Combinations of two synthetic adjuvants: synergistic effects of a surfactant and a polyanion on the humoral immune response

Synergistic effects of two synthetic adjuvants, dimethyldioctadecylammonium bromide (DDA) and dextran sulfate (DXS) on the humoral response to sheep red blood cells (SRBC) were investigated. Mice received intraperitoneal (ip) injections of adjuvant and antigen simultaneously. The number of plaque-forming cells (PFC) in the spleen were determined 5 days later and circulating anti-SRBC antibodies were measured till 16 weeks after immunization. Although combinations of DDA and DXS were very effective in enhancing the PFC response to both moderate (2 X 10(7] and low (2 X 10(6] doses of SRBC, synergy between the adjuvants was only observed at the low dose of SRBC. Optimal augmentation of the primary response to the low antigen dose was evoked by the combination of the highest dose tested of either adjuvant (1 mumol DDA and 1 nmol DXS) resulting in a 560-fold increase of the number of PFC in the spleen as compared to controls. Even combinations of relatively small amounts of both adjuvants were very effective in augmenting the response to SRBC. Mice receiving half the amounts of both adjuvants with 2 X 10(6) SRBC displayed increased numbers of PFC in the spleen at Day 5 as well as increased titers of total anti-SRBC antibodies at Week 1 and Week 2 and 2-mercaptoethanol-resistant antibodies from Week 4 till Week 16 as compared to the calculated sum of responses in mice which received either DDA (0.05 mumol per mouse) or DXS (0.05 nmol per mouse). The mechanism behind the synergy between these adjuvants is discussed and the possibility of discerning adjuvants on their modes of action is suggested.     

Effect of thymocytes on the quantity of polypotent hematopoietic mast cells in the spleen of sublethally irradiated mice]

With the aid of Till and McCulloch's method, 5 times 10(-6) thymic cells were found to cause an increase in the number of hemopoietic endogenous spleen colonies in syngeneic donor-recipient combination. Thymic cells of C57BL mice had no effect on the number of endogenous colonies in the spleen. 40 times 10(-6) thymic cells administered 24 hr after sublethal irradiation caused an increase in the number of colony forming units in the spleen within 14 days. Possible ways of the thymus effect on hemopoiesis are discussed.     

A reverse effect of in vitro and in vivo concanavalin A-induced spleen cells on anti-sheep red blood cells response detected with a new method based on flow cytometry

A simple flow cytometric method for detecting humoral immunity against sheep red blood cells (SRBC) is described. The SRBC were incubated with the serum from SRBC-immunized mice, monoclonal anti-SRBC, or the supernatant which was obtained from the in vitro primary culture of spleen cells with SRBC. The antibodies which bound to SRBC were estimated by means of an immunofluorescence and a flow cytometry. When the channel number of the peak in the histogram of flow cytometry was measured as an index of fluorescence intensity of SRBC, the number significantly correlated with the concentration of IgM and IgG classes of anti-SRBC. The flow cytometry method and hemagglutination (HA) test, as a classic method, were compared in SRBC-immune sera and monoclonal anti-SRBC antibody. The sensitivity determined with flow cytometry was much higher than that with HA. The minimum detectable concentration of anti-SRBC antibody was found to be 3.4 ng/ml by the flow cytometry. The dose response of SRBC in in vitro primary culture was detected by the flow cytometry, not by HA, and the response increased with the dose of SRBC. Using this method, the effect of in vitro and in vivo concanavalin A (Con A)-induced spleen cells on humoral response against SRBC was examined in an in vitro culture system. Anti-SRBC response (IgM and IgG) was found to be suppressed by in vitro Con A-induced lymphocytes, but enhanced by in vivo Con A-induced lymphocytes. Thus, this new approach is found to be a good method for detecting the in vitro primary humoral antibody response, which is known to have a low reactivity.     

