In vitro immune response of human peripheral lymphocytes. VII. Effect of anti-mu and anti-delta antibodies on B colony formation and detection of abnormal B cells in patients with juvenile rheumatoid arthritis

Effect of anti-mu and anti-delta antibodies on PHA- and protein A-induced B colony formation was studied. Anti-mu antibody at any concentrations tested did not show inhibitory or enhancing effect on colony formation. On the other hand, anti-delta antibody enhanced both PHA- and protein A-induced colony formation. Optimum concentration of anti-delta antibody for maximum enhancement was 0.1 microgram/ml. and F(ab')2 fragment of anti-delta antibody also showed comparable enhancing effect. Simultaneous addition of IgD with anti-delta antibody abrogated anti-delta-induced enhancement, and anti-delta antibody did not show any facilitation of colony formation in IgM+ IgD- cell population. In marked contrast with normal B cells, anti-mu antibody showed a remarkable enhancing effect on protein A-induced colony formation of B cells from JRA patients. F(ab')2 fragment of anti-mu antibody also showed comparable enhancing effect. Anti-mu antibody did not show any enhancement of colony formation of B cells from several other autoimmune diseases. The result indicated the presence of abnormal B cells in JRA patients.     

Lymphoma models for B cell activation and tolerance. VIII. Cross-desensitization by sIgM and sIgD and its effects on growth regulation by anti-isotype antibodies

ECH408-1 is a murine B cell lymphoma expressing idiotypically and allotypically distinguishable transfected and endogenous IgD. Previously, we demonstrated that this cell line was not growth inhibited by antibodies directed at membrane IgD, but could be inhibited by antibodies which crosslink membrane IgM. Herein, we demonstrate that both anti-mu and anti-delta will cause calcium mobilization in this transfected cell line; this is followed by a period during which antibodies against the alternative isotype are unable to induce significant increases in intracellular calcium concentrations. This phenomenon, called "desensitization," is short-lived, lasting 20 min. We further demonstrate that acute desensitization of these cells by anti-delta has no effect on immediate growth inhibition which is elicited by anti-mu. These data confirm our earlier proposal that the rapid, initial calcium response seen in these lymphomas is not required for the negative signal for growth. Moreover, we also demonstrate that pretreatment of these lymphoma cells with phorbol myristate acetate (PMA) also renders these lymphoma cells temporarily incapable of manifesting a significant calcium signal. Nonetheless, PMA-pretreated B lymphoma cells are not altered in their subsequent sensitivity to anti-mu growth inhibition, nor are they affected in their resistance to inhibition by anti-delta. Our data confirm the proposal that neither the calcium signal nor protein kinase-C activation is involved in the modulation of B lymphoma growth.     

The murine B cell response to TNP-polyacrylamide beads: the relationship between the epitope density of the antigen and the requirements for T cell help and surface IgD

Spleen cells were cultured with high or low epitope TNP-polyacrylamide beads (TNP-PAB) in order to investigate the effect of epitope density on the requirements for T cell help and surface IgD on responding B cells. The response to low epitope density TNP-PAB was abolished by treatment with anti-Thy-1.2 and complement, whereas approximately 50% of the response to high epitope density TNP-PAB was retained after similar treatment. Thus, an increase in epitope density resulted in a decreased requirement for T cell help. An increase in epitope density was also associated with a decreased requirement for interaction of antigen and surface IgD as determined by "blocking" studies with anti-delta; further, the majority of the T-independent portion of this response was not blocked by anti-delta antibodies. This finding indicate that the T-independent portion of the anti-TNP response does not require interaction of antigen with surface IgD on B cells. These results are discussed in terms of differential cross-linking of IgM and IgD receptors on B cells by multivalent antigens.     

