Macrophage requirements of CR- and CR+ B lymphocytes for antibody production in vitro.

A Sephadex G-10 column coated with antigen-antibody complexes and complement retains complement receptor-bearing (CR+) mouse spleen cells. The effluent is rich in thymus-derived cells (T cells), and contains bone marrow-derived cells (B cells) which carry surface immunoglobulin (Ig), Ir-associated antigen (Ia), and Fc receptors, but no complement receptors (CR-). Although both unfractionated and CR- B cell populations are capable of producing antibody to red cell antigens, they differ in their requirements for the initiation of the response. Unfractionated B cells cooperate with primed as well as unprimed helper T cells; macrophages are required for this cooperation but can be replaced by 2-mercaptoethanol. CR- B cells cooperate with primed but not with unprimed T cells provided macrophages are added to cultures. After addition of culture supernatant from BCG-activated macrophages CR- B cells cooperate with both unprimed and primed T helper cells.     

Immune response to a syngeneic mammary adenocarcinoma. III. Development of memory and suppressor functions modulating cellular cytotoxicity.

Measurement of the development of cytolytic activity by mammary tumor primed or unprimed syngeneic spleen cells on in vitro monolayers of the 13762 rat mammary tumor operationally defined several subpopulations of lymphoid cells involved in the cytotoxic response. In vitro sensitization of cells from Fischer 344 animals injected 2 to 10 days earlier with 2 x 10(7) viable tumor cells always resulted in a higher and earlier lytic response than cells from non-inoculated animals. Adoptive transfer of the same in vivo primed cells for 5 days in irradiated syngeneic hosts removed any cytotoxic cells originally present but subsequent in vitro sensitization still resulted in a higher and earlier cytolytic response. We defined such cells as "memory" cells for cytotoxicity. Memory cells were radiosensitive and specific for the immunizing target cell. In contrast to cells from animals inoculated for 3 to 10 days, cells obtained 11 and 12 days after immunization had a lower response than unprimed cells on vitro sensitization. The anamnestic response could be restored either by culturing 12-day primed cells in vitro for 2 days without antigen or by adoptive transfer for 5 days into irradiated syngeneic rats. This suggests that another population of cells is present in spleen and suppresses the conversion of memory to cytotoxic cells. A more direct measurement of suppressor cell function was obtained by coincubating tumor-primed and unprimed cells on monolayers during in vitro sensitization. Cells from animals bearing tumors for 5 to 10 days always caused an increase in the response of the mixed lymphocyte groups, whereas 11- to 13-day tumor primed cells always caused a marked decrease in the cytolytic response. These results suggest the following interpretation of the kinetics of cell-mediated cytotoxicity to syngeneic tumor inoculation. Cytotoxic cells appear about 6 days after immunization, reach peak levels 2 days later, and then decrease rapidly. Memory cells are generated at a faster rate, reach peak levels before maximum cytolytic activity, but are then functionally inhibited from converting into differentiated cytotoxic cells by a new population of suppressor cells which reach peak activity about 12 days after immunization.     

Regulation of the secondary in vitro antibody response by endogenous natural killer cells: kinetics, isotype preference, and non-identity with T suppressor cells

Our previous studies had demonstrated that depletion of endogenous natural killer (NK) cells resulted in an augmented primary antibody response in vivo and in vitro. We have now examined the effect of NK cell depletion on the in vitro secondary response to antigen. Treatment of primed murine spleen cells with anti-NK-1.1 allo-antibody and complement before culture resulted in a significant increase in the magnitude of the antigen-specific plaque-forming cell (PFC) response. This treatment did not affect the proportions of Lyt-2+, L3T4+, or sIg+ cells in the population, however, indicating that the augmentation in PFC was not due to changes in the ratio of T to B cells. Removal of endogenous NK cells had a greater effect on the IgG (indirect) PFC response (100 to 200% increase) than on the IgM (direct) PFC response (25 to 50% increase). In contrast, removal of Lyt-2+ cells before culture affected the IgM and IgG responses similarly. Moreover, the kinetics of augmentation differed between cultures depleted of Lyt-2+ cells and those depleted of NK-1.1+ cells. NK cells appeared to act earlier in the response than did T suppressor cells. The NK-1.1+ cells involved in antibody regulation were not involved in the generation of the in vitro derived T suppressor cells. The conclusion that the regulation of the antibody response by NK-1.1+ cells is distinct from that involving T suppressor cells was confirmed in experiments in which removal of both regulatory cell populations resulted in an increase in PFC that was greater than in cultures depleted of either NK or T suppressor cells.     