Stimulating action of Brucella melitensis lipopolysaccharide on hemopoiesis in mice

The bacterial mass, brucellar protective antigen and lipopolysaccharide (LPS) obtained from B. melitensis stimulated the formation of endogenous colonies in the spleen of mice belonging to different strains, subjected to irradiation in sublethal doses. The maximum stimulating effect was observed when the antigens were introduced 24 hours prior to irradiation. LPS introduced in the optimal dose induced an increase in the number of hemopoietic stem cells (HSC) in the s-phase of the cell cycle, thus stimulating the postirradiation survival of mice irradiated in a lethal dose. 24 hours after the injection of LPS the total number of HSC in the spleen increased 1.5 times. These data indicate that LPS has a stimulating effect on hemopoiesis in mice. The effect rendered by LPS is seemingly linked with an increase in the proliferation of HSC and, to a lesser extent, depends on changes in the migration of HSC.     

Delayed-type hypersensitivity (DTH) in BCG-sensitized mice I. Lack of suppressor T cell activity on DTH to sheep red blood cells.

Mice pretreated with an intravenous (i.v.) injection of BCG (BCG-sensitized mice) and then immunized intravenously with a high dose (10(8)--10(9)) of sheep red blood cells (SRBC) 2 weeks later developed strong delayed-type hypersensitivity (DTH) to SRBC, as in mice pretreated with cyclophosphamide (CY) (CY-treated mice) and then immunized with SRBC 2 days later; normal mice given the same dose of SRBC did not show such DTH. The mechanism of this strong DTH to SRBC which developed in BCG-sensitized mice was studied, by comparing it with that in CY-treated mice. The transfer of either whole spleen cells or thymus cells, but not serum, obtained from mice immunized with i.v. injections of 10(9) SRBC 4 days previously (hyperimmune mice) did not suppress either the induction or the expression of DTH to SRBC in BCG-sensitized mice, but suppressed those in CY-treated mice. The suppressor cells were SRBC-specific T cells. Adoptive transfer of DTH to SRBC by spleen cells from either BCG-sensitized mice of CY-treated mice to hyperimmune recipients failed. The adoptive transfer of DTH from BCG-sensitized mice to normal recipients also failed if the spleen cells from hyperimmune mice were cotransferred. Whole body irradiation (600 rad) of mice 2 hr before or after the time of immunization with SRBC reduced significantly DTH to SRBC in both BCG-sensitized and CY-treated mice. It was noticed that the total number of spleen cells in BCG-sensitized mice was 3--4 times larger than that in CY-treated mice. From these results, we conclude that the entity of effector T cells of DTH to SRBC induced in BCG-sensitized mice and in CY-treated mice was not different in terms of susceptibility to suppressor T cells and irradiation, but that the total numbers of effector T cells generated in these mice differed remarkably, resulting in the above-described different responsiveness to suppressor T cells transferred passively.     

Immune response of the Mongolian gerbil (Meriones unguiculatus) to sheep red blood cells.

The immune responses of Mongolian gerbils, Meriones unguiculatus, to sheep red blood cells (SRBC) were studied as compared to those of mice. After a single injection of SRBC, hemagglutinin titers in gerbils were significantly lower and hemolytic plaque-forming cells (PFC) in the spleen were less in number as compared to the response of mice. In gerbils the PFC response to a higher dose of bacterial lipopolysaccharide (LPS) was rather higher than in mice. The delayed-type hypersensitivity (DTH) assay on the foot-pad revealed that the responsiveness was considerably lower in gerbils than in mice.     

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.     

Phenomenon of parental resistance and its genetic regulation]

Lymphocytes of mice F1 (CBA X M523) and F1 (A X M523) transplanted to 1000 R irradiated CBA or A mice responded to the test antigens--SRBC or S. typhi Vi-antigen--by formation of 100--1000 times less antibody forming cells than in syngeneic recipients. An intermediate result is achieved when the lymphoid cells are transplanted to the irradiated M523 mice. Lymphocytes of mice F1 (A X CBA), F1 (CBA X C57Bl/6), or F1 (A X A.CA) developed a similar immune response in the irradiated syngeneic mice and in both parental lines. The ability of parental line M523 to respond to SRBC was the same as in the other lines studied when examined in situ or in adoptive transfer experiments. The stem hemopoietic cells of mice F1 (CBA X M523) develop in the spleen of CBA mice 2--2.5 times less hemopoietic colonies than in the spleen of syngeneic animals. A conclusion was drawn that mutation M523 in CBA mice inhibited the proliferation and differentiation of hemopoietic and lymphoid cells in the irradiated nonsyngeneic recipients.     