G protein coupling of antigen receptor-stimulated polyphosphoinositide hydrolysis in B cells

Cross-linking of the IgM and IgD Ag-R on mature B lymphocytes provokes the rapid hydrolysis of phosphatidylinositol 4,5-bisphosphate. We show here that in permeabilized, [3H]inositol-labeled mouse B cells the nonhydrolyzable GTP analogue GTP gamma S induces release of inositol phosphates, including inositol trisphosphate. The response is markedly augmented by the addition of polyclonal anti-Ig or anti-mu or anti-delta mAb. Inositol phosphate release provoked in intact B cells by any of the anti-receptor antibodies was not inhibited by pertussis toxin and only partially inhibited by cholera toxin. The results therefore indicate that both IgM- and IgD-R on B cells are coupled to the polyphosphoinositide-specific phosphodiesterase by one or more G proteins, which have yet to be identified.     

Cross-linking of B lymphocyte Fc gamma receptors and membrane immunoglobulin inhibits anti-immunoglobulin-induced blastogenesis

The Fc portion of rabbit anti-mouse immunoglobulin (Ig) antibodies interferes with anti-Ig-induced B lymphocyte activation as measured by DNA synthesis on day 3 of culture or maturation to Ig-secreting cells in the presence of soluble helper factors on day 4 or 5. To investigate this Fc-dependent effect at an earlier stage in B cell activation, rabbit IgG anti-mouse mu-chain- or delta-chain-specific antibodies were compared with their F(ab')2 fragments for the ability to induce mouse B cells to undergo blast transformation, as defined by an increase in cell volume during the first 24 hr of culture. Both F(ab')2 anti-Ig reagents induce blast transformation, although F(ab')2 anti-mu antibodies induce a greater size change than F(ab')2 anti-delta antibodies. Whole anti-mu or anti-delta antibodies do not induce blast transformation; however, in the presence of a monoclonal anti-mouse Fc gamma receptor antibody that blocks IgG binding to Fc gamma receptors (Fc gamma R), whole anti-mu or anti-delta antibodies induce blast transformation as well as their F(ab')2 fragments. Because the anti-Fc gamma R antibody alone has no effect on blast transformation, it appears that the simultaneous binding of membrane IgM (or IgD) and Fc gamma R by whole anti-Ig antibodies prevents this early event in membrane Ig-induced B cell activation.     

Evidence for an IgD homologue on chicken lymphocytes

Chicken lymphocyte membrane immunoglobulins (Ig), were precipitated with mouse monoclonal antibodies specific for heavy and light chain isotypes and analyzed by polyacrylamide gel electrophoresis. Very little or no membrane-bound IgG and IgA was detected. After sequential precipitation and removal of IgM reactive with any of three monoclonal anti-mu antibodies, anti-light chain antibody precipitated residual Ig with a relative electrophoretic mobility similar to that of IgM. Under reducing conditions, these surface Ig molecules had a heavy chain that appeared slightly larger (approximately 81,000 daltons) than mu-chain (approximately 79,000 daltons), and light chains of approximately 25,000 daltons. Complete clearance of membrane-bound IgM reactive with an anti-mu allotype antiserum left similar molecules precipitate by monoclonal anti-light chain antibody. These non-IgM molecules could be detected on the surface of lymphocytes from blood, spleen, bursa and the B cell line RAV-1, but not from thymus or blood from an agammaglobulinemic chicken. After capping of B cell surface IgM with anti-mu, immunofluorescent staining with anti-light chain antibody revealed residual Ig molecules disturbed across the surface of more than 90% of the IgM-bearing cells. The data suggest the existence of an avian homologue of mammalian IgD. Affinity-purified goat anti-mu antibodies and a fourth monoclonal anti-mu antibody reacted with both IgM and the putative IgD molecules, which suggests that the IgD homologue shares at least one common determinant with chicken IgM.     

Role of phosphatidylinositol 3-kinase in anti-IgM- and anti-IgD-induced apoptosis in B cell lymphomas