Clonal expansion of IgM B memory cells in vitro.

Clonal development of Srbc-primed IgM B cell precursors has been studied in vitro. Cells were cultured in the presence of LPS and Srbc, as well as additional T cells derived from three sources: specific Srbc-activated T cells, allogeneic spleen cells and normal thymus cells. Clones developing in the presence of Srbc-activated T cells reached larger sixes than did those developing in the presence of allogeneic cells, thymus cells, or only those primed T cells indigenous in the primed spleen population. However, in all these experiments, precursors primed as described attained considerably larger clone sixes than did normal unprimed precursors. Two conclusions can be made: (1) primed precursors have a greater capacity to generate progeny pfc in response to LPS + Srbc than do normal precursors and (2) specifically activated T cells appear to play a role in elevating pfc production which occurs in response to LPS and Srbc.     

Mechanism of allosuppression: evidence for direct suppression of responding B cells.

The mechanism of allosuppression has been investigated. As previously described, negative allogeneic effects result when T cells recognize MHC-encoded alloantigens on responding lymphocytes, preventing the generation of a secondary anti-PFC response in vitro. Several experiments suggested that this suppression was not due to the generation of cytotoxic effectors. First, effective suppression occurred only when T cells, either unprimed or alloantigen activated, were added during the first 24 hr of the responding culture. Even previously generated cytotoxic effectors were relatively ineffective when added late in the response. Furthermore, no detectable cytotoxic effectors were found in suppressed cultures. The major target of suppression was the responding B cell. Only B cells carrying alloantigens (thus recognized by the T cells) were suppressed; bystander B cells were little affected. Thus allosuppression appears to involve the recognition by T cells of alloantigens on responding B cells and direct suppression of some early event in the development of these B cells into PFC. The responses of primed B cells were found to be preferentially sensitive to the suppressive effects of allo- T cells, whereas the response of unprimed B cells was influenced preferentially by the helper effects of alloantigen-activated T cells. It is possible that the state of differentiation of the B cell may determine the outcome of the interaction with regulatory T cells.     

Induction of antigen-specific antibody responses in primed and unprimed B cells. Functional heterogeneity among Th1 and Th2 T cell clones

CD4+ T cells have been recently divided into two subsets. The functions of these subsets are thought to be distinct: one subset (Th1) is responsible for delayed type hypersensitivity responses and another (Th2) is primarily responsible for induction of antibody synthesis. To more precisely define the roles of both subsets in humoral immune responses, we examined the ability of a panel of nominal antigen specific Th1 and Th2 clones to induce anti-TNP specific antibody synthesis in TNP-primed or unprimed B cells. Four of nine Th1 clones induced little or no antibody synthesis with TNP-primed B cells. However, five other Th1 clones were very effective at inducing IgG anti-TNP plaque-forming cell (PFC) responses in primed B cells. One of these Th1 clones was analysed in detail and found to also provide helper function for unprimed B cells. Cognate B-T cell interaction was required for induction of both primary and secondary responses with this clone, indicating that a Th1 clone could function as a "classical" Th cell. The seven IL-4 producing Th2 clones examined were also heterogeneous in their ability to induce antibody secretion by TNP-primed B cells. Although four of the Th2 clones induced IgG and IgM anti-TNP PFC responses, two Th2 clones induced only IgM and no IgG antibody, and another clone failed to induce any anti-TNP PFC. All Th2 clones failed to induce any anti-TNP PFC. All Th2 clones produced high levels of IL-4, but "helper" Th2 clones produced significantly greater amounts of IL-5 than "non-helper" Th2 clones. These studies indicate that some IL-2- and some IL-4-producing T cell clones can induce TNP-specific antibody in cell clones can induce TNP-specific antibody in primed and unprimed B cells, and that Th1 and Th2 clones are heterogeneous in their ability to induce Ig synthesis. Therefore, although T cell clones can be classified as Th1 or Th2 types according to patterns of IL-2, IFN-gamma, or IL-4 synthesis, the functional capacity to induce antibody synthesis cannot be predicted solely by their ability to secrete these lymphokines.     

Dissociation between proliferation and antibody formation by old mouse spleen cells in response to LPS stimulation.

