Suppression of a thymus dependent humoral response in mice by concanavalin A in vivo

Mice treated with Concanavalin A prior to immunization with sheep erthyrocytes exhibit a markedly reduced plaque forming spleen cell response. This immunosuppressive effect could be reversed by using higher doses of antigen or priming the animals with nonimmunizing doses of antigen prior to Concanavalin A injection designed to either by-pass or enhance thymus derived lymphocyte functions. It was also demonstrated that Concanavalin A in vivo activated the thymus derived lymphocyte subpopulation in the spleen, and this activation was dose dependent and correlated with the immunosuppression observed. Animals injected with Concanavalin A at various times prior to whole body lethal irradiation would not support the plaque forming cell response of adoptively transferred normal syngeneic spleen cells. This effect was shown to be time and dose of Concanavalin A dependent. It was also shown that the route of injection of Concanavalin A prior to irradiation determined the results observed, in that the intravenous route resulted in the suppression of transferred cells, while the intraperitoneal route showed no effect. It is suggested that Concanavalin A induced immunosuppression of the humoral, thymus dependent immune response in mice results for the activation of a subpopulation of thymus derived suppressors cells, and that the effect is short lived, radiation resistant, and dose of Concanavalin A and antigen dependent.     

Passive administration of antibodies during the primary immunization. The influence on the secondary response

Groups of mice were injected with different quantities of sheep red blood cells (SRBC: 10⁸, 10⁹ and 10¹⁰) and simultaneously with different quantities of antibodies against SRBC. The response was tested 15 and 30 days after the primary dose and 4 days after the secondary response. The action of antiserum regulates the quantity of antigen available for the immunization process. With a large dose of antiserum it is possible to inhibit the primary, as well as the secondary response. A smaller dose of antiserum suppresses primary antibody formation but the process of preparing the secondary response is not inhibited. An inhibitory dose of antiserum injected 24 and 48 hours after antigen significantly depresses the primary response but is followed by a pronounced secondary response. When the antigen is bound 24 and 48 hours after the primary stimulus, the secondary response is only of the 19S type. If the antigen is present at least 72 hours after the primary dose of antigen cells forming 7S antibodies appear also in the secondary response. Experimental data support the hypothesis that there is a common precursor cell for the 19S and 7S Ab-forming cell; during limited proliferation the cellular basis for the 19S secondary response and with intensive proliferation (only after 6 or 7 generations) the precursors for 7S antibody forming cells, appear. Dedicated to Academician Ivan Málek on the occasion of his 60th birthday     

Mechanisms of antibody formation: I. Early in vivo proliferation of mouse spleen T cells as an initial step in antibody formation