Cross-linking of surface Ig receptors with anti IgM (anti-mu heavy chain, anti-mu), but not anti-IgD (anti-delta heavy chain, anti-delta), Abs leads to growth arrest and apoptosis in several extensively characterized B cell lymphomas. By poorly understood mechanisms, both Igs transiently stimulate c-Myc protein expression. However, ultimately, only anti-mu causes a severe loss in c-Myc and a large induction of p27(Kip1) protein expression. Because phosphatidylinositol 3-kinase (PI3K) has been established as a major modulator of cellular growth and survival, we investigated its role in mediating anti-Ig-stimulated outcomes. Herein, we show that PI3K pathways regulate cell cycle progression and apoptosis in the ECH408 B cell lymphoma. Anti-mu and anti-delta driven c-Myc protein changes precisely follow their effects on the PI3K effector, p70(S6K). Upstream of p70(S6K), signaling through both Ig receptors depresses PI3K pathway phospholipids below control with time, which is followed by p27(Kip1) induction. Conversely, anti-delta, but not anti-mu stimulated PI3K-dependent phospholipid return to control levels by 4-8 h. Abrogation of the PI3K pathway with specific inhibitors mimics anti-mu action, potentiates anti-mu-induced cell death and, importantly, converts anti-delta to a death signal. Transfection with active PI3K kinase construct induces anti-mu resistance, whereas transfection with dominant negative PI3K augments anti-mu sensitivity. Our results show that prolonged disengagement of PI3K or down-regulation of its products by anti-mu (and not anti-delta) determines B cell fate.     

Polyclonal activation of the murine immune system by an antibody to IgD. XI. Contribution of membrane IgD cross-linking to the generation of an in vivo polyclonal antibody response

The injection of mice with a foreign, polyclonal antibody to IgD sequentially induces: 1) activation of B cells by cross-linking of their cell membrane (m) IgD; 2) B cell processing and presentation of the bound anti-IgD antibody to T cells; 3) activation of these T cells; and 4) T-dependent stimulation of B cell differentiation into IgG1 secreting cells. To determine whether the cross-linking of B cell membrane IgD and/or the resulting B cell activation that follows contribute to the generation of the polyclonal IgG1 response, we examined the abilities of three sets of anti-delta mAb or mAb fragments to stimulate polyclonal IgG1 production. Within each set mAb were matched for species and Ig isotypic determinants, but differed in avidity for IgD or in ability to cross-link IgD. In addition, experiments were performed to determine whether the anti-delta mAb had to be foreign to the immunized mouse to stimulate an IgG1 response. Results of these experiments indicate that: 1) recognition of the injected anti-delta antibody as foreign is required for the induction of a polyclonal IgG1 response; 2) the cross-linking of B cell membrane Ig, which directly activates B cells, can contribute considerably to the generation of in vivo IgG1 production; and 3) that even relatively weak cross-linking of membrane Ig by ligands that bind it with low avidity can make this contribution.     

Splenic B cells and antigen-specific B cells process anti-Ig in a similar manner

B lymphocytes can process and present antigen to T cells. However, the fate of native antigen after its binding to specific B cells, i.e., the intracellular events involved in the processing and recycling of the antigenic fragments to the cell surface for antigen presentation, are not well understood. In the present study, we demonstrate that murine B cells degrade anti-Ig molecules bound to their surface and release acid soluble fragments into the supernatant. We also demonstrate that the kinetics of this process are identical for anti-mu, anti-delta, and anti-light chain antibodies, indicating that both surface IgM and surface IgD are equally effective in binding antigen and directing its processing. We also describe the effects of azide, chloroquine, and irradiation on this process. To extend these studies to the processing of specifically bound antigen, we demonstrate that highly purified trinitrophenyl antigen-binding cells degrade anti-Ig molecules with the same kinetics as unpurified splenic B cells. Thus, this purified population provides a suitable model system for the analysis of antigen degradation by antigen-specific cells.     

Genetic control of B- and T-Lymphocyte abnormalities of NZB mice in crosses with B10.D2 mice

Parental NZB and B10.D2, F₁ and F₁ × B10.D2 mice were studied to determine the genetic control of (1) altered B-cell IgD expression, (2) plasma cell frequency, (3) IgM secretion per plasma cell, (4) primary in vitro cytotoxic T-cell responses to H-2-compatible cells, (5) production of thymocyte-binding antibodies, and (6) production of red-cell-specific antibodies. The results demonstrate that, in this cross, IgD abnormalities and production of red-cell-specific antibodies were recessive traits. There was a common genetic influence on plasma cell frequency, IgM secretion per plasma cell and production of thymocyte-binding antibodies which was distinct from the genes governing the ability to generate a cytotoxic T lymphocyte response to H-2-compatible cells.Abbreviations used in this paper CTL cytotoxic T lymphocyte - F1 anti-Fab fluorescein-labeled antimouse Fab - FMF flow microfluorometry - Ig immunoglobulin - IgM/PC IgM secretion per PC - PC plasma cell - sIg surface immunoglobulin - TBA thymocyte-binding antibody     