Both lipopolysaccharide (LPS)-induced proliferation and antibody formation by C57B1/6 spleen cells from old mice were studied by measuring thymidine incorporation and plaque-forming cells (PFCs) to the 2,4-dinitrophenyl group (DNP). There was no significant difference in the proliferative response of spleen cells from young or old mice. Anti-DNP antibody formation by spleen cells from the old mice was greatly reduced. The reduced PFC response could not explained by a shift in kinetics of the responding cells. A similar dissociation could be obtained with LPS-stimulated spleen cells from young mice by using an anti-μ serum or a low concentration of hydroxyurea in the culture medium.     

Regulation of the anti-alpha (1,3) dextran response: two populations of dextran-reactive B cells that differ in their T cell requirements for induction to antibody synthesis

The in vitro antibody response to dextran B1355S, a thymus-independent Type 2 antigen, requires T cell-derived lymphokines but is not thought to require an activation signal from an antigen-specific T helper cell. The present study demonstrates that there are two dextran-reactive B cell populations in BALB/c mice with respect to the T cell requirements for the generation of antibody-forming cells. One population found among dextran-reactive spleen B cells from 12- to 14-mo-old BALB/c mice generated anti-dextran PFC in the presence of B cell growth factor (BCGF II) and IL 2 or the combination of BCGF II, IL 2, and IFN-gamma. A second population of dextran-reactive B cells found in spleen and Peyer's patches of 2-mo-old unprimed mice did not respond to these same lymphokines, but did generate anti-dextran plaque-forming cells in the presence of Thy-1.2+, L3T4+ T cells from Peyer's patches. However, splenic B cells obtained from 2-mo-old mice that had been primed with dextran 2 to 3 days after birth were shown to be responsive to the same lymphokines as dextran-reactive B cells from 12- to 14-mo-old mice. These results suggest that previous priming with dextran B1355S induces a dextran-specific B cell population that can be activated to antibody-forming cells in the presence of antigen and T cell-derived lymphokines, whereas a second, unprimed population requires an additional activation signal from L3T4+ T cells.     

Cell cycle analysis of lymphocyte activation in normal and autoimmune strains of mice

The spontaneous spleen cell proliferation and the proliferation induced by in vivo or in vitro stimulation with such polyclonal B cell activators (PBA) as LPS, poly rI.rC, and anti-mu were studied in normal and autoimmune mice. The various murine models of autoimmunity differ in the level of naturally occurring splenic cellular hyperactivity as well as in the ability of their spleen cells to be further stimulated in vitro by polyclonal stimulators. Both the NZB strain and the MRL/Ipr strain had markedly increased numbers and percentages of spontaneously proliferating spleen cells, whereas the BXSB strain did not. Nonautoimmune strains were found to have very small numbers of activated cells in the spleen. However, such normal strains could be induced in vivo to mimic the natural splenic hyperactivity observed in older NZB and MRL/Ipr autoimmune strains by the injection of polyclonal B lymphocyte stimulators. In contrast, old hyperactive NZB mice were not further induced to undergo proliferation by in vivo administration of such stimulators. Density-separated, T depleted, spleen cells of normal and autoimmune mice were stimulated in vitro with PBA in 48-hr cultures. Cells from old MRL/Ipr and NZB mice were abnormal in both the anti-mu response and the LPS response; BXSB mice had normal anti-mu responses. These studies suggest that there is no prerequisite for spontaneous splenic hyperactivity in the development of autoimmunity. In addition, different PBA stimulate separate subsets of B cells that differ in their state of activation in the various autoimmune strains. Finally, different B cell subsets appear to be abnormal in different types of autoimmune mice.     

Biologic activity of antigen receptors artificially incorporated onto B lymphocytes