Spleen cultures prepared from mice injected 24 hr earlier with 2 × 10⁶?2 × 10⁸ sRBC and challenged in vitro with sRBC produced 10 times more anti-sRBC IgM PFC than cultures prepared from uninjected mice. The effect was specific for the particular species of foreign RBC injected in vivo. In vitro responses to TNP were also increased in spleen cultures prepared from animals injected 24 or 12 hr earlier with carrier RBC alone, directly implicating carrier-specific T cells in this process. Similar enhancements of PFC formation occurred in cultures prepared from mice which had been injected with sRBC 24 and 48 hr earlier, but which were exposed to lethal irradiation at 1 hr after injection of antigen, if their spleens were shielded extracorporeally during irradiation. This finding indicated that in vivo recruitment of antigen-reactive extrasplenic X-ray-sensitive cells from the circulating lymphocyte pool by the spleen could not account for the observed enhancement.Proliferation in the spleen of antigen-reactive T cells, commencing 12–20 hr after the administration of antigen, was demonstrated by the tritiated thymidine pulse technique. An 8-hr hot-pulse given to spleen cell cultures from normal animals at 20 hr after in vitro challenge with antigen did not affect the rate of generation of IgM-producing cells; however, administration of a similar pulse to cultures which were initiated at 12 or at 20 hr after the in vivo injection of sRBC eliminated the enhanced generation of PFC and delayed the in vitro response to sRBC by 24 hr.Spleen cell cultures were prepared from mice which had been injected in vivo with sRBC at 12, 20, and 70 hr earlier, and 8- to 10-hr hot pulses were given immediately after initiation of the cultures. The cultures were then challenged with sRBC-TNP; antibody responses to TNP were greatly reduced in hot-pulsed cultures prepared from mice injected in vivo with carrier RBC at 12 or 20 hr prior to initiation of the cultures. In contrast, antibody responses to TNP observed in hot-pulsed cultures prepared from mice which had been injected with carrier RBC at 70 hr prior to initiation of the cultures were generally similar to those of nonpulsed 70 hr control cultures. This result suggests that the onset of T helper cell proliferation begins within 12–20 hr after injection of antigen, but subsides in vivo within 70 hr. By that time, the antigen-reactive T cells have already differentiated to perform their helper function.In spite of the triggering of T-cell proliferation during the first 24 hr after injection of antigen, spleen cell cultures prepared from mice which had been injected 24 hr earlier in vivo with 2 × 10⁸ sRBC produced only minimal numbers of anti-sRBC PFC if no antigen was added to the cultures. The presence of unprocessed antigen thus appears to be a requirement for B-cell proliferation in vitro, even after T-cell division has been triggered. This finding is consistent with earlier suggestions that the function of “helper” T cells may not be limited to passive transport of antigenic determinants to B cells. Evidence is also presented to support the contention that the antigen-reactive T cell involved in this process may have to undergo cell division in order to develop “helper” capacity.     

Effects of deoxycoformycin in mice. I. Suppression and enhancement of in vivo antibody responses to thymus-dependent and -independent antigens

The effect of 2'-deoxycoformycin (DCF) on the PFC responses of AKR mice to SE, TNP-Ficoll, and TNP-B. abortus was examined. Subcutaneous injection of DCF 4 days before antigen caused suppression of all three responses by 70 to 78%. In contrast, injection of DCF 1 day after antigen caused enhancement of both the anti-SE and the anti-TNP-Ficoll responses. Although a single high dose of cortisone acetate injected 4 days before antigen caused a similar suppression, the effect of DCF was not mediated via a steroid release, inasmuch as DCF also suppressed the immune response in adrenalectomized mice. The response of BALB/c mice to TNP-Ficoll was also inhibited by DCF pretreatment and enhanced by injection of DCF after antigen. In contrast, in athymic mice DCF caused suppression of the anti-TNP-Ficoll PFC response, whether injected before or after antigen. These results are interpreted as suggesting that DCF causes suppression primarily via an effect on B cells. The enhancement seen in normal but not in athymic mice may possibly be ascribed to an effect on suppressor T cells. Apparently the enhancement of both TD and TI responses caused by DCF injected 1 day after antigen in normal mice is the net result of these two opposing effects. The results imply that helper T cells are resistant to DCF.     

The number of immunologically activated cells after repeated immunization (A mathematical model)

Using a mathematical model, the effect of the dose of antigen and of the rate of its elimination on the number of immunologically activated cells, derived from a single immunocompetent cell, that are prepared for the change into antibody-producing cells under the condition that further antigenic stimulus takes place, was studied. The following results were obtained under certain assumptions that are explained and discussed in our present work: (1) The shape of the dependence of the number of immunologically activated cells afterk-fold immunization on the immunizing dose and the rate of elimination of antigen was established. (2) In studies on the influence of the magnitude of a single antigen dose on the readiness for the secondary reaction (expressed as the number of immunologically activated cells present at the time of injection of the secondary antigen dose), we found that with increasing antigen dose the number of immunologically activated cells increases until it reaches its peak at the optimum antigen dose; then a decrease starts to occur. The range of doses of antigen causing approximately similar (and high) readiness for the secondary response is broader with antigens that are eliminated faster from the organism. (3) A method for the estimation of the optimum dose of antigen and of the number of persisting immunologically activated cells after this antigen dose is presented. This method can be used provided certain knowledge concerning the particular experimental system is available.     