Hapten-specific murine colony-forming B cells. III. Delineation of functional B cell subpopulations grown under different conditions

The influence of anti-immunoglobulin M (IgM) and anti-IgD on the ability of fluorescein (FL)-specific B cells to proliferate in a colony-forming assay, and of their progeny to further differentiate in response to different FL-antigens was studied. Splenic FL-specific B cells were purified on FL-gelatin plates and were then cultured in semisolid agar in the presence or absence of anti-mu, and anti-delta, or both. Experiments were performed under conditions of either sheep red blood cell (SRBC)-potentiated or SRBC + lipopolysaccharide (LPS)-potentiated colony growth. The resulting colonies were then tested in secondary filler cell-dependent microcultures for the ability to be triggered by different classes of FL-antigens to yield plaque-forming cells (PFC). Anti-delta inhibited 47% of colony growth under both agar culture conditions. Anti-mu inhibited 55% of colony growth in SRBC + LPS-potentiated agar cultures, and inhibited 72% if only SRBC was present. If anti-delta and anti-mu were added together, inhibition was nearly additive. When anti-Ig-treated colonies were tested for PFC responses against FL-polymerized flagellin (POL), both normal and anti-delta resistant colonies, grown under both agar culture conditions, responded well. Anti-mu resistant colonies were refractory to FL-POL challenge. Only normal or anti-delta resistant colonies grown in SRBC + LPS agar cultures were able to respond well to FL-Ficoll, whereas even normal SRBC-potentiated colonies responded poorly. All except SRBC-potentiated, anti-mu treated colonies were able to respond to nonspecific signals present in cultures containing FL-KLH and activated T cell help. These data suggest that addition of specific anti-Ig antibodies, and variation of agar culture conditions, can select for B cell subpopulations responsive only to certain types of antigens.     

The influence of avidity on signaling murine B lymphocytes with monoclonal anti-IgM antibodies. Effects of B cell proliferation versus growth inhibition (tolerance) of an immature B cell lymphoma

We have investigated the effect of the avidity of a monoclonal anti-mouse IgM antibody (mAb) on its ability to activate normal B cells vs its capacity to inhibit the growth of an immature B lymphoma, BKS-2. A panel of seven mAb with specificities for four different domains of mu-heavy chain were selected and their relative avidities measured. Of the seven mAb studied, four antibodies (b7-6, Ak11, AK15, and DS1) were found to have relatively higher avidities than three others (AK17, 331.12, and Bet-2). Among them, the mAb b7-6 was highly efficient in inducing proliferation of normal B cells, whereas all others (including the remaining three high avidity mAb) were inefficient in inducing B cell proliferation. This failure cannot be simply related to the differences in their fine specificity because all the mAb became highly stimulatory after coupling to Sepharose beads. With one exception (DS1), avidity was a better predictor of the growth-stimulatory capacity when the antibodies were immobilized. Taken together, these findings suggested that although high affinity was important, there were other factors that might influence the mitogenic potential of a soluble anti-mu mAb. On the other hand, all anti-mu mAb irrespective of their avidity, fine specificity, and isotype were capable of effectively inhibiting the growth of BKS-2 cells. Furthermore, there was a direct correlation between the avidity and the dose of the mAb required to cause half-maximal inhibition of BKS-2 growth. The F(ab) fragments of high avidity mAb b7-6 failed to inhibit the growth of BKS-2 cells, which indicates that a minimal level of cross-linking of the membrane Ig receptor is necessary for causing growth inhibition in BKS-2 cells. Although there was no significant difference in the tolerogenic potential of soluble vs immobilized anti-mu mAb in directly inactivating BKS-2 cells, their growth-inhibitory capacity was remarkably different in the presence of rIL-5. Thus, rIL-5 was effective in partially overcoming the tolerogenic effect of soluble but not immobilized anti-mu mAb. Unlike IL-5, LPS rescued BKS-2 cells from the inhibitory effect of both soluble and immobilized anti-mu antibodies. Altogether, these results suggested that the ligand binding requisites for tolerance induction were less stringent than those for B cell activation. Furthermore, a high affinity interaction between membrane Ig receptor and its ligand appeared to generate a dominant negative signal that was not reversed by lymphokines.     