We describe a method for incorporating monoclonal antibody molecules onto viable murine lymphocytes and summarize the biologic activity of these artificial receptors on B cells. Mouse spleen cells incubated overnight with palmitate conjugates of a monoclonal anti-DNP IgA (protein 315) in the presence of deoxycholic acid incorporate about 50,000 antibody molecules per cell. When concentrations of deoxycholate and palmitoyl-protein 315 are carefully controlled, this labeling procedure does not affect the viability or the normal functions of the receptor-decorated cells. The incorporated antibody specifically binds DNP-antigens, although it appears to be unable to communicate directly with internal cellular components. Yet when these receptor-decorated, unprimed cells are challenged with any one of several DNP-antigens, up to 42,000 per 10(6) B cells differentiate into Ig-secreting cells. This response is about 23-fold greater than that induced in normal cell cultures and is of the same magnitude as that induced by the polyclonal B cell activator LPS. This, in addition to the observation that only about 3.6% of receptor-decorated B cells responding to DNP-conjugated polymerized flagellin (DNP-POL) produce hapten-specific antibody, demonstrates that these antigens cause polyclonal B cell differentiation. Normal spleen cells in the presence of DNP-POL and irradiated spleen cells bearing the artificial receptors do not exhibit the polyclonal antibody response. Also, the response of receptor-decorated B cell is blocked by high but nontoxic concentrations of the nonimmunogenic hapten DNP-lysine. These observations demonstrate that the polyclonal B cell response in this system requires the binding of antigen to artificial receptors on functionally viable cells. The polyclonal B cell response to a thymus-dependent antigen DNP-conjugated bovine gamma-globulin (DNP-BGG) requires the presence of the carrier-primed T cells. On the other hand, T cell depletion by anti-Thy-1.2 monoclonal antibody and complement causes only a slight reduction in the number of receptor-decorated B cells that respond to the relatively thymus-independent antigen DNP-POL. This type of phenomenon is also seen with natural antigen-specific B cells. Thus, polyclonal activation of receptor-decorated B cells exhibits the same gross helper cell requirements as antigenic activation of natural antigen-specific B cells. The results of this study are discussed in the context of the role of membrane-bound surface Ig in antigen-dependent B cell activation.(ABSTRACT TRUNCATED AT 400 WORDS)     

In vivo priming of helper T cells in the absence of B cell activation

This paper describes an adjuvant-free immunization regimen that results in the priming of T cells but not B cells. B10.A mice were primed s.c. with syngeneic spleen cells that had been pulsed with the peptide 81-104 derived from pigeon cytochrome c. The T cell response was measured by using a sensitive limiting dilution assay that measures lymphokine production. The precursor frequency of Ag-specific cells found in these mice was indistinguishable from the frequency found in mice primed in the footpads with 81-104 in CFA. A striking difference in antibody induction was found, however, when these two immunization regimens were compared. Mice primed with 81-104 in CFA developed significant serum antibody responses against the peptide, whereas mice primed with Ag-pulsed spleen cells produced no detectable anti-peptide antibodies. This lack of antibody did not result from detectable differences in the T cells that were primed: no differences were seen in IL-2 and IL-4 production or in the ability to provide help to B cells in vitro. In vitro stimulation with LPS suggested that the B cells were not primed by the Ag-pulsed spleen cells. The B cells were not tolerized, however, because boosting the mice with Ag in CFA resulted in the induction of an antibody response. The failure to induce an antibody response by priming with Ag-pulsed spleen cells was not caused by the site of immunization or the total amount of Ag used for priming. The critical variable may be the introduction of the Ag on the surface of an APC; in this form, B cell Ag recognition was apparently inefficient, whereas T cell Ag recognition was optimal.     

Polyclonal Antibody Production in Murine Spleen Cells Induced by Staphylococcus

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

Antigen-specific protection against graft-vs-host induced immune deficiency

A severe, antigen-nonspecific, and long-lasting immune-deficient state can be induced in healthy, adult immune-competent F1 hybrid mice by a single i.v. injection of parental T lymphocytes. The present report demonstrates that this graft-vs-host-induced immune deficiency (GVHID) can be prevented in an antigen-specific way by immunization of the F1 mice with allogeneic cells before induction of GVHID. Thus, spleen cells from (A X B)F1 mice primed with allogeneic cells from strain C and then injected with parental spleen cells from A did not generate cytotoxic T lymphocyte responses to trinitophenyl-modified self cells or to allogeneic cells from third party strains D or E. However, spleen cells from the same mice generated normal levels of cytotoxic T lymphocyte activity to allogeneic cells from C, the strain used for immunization. Furthermore, mice exposed to murine cytomegalovirus before induction of GVHID were resistant to a subsequent challenge with murine cytomegalovirus, whereas GVHID mice that received only the murine cytomegalovirus challenge all died. These findings are discussed with respect to the possibilities that primed and unprimed T helper cells may be differentially susceptible to the suppressive effects of GVH.     

Acylation of lysophosphatidylcholine plays a key role in the response of monocytes to lipopolysaccharide.