Transfer of agammaglobulinemia in the chicken. I. Generation of suppressor activity by injection of bursa cells

Spleen cells from adult agammaglobulinemic (bursectomized) chickens taken 1 to 3 weeks after an injection of histocompatible bursa cells can inhibit the adoptive antibody response to B. abortus of normal spleen or bursa cells in irradiated recipients. Spleen cells from Aγ chickens not injected with bursa cells generally do not. Moreover, bursectomized chickens which have been reconstituted with spleen cells within the first week after hatching do not respond with suppressor cell formation upon bursa cell injection. This apparent “autoimmunization” with bursa cells induces suppressor T cells which are only minimally sensitive to treatment with mitomycin C or to 5000 R γ irradiation. The suppressor activity is neither induced nor potentiated by concanavalin A in vivo. It is much stronger in spleen than in thymus cells and appears to be macrophage independent and to require intact cells. The cell component which stimulates the suppressor activity is more pronounced on bursa than on spleen cells, and is at most present to a very limited extent on bone marrow, thymus, or peritoneal exudate cells. It is better represented in comparable cell numbers of Day 17 than of Day 14 embryonic bursa. The inducing cell component is present in the membrane fraction of disrupted bursa cells. Immunization with bursa cells from B locus histoincompatible chickens leads to suppressor activity against histocompatible bursa cells. Although the removal of Ig-bearing cells from bursa greatly diminishes its immunizing capacity, injection of serum IgM and IgG does not induce suppressor cells. It is suggested that tolerance to a B-cell antigen is lacking in adult Aγ chickens, resulting in an autoimmune response upon exposure to B cells. The B-cell antigen may be a cell surface-specific form of Ig, a complex of Ig and a membrane component, or a differentiation antigen which appears simultaneously with Ig during ontogeny.     

Influence of antigen dose on antibody production of intact and splenectomised Xenopus laevis.

Antigen persistence and serum antibody production in intact Xenopus were monitored using human gamma globulin (HGG), in adjuvant, in various immunisation schedules. Retention of HGG in spleen and serum was directly related to the quantity injected. However, antibody responses to a dose range between 1 mu-g-6 mg antigen were similar in intensity. These were detected in the serum two weeks after injection and at this stage were exclusively mercapto-ethanol (ME) sensitive; ME-resistant antibodies had appeared by four weeks. No antibodies were detected below a dose of 100 ng HGG. The effect of splenectomy on antibody levels was tested using HGG/adjuvant or sheep erythrocytes (SRBC) in saline. Splenectomised toads showed impairment of antibody responses only to threshold doses of HGG (100 ng) but to a wider range of SRBC doses.     

Anti-tumor activity of class II MHC antigen-restricted cloned autoreactive T cells. II. Novel immunotherapy of B16 melanomas by local and systemic adoptive transfer

Lyt-1+, L3T4a+ autoreactive cloned T cells, producing lymphotoxin (LT) and interferon-gamma (IFN-gamma) in response to self-class II major histocompatibility complex antigen in vitro were examined for their anti-tumor effect in vivo against B16 melanomas. Without the aid of exogenous interleukin 2, the autoreactive T cells, when injected immediately and at an equal cell number into the site of s.c. inoculated B16 melanoma cells inhibited tumor growth in sublethally irradiated and nonirradiated syngeneic mice. The autoreactive T cells also induced regression of tumors established 3 days earlier. Normal spleen cells or class II-restricted cloned T cells specific for chicken gamma-globulin (CGG) had no inhibitory effect on tumor growth. A single injection of autoreactive T cells delayed tumor growth and prolonged the survival of mice that had received a lethal dose of B16 melanoma cells. The autoreactive T cells caused extensive necrosis at the injection site. A treatment regime consisting of two successive injections of anti-I-Ab monoclonal antibody 3JP prevented the inhibition of tumor growth, supporting the hypothesis that the autoreactive T cells inhibited the growth of melanomas by releasing LT and IFN-gamma upon recognition of I-A antigen-bearing cells at the injection site. The CGG-specific control T cells did not cause necrosis and survived within the nests of uninhibited tumor cells. Autoreactive T cells administered i.v. immediately after i.v. injection of B16 melanoma cells markedly reduced pulmonary metastases, whereas CGG-specific T cells did not. These results indicate that autoreactive T cells can function in vivo as inhibitors of tumor growth.     

