before becoming functionally active.     

In vivo immune response suppression by the supernatant from concanavalin A-activated spleen cells.

Supernatants from concanavalin A- (Con A) activated murine spleen cells have been shown to suppress the in vitro plaque-forming cell (PFC) response to sheep red blood cells (SRBC). The present study examined the effect of such Con A-activated spleen cell supernatants (herein termed CONS) on the in vivo immune response to SRBC in C57BL/6, BALB/c and CDF1 mice. CONS derived from BALB/c spleen cells suppressed direct PFC 4 and 8 days after immunization with 2 X 10(8) SRBC. CONS also suppressed indirect PFC 8 days after immunization, as well as serum hemagglutinins to SRBC. The PFC response of C57BL/6 (H-2b) mice was suppressed as much as that of BALB/c (H-2d) by CONS derived from BALB/c mice, indicating a lack of H-2 specificity of the CONS. In addition to suppression of the antibody response to SRBC, in vivo CONS administration resulted in reduction in spleen cell number. This reduction was not sufficient to explain the decreased PFC response. When the CONS was separated into less than 10,000 m.w. and greater than or equal to 10,000 m.w. fractions, the immunosuppressive activity was found in the less than 10,000 m.w. fraction. This observation suggests that intact interferon, SIRS, and MIF were not responsible for the results obtained.     

The enhancement of the immune response by pain stimulation in mice. I. The enhancement effect on PFC production via sympathetic nervous system in vivo and in vitro

Effects of catecholamines and osmotical and physical stimuli on the induction of anti-sheep red blood cells (SRBC) plaque-forming cells (PFC) were investigated in (C57BL/6 X BALB/c)F1 mice in vivo and in vitro. The anti-SRBC PFC from mice immunized with 5 X 10(7) SRBC was markedly increased by daily s.c. injections of epinephrine. The enhancement of PFC by epinephrine was completely blocked by preadministration with propranolol and hexamethonium, but not with phentolamine. The PFC was increased by osmotic and physical stimuli given once a day for 4 days after immunization with SRBC. The enhancement of PFC by these stimuli was completely blocked by preadministration with propranolol and hexamethonium. The enhancement of PFC by physical stimuli was observed in nonimmunized mice when spleen cells from stimulated mice were cultured with SRBC in vitro. In normal mice, the enhancement of PFC was observed 2 hr after one physical stimulation. However, spleen cells from mice given two physical stimuli did not show the enhancement of PFC after treatment with anti-Thy-1.2 antibody and complement, nor after removal of nonadherent cells. Next, the serum obtained from mice 30 to 60 min after a physical stimulation enhanced PFC of normal mice spleen cells in vitro, but the enhancement was abolished by the addition of propranolol. The enhancement of anti-SRBC PFC by s.c. injection of epinephrine suggested that the autonomic nervous system, especially the sympathetic nervous system, was activated by a local stimulus effect of the injection. This enhancement of anti-SRBC PFC appear to be due to the activation of antigen non-specific helper T lymphocytes by the beta-actin of endogenous catecholamines from the adrenal gland.     

On the mechanism of early recovery of specifically depleted lymphoid cell populations by nonspecific activation of T cells.

Specific depletion from normal CBA mouse spleen cells of those bound on pigeon erythrocyte (PRBC) immunoabsorbent columns before transfer of the depleted population into irradiated syngeneic recipients resulted in elimination of the anti-PRBC responsiveness as assessed by rosette (RFC) and hemolytic plaque (PFC) formation. The anti-sheep erythrocyte (SRBC) responses of cell populations treated in the same manner remained unimpaired. When, however, these populations were stimulated with both PRBC and muramyl dipeptide (MDP), an early recovery of specific anti-PRBC responsiveness was produced. PFC response in particular, suddenly increased between the fourth and fifth day after transfer and stimulation thus exhibiting a doubling time of only 4 to 6 hr. This effect of MDP was T-cell dependent since treatment of the depleted population with anti-θ antigen serum and complement hindered early recovery. Depleted populations stimulated with PRBC alone resumed their T-dependent RFC (but not PFC) responsiveness after the eighth day. In spite of the existence of these educated T cells, a second stimulation on the tenth day with PRBC was unable to elicit a specific PFC response. On the other hand stimulation with MDP alone on the day of cell transfer (Day 0) followed by stimulation with PRBC on Day 10 resulted in a specific PFC response on Day 15. Thus, MDP appeared to do more than simply promote education of T cells by antigen. In vitro cultures of depleted populations also recovered their specific reactivity when stimulated by antigen and MDP.     