Mononuclear phagocytes play a pivotal role in the progression of septic shock by producing tumor necrosis factor-alpha (TNF-alpha) and other inflammatory mediators in response to lipopolysaccharide (LPS) from Gram-negative bacteria. Our previous studies have shown monocyte and macrophage activation correlate with changes in membrane phospholipid composition, mediated by acyltransferases. Interferon-gamma (IFN-gamma), which activates and primes these cells for enhanced inflammatory responses to LPS, was found to selectively activate lysophosphatidylcholine acyltransferase (LPCAT) (P < 0.05) but not lysophosphatidic acid acyltransferase (LPAAT) activity. When used to prime the human monocytic cell line MonoMac 6, the production of TNF-alpha and interleukin-6 (IL-6) was approximately five times greater in cells primed with IFN-gamma than unprimed cells. Two LPCAT inhibitors SK&F 98625 (diethyl 7-(3,4,5-triphenyl-2-oxo2,3-dihydro-imidazole-1-yl)heptane phosphonate) and YM 50201 (3-hydroxyethyl 5,3'-thiophenyl pyridine) strongly inhibited (up to 90%) TNF-alpha and IL-6 production in response to LPS in both unprimed MonoMac-6 cells and in cells primed with IFN-gamma. In similar experiments, these inhibitors also substantially decreased the response of both primed and unprimed peripheral blood mononuclear cells to LPS. Sequence-based amplification methods showed that SK&F 98625 inhibited TNF-alpha production by decreasing TNF-alpha mRNA levels in MonoMac-6 cells. Taken together, the data from these studies suggest that LPCAT is a key enzyme in both the pathways of activation (priming) and the inflammatory response to LPS in monocytes.     

Participation of IL-4 in the formation of IgD-binding factors by antigen-primed mouse spleen cells

BALB/c mouse spleen cells primed with either keyhole limpet hemocyanin or DNP-keyhole limpet hemocyanin formed not only IgG-binding factors (BF) and IgE-BF but also IgD-BF upon antigenic stimulation. Analysis of cellular mechanisms involved in the formation of Ig-BF by antigenic stimulation revealed that Ag-primed Th cells released lymphokines upon antigenic stimulation, and that the lymphokine(s) in turn stimulates unprimed T cells to form Ig-BF. Normal unprimed lymphocytes formed IgD-BF upon incubation with culture supernatants of Ag-stimulated spleen cells. The formation of IgD-BF induced by the culture supernatant was prevented by anti-IL-4 mAb (11B11). It was also found that 0.3 to 10 U/ml mouse rIL-4, but none of the rIL-1, IL-2, and IFN-gamma, induced normal T cells to form IgD-BF. Indeed, both IL-2 and IFN-gamma inhibited IL-4 to induce the formation of IgD-BF. In contrast, 10 to 50 U/ml of IFN-gamma induced the formation of IgE-BF, and 50 to 200 U/ml IFN-gamma induced the formation of IgG-BF. However, none of the other lymphokines tested, i.e., IL-1, IL-2, and IL-4, induced the formation of either IgE-BF or IgG-BF. The IgD-BF formed by antigenic stimulation of keyhole limpet hemocyanin-primed spleen cells and those formed by stimulation of normal lymphocytes with 1 to 2 U/ml IL-4 enhanced both IgM and IgG1 plaque-forming cell responses of SRBC-primed spleen cells to homologous Ag. In contrast, 1 to 2 U/ml of IL-4, which could induce the formation of IgD-BF, failed to affect the PFC responses. It appears that the formation of IgD-BF may be involved in the effects of IL-4 to enhance the antibody response.     

Priming of peripheral lymph node B cells with TNP-Ficoll: role of lymphokines in B cell differentiation.