B-Lymphocyte differentiation in lethally irradiated and reconstituted mice. II. Recovery of humoral immune responsiveness.

The recovery of humoral immune responsiveness was studied in lethally irradiated, fetal liver-reconstituted mice. By means of both membrane fluorescence and antibody formation to sheep red blood cells (SRBC) as a functional assay, the rate of recovery of the compartments of B and T lymphocytes was determined in various lymphoid organs. The recovery of the immunoglobulin-positive (B) cell compartment after irradiation and reconstitution started in the spleen. This organ was also found to be the first in which the recovery of the B-cell population was completed. The interval between the recovery of the B-cell population in the spleen and that in the other organs tested was found to increase when the irradiated mice were reconstituted with spleen colony cells instead of fetal liver cells. This proved to be caused by the number and nature of the reconstituting hemopoietic stem cells. The immunoglobulin-positive (B) cells were found to appear before SRBC-reactive B cells could be demonstrated in spleen, lymph nodes, and Peyer's patches. The appearance of T lymphocytes in the various lymphoid organs required even more time. By means of cell transfer experiments, a sequential appearance of the precursors of anti-SRBC IgM-, IgG-, and IgA-plaque-forming cells could be demonstrated in spleen, bone marrow, lymph nodes, and Peyer's patches.     

B-cell suppression of antibody response to sheep red blood cells in mice of high- and low-responding genotypes.

CBA and C57B1 mice (high and low responders to sheep red blood cells, respectively) were injected intravenously with syngeneic lymph node, marrow, spleen, or thymus cells together with sheep red blood cells (SRBC), and the production of antibody-forming cells (AFC) was assayed in the spleen. Transfer of lymph node, marrow, spleen, or thymus cells led to a significant enhancement of immune responsiveness in low-responding C57B1 mice. In contrast, transfer of marrow, lymph node, or spleen cells to high-responding CBA mice was accompanied by a decline in AFC production. These effects were magnified if syngeneic cell donors had been primed with SRBC; suppression in CBA mice and stimulation in C57B1 mice were especially pronounced after transfer of SRBC-primed lymphoid cells. Pretreatment of CBA donors with cyclophosphamide in a dose causing selective B-cell depletion completely abrogated the suppression of immune responsiveness. A large dose (10⁷) of syngeneic B cells injected together with SRBC suppressed the accumulation of AFC in both CBA and C57B1 mice. No suppression of immune responsiveness was observed after transfer of intact thymus cells, hydrocortisone-resistant thymocytes, or activated T cells. We conclude that suppression of the immune response to SRBC is induced by B cells. At the same time, there is a possibility that the addition of “excess” B cells acts as a signal, triggering suppressor T cells.     

In vitro development of a primary antibody response with lymph node cells.

Utilizing a variety of lymphoid tissues from three common laboratory species, comparative studies were performed to investigate the competence of the dissociated cells to respond to a heterologous erythrocyte with the development of specific plaque-forming cells. Dissociated spleen cells harvested from BDF1 mice consistently developed specific plaque-forming cells (PFC) to sheep red blood cells (SRBC), while hamster spleen cells inconsistently developed specific antibody-forming cells to SRBC. Under identical conditions, guinea pig spleen cells did not develop significant numbers of PFC to SRBC. However, lymph node cell cultures of all three species tested yielded specific PFC. In the mouse and hamster lymph node cell cultures, the yield of PFC per culture or per 10⁶ recovered viable cells was always greater than the yield from companion spleen cell cultures. Guinea pig mesenteric lymph node cell cultures developed the major PFC response to SRBC, while both mesenteric and peripheral lymph node cell cultures from hamsters were equivalent in their response to SRBC. The data demonstrate that it is possible to develop a primary antibody response to SRBC in vitro utilizing normal endogenous hamster or guinea pig lymphoid cells, if lymph nodes are the source of cells.     

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.     