Regulatory mechanism of simian virus 40 gene expression in permissive and in nonpermissive cells.

Primary or continuous lines of mouse cells (3T3) are nonpermissive for simian virus 40 (SV40). Abortively infected cells synthesize tumor antigen (T antigen but not viral DNA and virus capsid protein (V antigen). V antigen, however, was obtained when SV40 DNA was injected into 3T3 cells. This late gene expression also appears to be correlated with the quantity of injected DNA molecules per 3T3 cell. T antigen formation can be detected after microinjection of only 1 to 2 DNA molecules, but the intensity of intranuclear T antigen fluorescence is significantly brighter with injection of higher concentrations of viral DNA. In permissive cells (TC7), early and late SV40 gene expression is directly related to the number of injected molecules. Microinjection of 1DNA molecule induced T and V antigen formation with the same efficiency as microinjection of 2,000 to 4,000 molecules. The question of weather late SV40 gene expression is directly related to the quantity of an early virus-specific product was approached by microinjection of early SV40 complementary RNA together with small amounts of viral DNA. V antigen was obtained in a high proportion of recipient 3T3 cells at conditions where microinjection of viral DNA alone induced T but not V antigen synthesis.     

Mathematical model of clonal selection and antibody production. II

Several modifications are proposed to a recent mathematical model (Bell, 1970) of the clonal selection and antibody production which take place when an adult animal is injected with an antigen. In the original model, antigen molecules were assumed univalent, i.e. to have only one combining site per molecule, and the first modification is an allowance for multivalent antigens by permitting an antigen molecule to interact with only one cell at a time. It is found that, for antigens with few (? 10) sites per molecule this modification is not important while for many sites per molecule, the modification will reduce the response as compared to that from the same number of independent antigenic sites. In section 3, it is seen that by restricting the number of cells which can arise in an immune response, much more realistic responses to high antigen doses are obtained. Moreover, the response is made more predictable by assuming that both target and proliferating cells are stimulated by antigen when a fraction of their receptors, between f_min and f_max, is bound to antigen. The parameter f_min is shown to determine the extent to which a molecule which can be recognized by antibodies will also serve as an immunogen giving rise to cellular proliferation and antibody production. In section 4, it is found that if more plasma cells than memory cells result from antigen stimulation, then weak stimulation will lead to a depletion of target plus memory cells and to at least partial immunological paralysis. Optimum antigen doses and times for the induction of such paralysis are examined. In section 5, precipitation of antigen-antibody mixtures is considered and it is shown that the number of doubly bound antibody molecules per antigen site determines whether precipitation will occur. This number is easily computed for heterogeneous bivalent antibodies.     

Immunoregulation by antigen/antibody complexes. I. Specific immunosuppression induced in vivo with immune complexes formed in antibody excess

Specific immune complexes, prepared at different ratios of antibody to antigen, were examined for their effects on the antibody response of BALB/c mice to the cell wall polysaccharide antigen (PnC) extracted from Streptococcus pneumonia R36a. Mice immunized with complexes formed in antigen excess developed a PnC-specific antibody response that was equivalent to that in mice injected with free antigen. On the other hand, mice injected with complexes formed in antibody excess developed very little PnC-specific antibody. Furthermore, administration of immune complexes (formed in antibody excess) resulted in suppression of the response to an immunogenic dose of PnC given concurrently or 1 day after injection of immune complexes but not when the antigen was given 1 day before injection of the immune complexes. Injections of free antibody (TEPC-15) also resulted in suppression of the response to antigenic challenge; however, suppression was greatest when the antibody was injected concurrently with the antigen, suggesting that the suppression was mediated through the formation of immune complexes in vivo. The suppression appears to be specific for the antigen (PnC), since in mice injected with TEPC-15/PnC complexes (formed in antibody excess) and challenged with PnC coupled to sheep RBC, only the response to PnC was suppressed.     