Difference in thymus dependency between effector and suppressor T cells for delayed footpad reaction to sheep erythrocytes in mice

Effects of thymectomy at various times after birth on effector and suppressor T cells for a delayed footpad reaction were determined in 6-week-old mice immunized intraperitoneally (ip) with sheep erythrocytes (SRBC). Mice thymectomized 1 day after birth (Tx-1 mice) gave delayed footpad reactions weaker than those of mice thymectomized 7 days after birth (Tx-7 mice) or sham operated (SH mice) after immunization with a low dose of SRBC. After immunization with a high dose of SRBC, on the other hand, Tx-1 mice showed reactions stronger than those of Tx-7 or SH mice. Pretreatment with cyclophosphamide (CY) augmented the delayed footpad reaction in Tx-7 or SH mice, but not in Tx-1 mice, immunized with a high dose of SRBC. The presence of T cells suppressive for the delayed footpad reaction in the spleen of Tx-7 or SH mice was confirmed by cell transfer experiments. These results suggest that effector T cells responsible for a delayed footpad reaction to SRBC are less thymus dependent and require the presence of the thymus for a shorter period in their development compared to suppressor T cells.     

A study of the mechanism of Con A-induced immunosuppression in vivo

The plaque-forming cell (PFC) response to sheep erythrocytes (SRBC) is suppressed in a dose-related manner when concanavalin A (Con A) is administered intravenously to mice prior to or after immunization with antigen. The magnitude of suppression as well as the duration of the Con A effect greatly depends on the concentration of antigen used for immunization. Although profound suppression of the anti-SRBC PFC response is observed in intact mice pretreated with Con A for 4-24 hr, spleen cells from these mice do not exhibit suppressive activity when transferred into normal recipients or when cotransferred with normal spleen cells into irradiated recipients. Moreover, the cells from Con A-treated mice respond as normal spleen cells to SRBC when transferred alone into irradiated hosts. Suppression of the anti-SRBC PFC is only observed when adoptive hosts of cells from Con A-treated mice are also injected with Con A within 48 hr (but not 72 hr) of cell transfer and immunization. This time course of responsiveness to the suppressive effects of Con A is similar to that observed in normal mice and in irradiated recipients of normal spleen cells. The immune response to SRBC is also suppressed in adoptive hosts of normal spleen cells that are pretreated with Con A 4-24 hr prior to irradiation and cell transfer. Although functionally inactive when transferred into adoptive hosts, spleen cells from mice pretreated with Con A for 4-24 hr can suppress a primary antibody response to SRBC in vitro. The suppressive activity, which cannot be detected in the spleens of mice when the interval between pretreatment and assay is longer than 24 hr, is present in a subpopulation that bears the Thy 1.2 and Lyt 2 phenotype. Taken together the results obtained in in vivo and in vitro functional assays suggest that a suppressor cell population is activated following in vivo treatment with Con A, but that the cells rapidly lose their state of activation when removed from a Con A environment. This phenomenon is in all probability responsible for the failure to demonstrate suppressive activity in the spleens of Con A-treated mice using in vivo functional assays.     

Analysis of certain mechanisms of antigen-specific suppression of the immune response

CBA mice were immunized with sheep red blood cells (SRBC) to obtain immune spleen cells (ISc) which were used to suppressor cells. Administration of ISC to intact syngeneic recipients on the immunization day led to a more powerful suppression of the immune response as compared to that seen one day after antigen injection. Four days after immunization the animals' immune response was not liable to be suppressed. ISC extract possessed similar effects with respect to the immune response of normal spleen cells which were transplanted to the cyclophosphamide-treated recipients. The immune response of spleen cells from mice immunized with SRBC in a dose of 10(6) was less liable to be suppressed. Hyperimmune spleen cells from donors immunized with SRC in a dose of 10(9) were insensitive to ISC or to the extract. Experiments with the use of adoptive transfer of a mixture of immune and intact T- and B-cells have disclosed that B-cells from hyperimmune donors were resistant to suppression. Therefore, B-lymphocytes are the most probable target cells exposed to T-suppressors in the given system. The mechanism is discussed of the selective effect of T-suppressors on B-cells in the course of the immune response development during immunization with high doses of antigen.     