We have previously shown that peripheral lymph node (PLN) B lymphocytes of adult DBA/2J mice failed to make an antibody response to type 2 antigen TNP-Ficoll, but exhibited a good antibody response to type 1 antigen TNP-Brucella abortus. In the present study we wanted to find out whether the unresponsiveness of PLN B cells to TNP-Ficoll is due to defects in the early activation and proliferation stage or in the final differentiation stage of B cells. Therefore, we have used a two-step protocol of in vivo immunization of mice with TNP-Ficoll and the subsequent in vitro challenge with TNP-Brucella abortus and studied the anti-TNP plaque-forming cell (PFC) responses. The results indicate a three- to sixfold increase of PFC responses in PLN cell cultures derived from TNP-Ficoll-primed animals compared to saline control mice. This increased antibody response was TNP-specific as 93% of the PFC's were inhibited by TNP-lysine. Limiting dilution experiments confirm that the increase in anti-TNP PFC response from the TNP-Ficoll-primed animals was indeed due to an increase in TNP-specific precursor B cells. Further, the addition of rIL-5 or rIL-6 induced anti-TNP PFC in the TNP-Ficoll-primed and in control PLN cell cultures in the presence of antigen. However, in primed PLN cells lymphokines alone were sufficient to restore anti-TNP PFC response. In conclusion, our results show that in PLN, the TNP-Ficoll can induce proliferation of hapten-specific B cells but not final differentiation. These primed PLN B cells mature into antibody-secreting cells upon stimulation with TNP-BA or lymphokines.     

Keyhole limpet hemocyanin-propagated Peyer's patch T cell clones that help IgA responses

Four T cell clones, isolated from Peyer's patches of keyhole limpet hemocyanin (KLH)-primed BALB/c mice, were selected on the basis of their ability to help IgA responses by TNP-KLH-primed BALB/c mouse B cells. Two were KLH-dependent both in terms of their own proliferative response and in terms of their help for that of B cells. The other two were autoreactive and helped B cells proliferate independently of the presence of Ag. Both primed and unprimed B cells proliferated to some extent when helped by the KLH-reactive clones in the presence of high concentrations of either KLH or TNP-KLH. Much higher proliferation was, however, induced when primed, but not unprimed, B cells were exposed to the T cells in the presence of low concentrations of TNP-KLH but not KLH, i.e., under conditions favoring direct, cognate interaction between the T and B cells. Only modest IgM, and no IgG or IgA plaque-forming cell (PFC) responses were generated by TNP-primed B cells upon interaction with either autoreactive T cells in the absence of Ag or KLH-reactive T cells in the presence of high concentrations of KLH. For high IgM responses as well as for the appearance of IgG and IgA PFC responses, TNP-KLH was required whatever the source of the T cell help. The isotype ratios depended on the TNP-KLH concentration; IgA responses were highest and IgM responses lowest at the lowest TNP-KLH concentrations suggesting that the precursors of the IgA PFC have higher average affinity for TNP than the precursors of IgM PFC. Overall, the results are compatible with the idea that the precursors of IgA and IgG PFC and many of the precursors of IgM PFC in the long term primed B cell populations used in these experiments require engagement of their Ag-receptors before they express sufficient class II Ag and/or receptors for "switch" and differentiation factors for cognate interaction with T cells leading to PFC responses.     

Relation between Enhanced Antibody Responses Elicited by Adjuvant Injection and Those Elicited by Secondary Antigenic Stimulation

An attempt was made to determine if there is any common mechanism in the enhanced antibody response caused either by injection of adjuvant, such as bacterial endotoxin (LPS) and complexed polynucleotides, or by secondary antigenic stimulation. LPS inoculated in mice 4 days before injection of sheep red blood cells (SRBC) and polyA:U invalidated the adjuvant effect of polyA:U injected together with SRBC, and the hemolysin plaque-forming cell (PFC) response of such mice was similar to that of the mice which received SRBC alone. When mice primed with SRBC 24 days in advance were injected with LPS and 4 days later re-stimulated with SRBC, their PFC response to the secondary stimulation was suppressed to less than one tenth of the normal secondary PFC response. The suppressive effect of LPS on the secondary antibody response was abolished if the serum collected from mice injected with LPS was given to the primed and LPS-injected mice at the time of the secondary antigenic stimulation. From these results we discussed the possibility that some common mediator might play a role in the enhanced antibody response elicited by either adjuvant injection or secondary injection of antigen.     

In vitro antibody response to influenza virus. I. T cell dependence of secondary response to hemagglutinin.

A good secondary IgG response to the hemagglutinin (HA) of influenza virus has been obtained in vitro in Marbrook-type cultures of influenza-primed mouse spleen cell suspensions stimulated with inactivated influenza virus. Anti-HA antibody was quantitated by a solid phase radioimmunoassay (RIA) by using purified HA as substrate. The T dependence of this secondary response was shown by depletion of T cells and reconstitution with a source of primed or unprimed T cells. The help given by T cells primed to the homologous virus was many times greater than that given by unprimed T cells, although the latter was significant. The system described will allow investigation of the specificity requirements of helper T cells engaged in the anti-HA response.