Biochemical and morphological modifications in rabbit Achilles tendon during maturation and ageing.

1. The plasma clearance of intravenously injected 125I-labelled mitochondrial malate dehydrogenase (half-life 7 min) was not influenced by previous injection of suramin and/or leupeptin (inhibitors of intralysosomal proteolysis). 2. Pretreatment with both inhibitors considerably delayed degradation of endocytosed enzyme in liver, spleen, bone marrow and kidneys. 3. The tissue distribution of radioactivity was determined at 30 min after injection, when only 3% of the dose was left in plasma. All injected radioactivity was still present in the carcass. The major part of the injected dose was found in liver (49%), spleen (5%), kidneys (13%) and bone, including marrow (11%). 4. Liver cells were isolated 15 min after injection of labelled enzyme. We found that Kupffer cells and parenchymal cells had endocytosed the enzyme at rates corresponding to 9530 and 156 ml of plasma/day per g of cell protein respectively. Endothelial cells do not significantly contribute to uptake of the enzyme. 5. Uptake by Kupffer cells was saturable, whereas uptake by parenchymal cells was not. This suggests that these cell types endocytose the enzyme via different receptors. 6. Previous injection of carbon particles greatly decreased uptake of the enzyme by liver, spleen and bone marrow.     

Degradation of Streptococcal Cell Wall Antigens In Vivo

Specific chemical modification of group A polysaccharide antigen to the A-variant structure was demonstrated in the lymphoid organs of mice by autoradiography by use of radioantibodies specific for these structures. Both antigenic moieties persisted and were still discerned 10 weeks after injection of the group A cell wall. In rabbit skin, the group A specificity was altered after a prolonged period. Unlike the situation for the mouse, polysaccharide A was not converted to A-variant structure, but another specificity common to both polysaccharides persisted at the site of injection. Mucopeptide, separated from the polysaccharide of group A cell walls, was eliminated from the site of injection in rabbit skin between 4 and 8 hr after injection. Group D streptococcal cell walls were also rapidly eliminated from tissue, and were no longer detectable 8 hr after injection into rabbit skin or 24 hr after injection into mice. The rapid degradation of these structures was correlated with their susceptibility to lysozyme in vitro and was in contrast to the prolonged persistence of group A cell walls, which were completely resistant to egg white lysozyme. This persistence in tissue correlated with the capacity of group A cell wall fragments to induce a chronic inflammatory process, whereas the isolated mucopeptide or group D cell walls produced only an acute necrotoxic reaction.     

Prevention by a platelet-derived factor (platelet factor 4) of induction of low dose tolerance to pneumococcal polysaccharides

It was previously shown that human or mouse serum, and platelet factor 4 (PF4) prepared from human platelet releasate, counteracts nonspecific immunosuppression induced in mice by injection of concanavalin A or syngeneic gamma-irradiated lymphoma cells. The present studies show that PF4 prepared from normal mouse or human serum by absorption to heparin-agarose and elution between 0.5 and 1.5 M NaCl is also active in this respect. The ability of PF4 to counteract antigen-specific suppression of the antibody response to pneumococcal polysaccharide (pps) was now studied. PF4 derived from human or mouse serum as well as recombinant PF4 interferes with induction of antigen-specific low dose tolerance when they are injected at the same time as a low dose (0.2 microgram) of type 14 pps 3 days before an optimal immunizing dose (25 micrograms). Furthermore, injection of platelet releasate at the time of an optimal primary immunizing dose of pps type 14 enhances the secondary response to killed bacteria injected 2 weeks later, but not the primary response itself. Both effects are interpreted as due to interference with antigen-specific suppressor cell induction during primary immunization. Injection of PF4 is much less effective in reversing low dose tolerance to an optimal immunizing dose (0.1 microgram) of type 3 pps induced by injection of 0.005 microgram of this antigen. Differences in the mechanism of tolerance induction for the two pps types that might be responsible for this are discussed.     