Formation of hematopoietic colonies of the donor type in the bone marrow of irradiated chickens after transplantation of the cells of the yolk sac and hindlimb of the quail embryo]

The ability of yolk sac and primary bone marrow cells of the quail to form hemopoietic colonies at 6 hours of incubation (i. e. before establishment of circulation) was studied in the bone marrow of 3-week sublethally irradiated chickens. The experiments were based on the possibility of differentiating between quail and chicken cells from the natural cell marker (Pheulgen-positive nucleolus). The number of hemopoietic colonies produced by cells transplanted from the primary bone marrow was three times greater than that consequent on transplantation of yolk sac cells. With the given dose of irradiation the bone marrow shows about 75% exogenous (quail) and 25% endogenous (chicken) hemopoietic colonies.     

Studies of mouse immunoglobulin allotypes by reverse plaque assay: Detection of spleen cells secreting immunoglobulins with specific allotype in C57BL/6J mice

A reverse hemolytic plaque assay for the detection and enumeration of mouse spleen cells secreting immunoglobulins bearing a particular allotypic specificity is described. Sheep red blood cells (SRBC) coated with protein A or anti-mouse gamma globulin antibody were employed as indicator cells and an anti-allotype antibody was used as developer. A comparison of the efficiency of protein A, goat anti-mouse or rabbit anti-mouse gamma globulin antibody-coated SRBC as indicator cells in the plaque assay indicated that the rabbit anti-mouse gamma globulin-coated SRBC gave the best results in terms of number and morphology of the plaques. The number of indicator cells in the assay mixture also significantly affected the quality of the plaques formed. When the mouse spleen cells were assayed with the indicator cells and an anti-allotypic antibody as developer in presence of complement in a liquid medium, only those cells secreting the immunoglobulin of the given allotypic specificity formed hemolytic plaques.     

In vitro activation of the in vivo colony-forming units of the mouse yolk sac.

Experiments were performed to investigate the presence of colony-forming units (CFU) in the mouse embryonic yolk sac during the developmental period in which the yolk sac is the sole hemopoietic organ. Injection of yolk sac cell suspensions from normal embryos into syngeneic, lethally irradiated adult recipients evoked a very low number of spleen colonies. However, prior cultivation of yolk sacs in vitro caused a dramatic increase in the spleen colony-forming capacity--as high as 84-fold--following 48 hours in culture. The yolk sac origin of the spleen colonies was confirmed by: (a) Chromosomal marker analysis; (b) dose-response analysis; (c) demonstrating that the above colonies were not of endogenous origin induced by the mere injection of grafted cells. We conclude that the yolk sac contains many precursors of colony-forming cells which though undetectable by immediate grafting apparently become activated in culture by an as yet unknown induction process.     

Granulocyte colony-stimulating factor and drugs elevating extracellular adenosine act additively to enhance the hemopoietic spleen colony formation in irradiated mice.

The effects of combined administration of two drugs elevating extracellular adenosine, namely dipyridamole (DP) and adenosine monophosphate (AMP), and granulocyte colony-stimulating factor (G-CSF) on hemopoietic stem cells in vivo were investigated. The experiments were performed on mice using the endogenous spleen colony formation in gamma-irradiated animals as an endpoint. The results have shown that DP and AMP act additively with G-CSF to enhance spleen colony formation and thus the erythroid repopulation of the spleen. These findings indicate that the signaling pathways of G-CSF and drugs elevating extracellular adenosine can interact at the level of primitive hemopoietic stem cells. The enhancement of hemopoiesis-stimulating effects of G-CSF by DP and AMP, which are low-priced and clinically available drugs, could improve the cost-effectiveness of the therapy with G-CSF.     

Time-dependent mode of immunization augments suppressed antibody responses in spleen cell cultures from mice experimentally infected with Trypanosoma cruzi

Mice infected with Trypanosoma cruzi develop immunosuppressed responses to heterologous antigens. Experiments were performed using infected mice in the acute stage of infection to assess immunoregulatory activities during induction of direct plaque-forming cells (DPFC) to sheep erythrocytes (SRBC). After normal or infected mice were primed with SRBC, their spleen cells were restimulated 4 days later with SRBC in Mishell-Dutton cultures and found to mount hyperaugmented IgM anti-SRBC responses. It was also demonstrated that T-cells derived from normal mice primed in vivo 4 days previously with SRBC, and subsequently added to cultures of spleen cells from T. cruzi-infected mice, enhanced anti-SRBC DPFC responses in a dose-dependent fashion. These results show that functional help provided by T-cells activated during an in vivo priming and exposed to an in vitro challenge dose of antigen (SRBC) in a time-dependent mode can overcome the effect of immunosuppression in the spleen cell cultures from T. cruzi-infected mice.     