Effects of neonatal anti-delta antibody treatment on the murine immune system. I. Suppression of development of surface IgD+ B cells and expansion of a surface IgM+ IgD- B lymphocyte population

Lymphocytes that bear surface (s) IgD make up the majority of B cells in mature mice and are the precursors of most antibody secreting cells in primary immune responses made by these mice. In order to study the functional capabilities of the minority sIgD- B lymphocyte population and to gain insight into the possible roles of sIgD, we attempted to abort the development of sigD+ B cells and to expand the sigM+IgD- B cell population by treating mice from birth with affinity-purified rabbit antibodies specific for mouse IgD (RaM delta). RaM delta-suppressed mice had no detectable sIgD+ spleen, lymph node, or bone marrow cells and, on average, only 20% as many sIgM+Ia+ splenic B cells as control mice but had normal numbers of splenic T cells. Lymph nodes from anti-delta suppressed mice were even more depleted of B cells than were spleens from these mice, whereas the percentage of bone marrow B cells in these mice was relatively normal. Germinal centers of anti-delta suppressed mice were fairly normal in appearance, whereas follicular mantle layers, the locus of most sIgD+ B cells in normal mice, were greatly depleted. In addition to their lack of sIgD, splenic B cells of anti-delta suppressed mice differed from those found in control mice in that they bore, on average, twice as much sIgM as control cells, and in that they included an increased percentage of large, DNA synthesizing cells as compared with spleen cells from control mice. However, most sIgM+IgD- splenic B cells from anti-delta suppressed mice were small, nonproliferating cells. B cells from anti-delta suppressed mice insert little or no sIgD into their cell membranes since they continued to bear no detectable sIgD 2 days after in vivo neutralization of RaM delta and since, unlike B cells from control mice, they failed to be activated by a single in vitro injection of a goat anti-mouse delta antibody. Despite their lack of sIgD+ B cells, anti-delta suppressed mice had relatively normal levels of serum IgG as well as normal to increased levels of serum IgM. Thus, sIgM+IgD- B cells appear to have the potential of differentiating into Ig secreting cells in vivo without acquiring sIgD.     

Lymphokine-induction of memory B-cell differentiation: differential stimulation of large virgin and memory B-cell differentiation

In order to compare and contrast the requirements of virgin and memory B cells for B-cell differentiation factors, a model system was developed in which low-density rat B cells isolated from 4-week primed antigen-draining lymph nodes were cultured in vitro. This large low-density cell population contained B cells which were 90% surface IgM positive and 60% IgD positive and showed moderately elevated Ia staining. When the cell population was stimulated with antigen plus lymphokines or lymphokines alone, antigen-specific IgG antibody was secreted; this was used as a measure of memory cell differentiation. When the cell population was stimulated with mitogen (lipopolysaccharide plus dextran sulfate) plus lymphokines, polyclonal IgG and IgM secretion was seen and was used as a measure of virgin B-cell differentiation. Using this system, we found that lymphokines contained in a Con A-induced rat spleen cell supernatant (CSN) were sufficient to drive both memory and virgin B-cell differentiation. In contrast, lymphokines contained in the supernatant from the murine T-cell hybridoma B151K12 (B151CFS) were able to induce large amounts of polyclonal IgM and IgG secretion but did not support memory B-cell differentiation. When recombinant human IL-2 was added to these cultures, it acted synergistically to augment virgin B-cell differentiation, but this combination of lymphokines was still not able to support memory B-cell differentiation. Furthermore, recombinant rat interferon-gamma and a commercial source of human BCGF, with or without IL-2, were unable to promote significant virgin or memory B-cell differentiation. These data support the hypothesis that memory B cells and virgin B cells differ in their lymphokine requirements for differentiation into antibody-secreting cells.     