Galectin-9 and IL-21 Mediate Cross-regulation between Th17 and Treg Cells during Acute Hepatitis C

Loss of CD4 T cell help correlates with virus persistence during acute hepatitis C virus (HCV) infection, but the underlying mechanism(s) remain unknown. We developed a combined proliferation/intracellular cytokine staining assay to monitor expansion of HCV-specific CD4 T cells and helper cytokines expression patterns during acute infections with different outcomes. We demonstrate that acute resolving HCV is characterized by strong Th1/Th17 responses with specific expansion of IL-21-producing CD4 T cells and increased IL-21 levels in plasma. In contrast, viral persistence was associated with lower frequencies of IL-21-producing CD4 T cells, reduced proliferation and increased expression of the inhibitory receptors T cell immunoglobulin and mucin-domain-containing-molecule-3 (Tim-3), programmed death 1 (PD-1) and cytotoxic T-lymphocyte antigen 4 (CTLA-4) on HCV-specific CD8 T cells. Progression to persistent infection was accompanied by increased plasma levels of the Tim-3 ligand Galectin-9 (Gal-9) and expansion of Gal-9 expressing regulatory T cells (Tregs). In vitro supplementation of Tim-3^high HCV-specific CD8 T cells with IL-21 enhanced their proliferation and prevented Gal-9 induced apoptosis. siRNA-mediated knockdown of Gal-9 in Treg cells rescued IL-21 production by HCV-specific CD4 T cells. We propose that failure of CD4 T cell help during acute HCV is partially due to an imbalance between Th17 and Treg cells whereby exhaustion of both CD4 and CD8 T cells through the Tim-3/Gal-9 pathway may be limited by IL-21 producing Th17 cells or enhanced by Gal-9 producing Tregs.     

Desensitization of delayed-type hypersensitivity by antigen and specific antibody.

The role of antibody in the desensitization of delayed-type hypersnsitivity (DTH) to dinitrophenylated bovine gammaglobulin (DNP-BGG) was studied in rats. Rats sensitized by a subcutaneous injection of DNP₃₂-BGG in Freund's complete adjuvant (FCA) were desensitized 14 days later with various doses of DNP₃₂-BGG injected intravenously. It was found that only certain doses (100–500 μg) of DNP-BGG effectively desensitized, antigen doses outside this optimum range being ineffective in suppressing DTH. In adoptive cell transfer experiments, it was shown that sensitized peritoneal cells incubated with optimum doses of the antigen in the presence of specific antiserum in vitro failed to transfer the delayed response to normal recipients, whereas the treatment of the sensitized cells with the antigen or with the antiserum separately did not impair the ability of these cells to transfer DTH. The effect of desensitization is specific and is not permanent. The DTH reappears 3–4 wk after desensitizing injection.     

Effect of bromocriptine on lipid plasma levels in rats

Results show that bromocriptine induced marked alterations in plasma levels of cholesterol and lipids in response to acute and chronic administrations in rats. Two hours after an I.P. dose of 10 mg/kg, bromocriptine mesylate caused significant reductions in plasma levels of total high density lipoprotein (HDL) and high density lipoprotein cholesterol (HDL cholesterol). At a dose of 20 mg/kg, bromocriptine mesylate induced significant elevations in plasma levels of total cholesterol, total HDL, HDL cholesterol, total low density lipoproteins (LDL), and low density lipoprotein cholesterol (LDL cholesterol). Injected at a dose of 4 or 10 mg/kg daily for 14 consecutive days, bromocriptine mesylate caused significant increases in plasma levels of total cholesterol, LDL cholesterol and total LDL whereas the levels of HDL cholesterol, total HDL triglycerides (TG) were reduced. At a dose of 20 mg/kg all parameters were significantly increased. Marked hyperglycaemia was noticed in response to doses of 10, 15 and 20 mg/kg injected daily for 14 consecutive days or 2 hrs after a single administration of 15 mg/kg. Plasma insulin activity was reduced 2 hours after injection of bromocriptine at a dose of 15 mg/kg Likewise, a significant reduction in plasma insulin activity was observed in response to daily I.P. injections of bromocriptine at a dose of 15 mg/kg. Hyperglycaemic and hypoinsulinaemic effects of bromocriptine (acute and chronic) were markedly decreased when sulpiride, a dopaminergic D2 antagonist, was injected at an I.P. dose of 10 mg/kg before bromocriptine. Plasma ACTH activity was significantly increased in response to bromocriptine (15 mg/kg I.P.) in acute and chronic experiments. This effect was markedly diminished when sulpiride was injected prior to bromocriptine. In conclusion, bromocriptine induced marked elevations in plasma levels of total cholesterol and lipids which are likely to be related to hyperglycaemic and hypoinsulinaemic effects.     