Suppressive effects of co-stimulatory molecule expressions on mouse splenocytes by anti-allergic agents in vitro

The influence of anti-allergic drugs, epinastine hydrochloride (EP) and disodium cromoglycate (DSCG), on the co-stimulatory molecule expression was examined using in vitro cell culture technique. Spleen cells obtained from BALB/c mice 10 days after immunization with haemocyanin absorbed to aluminium hydroxide were cultured in the presence of 100.0 microg/ml haemocyanin and various concentrations of the agents. Low concentrations (<1.5 x 10(-4)M) of EP and DSCG did not influence spleen cell blastic activity induced by antigenic stimulation, whereas these agents caused significant inhibition of spleen cell activation when 2 x 10(-4) M of the agents were added to cell cultures. EP and DSCG also did not affect blastic activity of sensitized splenic T cells by anti-CD3 monoclonal antibody stimulation even when these cells were cultured in the presence of 2 x 10(-4) M of the agents. We next examined the influence of EP and DSCG on the expression of co-stimulatory molecules on spleen cells in response to antigenic stimulation. Sensitized spleen cells were cultured in the presence of 2 x 10(-4)M of the agents and the expression of molecules were examined by flow cytometer 24h later. EP and DSCG suppressed the expression of costimulatory molecules, CD40 and CD80, but not CD86, on splenic B cells which were enhanced by antigenic stimulation in vitro.     

Immunosuppressive Effect of Bacterial Lipopolysaccharide on Antibody Response

Injection of endotoxins (bacterial lipopolysaccharide: LPS) several days prior to immunization causes the suppression of antibody response. The suppressive effects of several kinds of LPS preparations on the plaque-forming cell (PFC) antibody response in the spleen of mice were examined after immunization with sheep red blood cells (SRBC). Glycolipids obtained from heptoseless mutants (Re form) of salmonella or its lipid A preparation coupled artificially with bovine serum albumin (BSA) are capable, like LPS obtained from a wild type (S form) strain, of inducing suppression of the PFC response, while alkaline-detoxified LPS can not. The refractory periods of the PFC response induced by LPS injection last only a few days. However, the use of cyclophosphamide (CY) together with LPS can extend the refractory periods of antigenic stimulation for several weeks. Injections of LPS and CY can also induce unresponsive states of OH agglutinin antibody response to antigenic stimulation with formalin-killed organisms of Escherichia coli or Salmonella enteritidis (presumably both thymus-independent antigens). These unresponsive states induced by LPS and CY are easily terminated by a transfer of syngeneic bone marrow cells but not by thymocyte transfer.     

Difference in genesis between antigen-induced IgM antibody-forming cells and B-cell mitogen-induced IgM antibody-forming cells in mouse spleen cell cultures.

To determine the mechanisms in the triggering of thymus-independent lymphocytes (B cells) for development into antibody-forming cells (AFC), genesis of IgM AFC elicited polyclonally by nonspecific stimulation with B-cell mitogen, such as nystatin and bacterial lipopolysaccharide, was compared with that of IgM AFC specifically elicited by antigenic stimulation, using mouse spleen cell cultures as an experimental system and sheep erythrocytes (SRBC) as a test antigen. Considering that differentiation and proliferation are necessary cellular events for precursor B cells to develop into AFC, the effect of different antimetabolic agents on the generation of each type of AFC in spleen cell cultures was examined. The generation of anti-SRBC IgM hemolysin plaque-forming cells (PFC) in B-cell mitogen-stimulated spleen cell cultures was found to be less susceptible to X-irradiation or mitomycin C than that in the SRBC-stimulated cultures. These apparently paradoxical results were affiirmed using colcemid as an inhibitor of cell mitosis and hydroxyurea (HU) as an inhibitor of cellular DNA synthesis. Thus, when spleen cell cultures responding to either SRBC or B-cell mitogen were exposed to colcemid or HU during a period from 2 days to 3 days after the stimulation, the exponential generation of anti-SRBC IgM PFC in the cultures responding to SRBC was completely halted, whereas that in the cultures responding to B-cell mitogen was not. Furthermore, N⁶, O^2′ -dibutyryl adenosine 3′, 5′ -cyclic monophosphoric acid was found to halt the exponential generation of antigen-induced anti-SRBC IgM PFC but not that of the B-cell mitogen-induced anti-SRBC IgM PFC. From these results it was suggested that B-cell mitogen might stimulate precursor Bμ cells at a late stage in the differentiative pathway to develop into AFC without cell division, and that antigenic stimulation might stimulate relatively primitive precursor Bμ cells to proliferate and then differentiate into AFC. Based on this idea, mechanisms in the triggering of B-cell activation are discussed.     

Studies on the adjuvant effect of Bordetella pertussis vaccine to sheep erythrocytes in the mouse. I. In vitro enhancement of antibody formation with normal spleen cells.