Trypanosomiasis-induced B cell apoptosis results in loss of protective anti-parasite antibody responses and abolishment of vaccine-induced memory responses

African trypanosomes of the Trypanosoma brucei species are extra-cellular parasites that cause human African trypanosomiasis (HAT) as well as infections in game animals and livestock. Trypanosomes are known to evade the immune response of their mammalian host by continuous antigenic variation of their surface coat. Here, we aim to demonstrate that in addition, trypanosomes (i) cause the loss of various B cell populations, (ii) disable the hosts' capacity to raise a long-lasting specific protective anti-parasite antibody response, and (iii) abrogate vaccine-induced protective response to a non-related human pathogen such as Bordetella pertussis. Using a mouse model for T. brucei, various B cell populations were analyzed by FACS at different time points of infection. The results show that during early onset of a T. brucei infection, spleen remodeling results in the rapid loss of the IgM(+) marginal zone (IgM(+)MZ) B cell population characterized as B220(+)IgM(High)IgD(Int) CD21(High)CD23(Low)CD1d(+)CD138(-). These cells, when isolated during the first peak of infection, stained positive for Annexin V and had increased caspase-3 enzyme activity. Elevated caspase-3 mRNA levels coincided with decreased mRNA levels of the anti-apoptotic Bcl-2 protein and BAFF receptor (BAFF-R), indicating the onset of apoptosis. Moreover, affected B cells became unresponsive to stimulation by BCR cross-linking with anti-IgM Fab fragments. In vivo, infection-induced loss of IgM(+) B cells coincided with the disappearance of protective variant-specific T-independent IgM responses, rendering the host rapidly susceptible to re-challenge with previously encountered parasites. Finally, using the well-established human diphtheria, tetanus, and B. pertussis (DTPa) vaccination model in mice, we show that T. brucei infections abrogate vaccine-induced protective responses to a non-related pathogen such as B. pertussis. Infections with T. brucei parasites result in the rapid loss of T-cell independent IgM(+)MZ B cells that are normally functioning as the primary immune barrier against blood-borne pathogens. In addition, ongoing trypanosome infections results in the rapid loss of B cell responsiveness and prevent the induction of protective memory responses. Finally, trypanosome infections disable the host's capacity to recall vaccine-induced memory responses against non-related pathogens. In particular, these last results call for detailed studies of the effect of HAT on memory recall responses in humans, prior to the planning of any mass vaccination campaign in HAT endemic areas.     

Effects of neonatal anti-delta antibody treatment on the murine immune system. II. Functional capacity of a stable sIgM+sIa+sIgD- B cell population

Mice were injected from birth with rabbit anti-mouse IgD (RaM delta). Studies in the accompanying paper indicated that the B cells from these mice have a stable sIgM+sIa+sIgD- B cell population. In the studies presented herein the in vivo and in vitro antibody responses of these mice were examined as well as their responsiveness to various B cell mitogens. The results indicate that splenic B cells from RaM delta-suppressed mice differ from normal adult murine splenic B cells by failure to express increased sIa antigen after in vitro stimulation with soluble anti-mu antibodies and failure to proliferate in response to in vitro stimulation with either soluble or Sepharose-bound anti-mu antibody. Nevertheless, these mice generate relatively normal in vivo IgM and IgG antibody responses to TI-2 and to both high and low epitope density forms of TD antigens as well as secondary IgG antibody responses to a TD antigen. In addition, B cells from RaM delta-treated mice generate relatively normal primary in vitro IgM antibody responses to TI-1, TI-2, and TD antigens. These data suggest that sIgD- B cells can produce antibody responses to the majority of antigenic signals even though they appear to lack one or more differentiative pathways.     