Cyclic kinetics and mathematical expression of the primary immune response to soluble antigen

The kinetics and the distribution of antigen and antibody were shown to be similar in four species of experimental animals and in two species of wild rodents immunized with the protein-polysaccharide capsular plague antigen. Serologically active antigen and antibody were detected in homologous conjugating serological tests. Soluble antigen persists at the injection site for as long as a week and adsorbed antigen for two weeks or more. Antigen persists in the blood of animals for 2–4 days. In regional popliteal lymph nodes, antigen was detected for the first days, followed by antibody in both lymph node and blood. Plasma cell response was more intensive in animals inoculated with adsorbed antigen. The gradual decrease of antigen at the injection site shows superimposed up-and-down changes, mostly parallel with the antibody in the popliteal lymph node and blood, as well as with plasma cell response in the regional lymph node. Serological cycles were related to the resistance of immunized white mice to plague infection. Cyclic kinetics of specific polysaccharide in the faeces of dysentery patients was found.     

Effect of thymus cell injections on germinal center formation in lymphoid tissues of nude (thymusless) mice

Nude mice, partially backcrossed to Balb/c or DBA/2, were injected iv with 5 × 10⁷ thymus cells from the respective inbred strain. The response of these mice to immunization with Brucella abortus antigen was studied, with respect to both antibody production and the formation of germinal centers in their lymphoid tissues. The results were compared to those obtained with nude mice to which no thymus cells were given, as well as to Balb/c, DBA/2, or +/? litter mate controls.Nude mice formed less 19S as well as 7S antibody than did litter mate controls and completely lacked germinal centers in lymph nodes and gut-associated lymphoid tissue. Those nude mice which had been injected with thymus cells made a much better secondary response, both for 19S and for 7S antibody, and had active germinal centers in their lymph nodes as early as 3 wk after thymus cell injection. Intestinal lymphoid tissue in nude mice showed only slight reconstitution of germinal center activity several months after thymus cell injection and none at earlier times. Irradiated (3000 R) thymus cells appeared as effective as normal cells in facilitating germinal center appearance and 7S antibody production in the nude mice.     

Mechanisms of increased immunogenicity for DNA-based vaccines adsorbed onto cationic microparticles

Investigation into the mechanism of action of vaccine adjuvants provides opportunities to define basic immune principles underlying the induction of strong immune responses and insights useful for the rational development of subunit vaccines. A novel HIV vaccine composed of plasmid DNA-encoding p55 gag formulated with poly-lactide-co-glycolide microparticles (PLG) and cetyl trimethyl ammonium bromide (CTAB) elicits both serum antibody titers and cytotoxic lymphocyte activity in mice at doses two orders of magnitude lower than those required for comparable response to plasmid DNA in saline. Using this model, we demonstrated the increase in potency requires the DNA to be complexed to the PLG-CTAB microparticles. Furthermore, the PLG-CTAB-DNA formulation increased the persistence of DNA at the injection site, recruited mononuclear phagocytes to the site of injection, and activated a population of antigen presenting cells. Intramuscular immunization with the PLG-CTAB-DNA complex induced antigen expression at both the injection site and the draining lymph node. These findings demonstrate that the PLG-CTAB-DNA formulation exhibits multiple mechanisms of immunopotentiation.