Mechanisms of lymphocytic choriomeningitis virus-induced hemopoietic dysfunction.

Results of this study showed that lymphocytic choriomeningitis virus infection causes a marked activation of natural killer (NK) cells not only in the spleen but also in the bone marrow. This activity reached its peak at about day 3 of infection and declined after days 6 to 7. Enhanced NK cell activity was found to correlate with decreased receptivity for syngeneic stem cells in bone marrow and spleen, with the notable exception that decreased receptivity persisted longer in bone marrow. Treatment of infected recipients with anti-asialo GM1 (ganglio-N-tetraosylceramide) significantly increased the receptivity for syngeneic hemopoietic cells. These findings are consistent with the hypothesis that NK cell activation causes rejection of syngeneic stem cells, thus resulting in hemopoietic depression. To understand the mechanisms behind the prolonged decrease in bone marrow receptivity (and bone marrow function in the intact mouse) mentioned above, we followed the changes in the number of pluripotential stem cells (CFU-S) circulating in the peripheral blood and in endogenous spleen colonies in irradiated mice, the limbs of which were partially shielded. It was found that following a marked early decline, both parameters increased to normal or supranormal levels at about day 9 after infection. Because the bone marrow pool of CFU-S is only about 20% of normal at this time after infection, a marked tendency for CFU-S at this stage in the infection to migrate from the bone marrow to the spleen is suggested. It seems, therefore, that as NK cell activity declines, the spleen regains the ability to support growth of hemopoietic cells and the bone marrow resumes an elevated export of stem cells to the spleen. This diversion of hemopoiesis could explain both the long-standing deficiencies of the bone marrow compartment and the prolonged decrease in the receptivity of this organ.     

Dose-dependent induction of immunologic enhancement and suppression after oral administration of antigen

The effects of feeding various quantities of a particulate antigen, sheep red blood cells (SRBC), on plaque-forming cells (PFC) in the spleen were determined. Mice were given various numbers of SRBC orally daily for 14 days, then injected with SRBC intravenously. Splenic IgA PFC responses to SRBC were enhanced in the mice fed 5 X 10(8) SRBC and splenic IgG PFC responses to SRBC were depressed in the mice fed 5 X 10(9) SRBC. Adoptive transfer experiments showed that enhancement of splenic IgA PFC responses and suppression of splenic IgG PFC responses were induced by the T-cell rich fraction from Peyer's patches (PP) and the spleen in 5 X 10(8) SRBC- and 5 X 10(9) SRBC-fed mice, respectively. Kinetic studies revealed that IgA helper cells or IgG suppressor cells appeared in PP 2 days after oral administration and 4 days after it in the spleen.     

Immunosuppressive effect of Entamoeba histolytica extract on hamsters

The immune response to sheep red blood cells (SRBC) in mice and hamsters injected with an extract of entamoeba histolytica was studied. Both the primary and secondary immune response, measured by anti-SRBC antibody titers, were unaltered in the mouse, while a significant depression of the primary, but not the secondary, response was observed in the hamster. The effect was greatest when the amebic extract (AE) and SRBC were injected on the same day. The number of anti-SRBC rosettes formed in the spleen cells of hamsters treated with both AE and SRBC on day 0 was measured from days 1-16. The response peaked on day 13, while cells from animals injected with SRBC alone gave a maximal response on day 5. The formation of anti-SRBC rosettes in T-lymphocyte-enriched spleen cells treated with anti-gamma globulin serum and complement was almost abolished for the duration of the experiment. It is suggested that the mechanism responsible for this immunosuppressive phenomenon could involve early interference in the afferent limb of the immune response.