Immunity to melanoma mediated by 4-1BB is associated with enhanced activity of tumour-infiltrating lymphocytes

4-1BB costimulates T cells to carry out effector functions such as eradication of established tumours. 4-1BB (CD137) is a member of the TNF receptor family, and its triggering by either 4-1BB ligand or antibody ligation induces T-cell activation and growth. We analysed tumour-infiltrating lymphocytes (TIL) in the experimental B16F10 melanoma model to determine the mechanisms involved in 4-1BB-mediated tumour suppression. 4-1BB(+/+) mice survived longer than 4-1BB(-/-) mice, and survival was further prolonged by triggering 4-1BB with an agonistic mAb. The number of metastatic B16F10 colonies in the lung was much greater in 4-1BB(-/-) mice than in their 4-1BB(+/+) littermates. Administration of agonistic anti-4-1BB mAb increased the number of TIL in the tumour masses in the lungs of 4-1BB(+/+) mice. The numbers of CD4(+) T, CD8(+) T and CD11b(+) TIL increased in these mice. Anti-4-1BB mAb induced not only CD8(+) 4-1BB(+) T cells but also a CD8(+) IFN-gamma(+) T-cell population. B16F10 cells from the lungs of anti-4-1BB-treated mice showed enhanced expression of MHC class Iota and IotaIota antigens compared with the same cells from control IgG-treated mice. Thus, the increase in number of CD8(+) T cells and enhanced MHC Iota and IotaIota expression in B16F10 cells that result from augmented IFN-gamma production in response to anti-4-1BB mAb may lead to suppression of tumour growth and metastasis.     

The resolution of relapsing fever borreliosis requires IgM and is concurrent with expansion of B1b lymphocytes

The rate of pathogen clearance is a critical determinant of morbidity and mortality. We sought to characterize the immune response responsible for the remarkably rapid clearance of individual episodes of bacteremia caused by the relapsing fever bacterium, Borrelia hermsii. SCID or Rag(-/-) mice were incapable of resolving B. hermsii infection, indicating a critical role for T and/or B cells. TCR(-/-) mice, which lack T cells, and IL-7(-/-) mice, which are deficient in both T cells and follicular B cells, but not in B1 cells and splenic marginal zone (MZ) B cells, efficiently cleared B. hermsii. These findings suggested that B1 cells and/or MZ B cells, two B cell subsets that are known to participate in rapid, T-independent responses, might be involved. The efficient resolution of the episodes of moderate level bacteremia by splenectomized mice suggested that MZ B cells do not play the primary role in clearance of this bacterium. In contrast, xid mice, which are deficient in B1 cells, suffered more severe episodes of bacteremia than wild-type mice. The hypothesis that B1 cells are critical for clearance of B. hermsii was further supported by a selective expansion of the B1b (i.e., IgM(high), IgD(-/low), Mac1(+) CD23(-), and CD5(-)) cell subset in infected xid mice, which coincided with the eventual resolution of infection. Finally, mice selectively incapable of secreting IgM, the dominant isotype produced by B1 cells, were completely unable to clear B. hermsii. Together these results support the model that B1b cells generate the T-independent IgM required for the control and resolution of relapsing fever borreliosis.     

Anti-IgD enhancement of primary antibody responses in rats

The role of membrane IgD in immune responses was examined by treating adult rats with anti-IgD. Anti-IgD when administered to rats in conjunction with optimal or suboptimal doses of either SRBC, a T-dependent antigen, or DNP-Ficoll, a T-independent antigen, enhanced the antibody responses. The greatest enhancement was obtained when anti-IgD was administered before the antigen. The effects of anti-IgD on antibody responses to SRBC were: (i) significant antibody responses to suboptimal antigen concentrations; (ii) greater antibody responses to optimal antigen concentrations; (iii) accelerated antibody responses; (iv) an early shift from IgM to IgG antibodies; (v) prolonged antibody responses. Similar effects on the immune response to DNP-Ficoll were observed with the exception that all antibodies were 2ME sensitive (IgM). These results suggest that an anamnestic type of immune response can be induced in anti-IgD-treated rats when given a primary antigen exposure. Injection of anti-IgD without SRBC or DNP-Ficoll induces B-cell proliferation without detectable antibody production to these antigens, indicating at least two signals are required for the enhanced antibody responses.