The adjuvant effect of Bordetella pertussis vaccine (PV) on the antibody response to sheep erythrocytes (SRBC) has been studied in vitro with the Mishell-Dutton immunization technique. The addition of PV to cultures of spleen cells obtained from normal non-immunized mice markedly enhanced the plaque-forming cell response to SRBC. The greatest enhancement was evident at 24 hr of culture. PV was also shown to enhance the antibody response of spleen cells that had been depleted of either T lymphocytes or adherent cells, presumably macrophages. In addition, it was found that PV, per se, released into the culture medium a soluble cell-free component(s) that contributed significantly to adjuvanticity. The results suggest that at least one of the ways that PV enhances the in vitro immune response to SRBC is by direct stimulation of precursors of antibody-forming cells.     

Specificity,avidity, and size of B-lymphocyte populations during ontogeny

The size and specificity of plaque-forming cell precursors (PFC) in murine fetal liver, neonatal, and adult spleen were studied in an adoptive transfer system. In this system, anti-4-hydroxy-3-iodo-5-nitrophenylacetic acid (anti-NIP) and anti-2,4,6-trinitrobenzene sulfonic acid (anti-TNP) direct PFC are generated from bone marrow-derived (B) cell precursors in fetal liver between 17 and 20 days of gestation and in 6- or 14-day neonatal spleen. PFC generated from fetal liver and neonatal and adult spleen cells are specific in that they lyse either NIP-coupled SRBC or TNP-coupled SRBC but not both. The generation of specific anti-NIP and anti-TNP PFC from precursors in fetal liver is primarily independent of antigenic stimulation. In contrast, the anti-NIP and anti-TNP responses generated from neonatal and adult spleen are antigen dependent. Both high-avidity PFC (detected with SRBC indicators coupled at low hapten density) and low-avidity PFC (detected with SRBC coupled at high hapten density) are generated from fetal liver and neonatal spleen cells; however, the proportion of high-avidity PFC precursors in adult spleen is at least threefold greater than in fetal liver or neonatal spleen. Analysis by velocity sedimentation indicates that most high-avidity PFC precursors are small lymphocytes in fetal liver, medium lymphocytes in 6-day neonatal spleen, and small lymphocytes in 14-day-old and adult spleen. Low-avidity PFC precursors are primarily medium-sized lymphocytes in fetal liver and 6-day neonatal spleen. In 14-day-old and adult spleen almost all high- and low-avidity PFC precursors are small lymphocytes. The results are discussed in terms of relative changes in the pool sizes of these lymphocyte populations.     

Suppression of heterologous immunity by Nematospiroides dubius antigens in vitro

The direct effect of the soluble antigens in the homogenate of adult Nematospiroides dubius (AH) on spleen cells from uninfected NIH mice was investigated using a Mishell-Dutton culture system. Parasite antigens were shown to reduce the plaque-forming cell (PFC) response to sheep red blood cells (SRBC) in a dose-dependent manner in vitro. A population of suppressor cells was demonstrated in the spleens of infected mice. Furthermore naive spleen cells cultured in the presence of AH gave rise to cells which depressed the PFC response of naive cells when subsequently cultured together in vitro. Treatment of these cell populations with anti-thy 1.2 plus complement did not impair suppressor activity, and it was concluded that cells expressing the T-cell phenotype were not involved.     

Mechanism of the suppressive effect of interferon on antibody synthesis in vivo.

Mouse interferon preparations significantly suppress the in vivo antibody response to sheep red blood cells (SRBC), a thymus-dependent antigen, and to Salmonella typhimurium lipopolysaccharide (LPS), a thymus-independent antigen. It is also possible to effect the late responses of antigen sensitive "memory" cells observed during secondary immunization by administration of interferon prior to primary immunization. The immunosuppressive activity of interferon was time- and dose-dependent. Maximum suppression was produced when animals were given 1.5 times 10-5 units of interferon between 4 and 48 hr before antigenic stimulation. These findings suggested that interferon affects some early event(s) in the process of antibody synthesis which might be related to the general inhibitory effect of interferon on rapidly dividing cells and viral m-RNA translation. In addition, the use of nonadherent spleen cell cultures from interferon-treated mice, immunized in vitro with a thymus-independent antigen, indicated that in this situation the inhibitory effect of interferon was due to an action on B lymphocytes. A variety of soluble "suppressive" factors are secreted by T cells as a consequence of activation by mitogens or specific antigens in vitro. Since T cells are recognized as one of the sources of interferon, it is suggested that interferon should be investigated as a suppressor T cell-produced lymphokine which can regulate B cell expression.