Human in vivo antigen-induced lymphoblastoid B cells are capable of cyclical antibody production in vitro

In vivo immunization of normal volunteers with tetanus toxoid induces the formation of a circulating B cell subset that has the capacity to secrete specific antibody in vitro without the need for T cell help or mitogen stimulation. From earlier studies it was not clear whether the spontaneous antibody-secreting lymphoblastoid (LB) B cell was at a terminal stage of differentiation or if it had the capacity to give rise to additional B cell subsets, such as memory cells or more fully mature antibody-producing cells. In this study we have shown that at least two distinct waves of spontaneous antibody secretion can occur in vitro when cultures are initiated with the lymphocytes from individuals immunized 6 days earlier. The first production of antibody was completed by 3 days of in vitro culture and the second production of antibody did not initiate until day 7 or 8 of culture and was completed by day 12. The B cells responsible for the second stage of antibody production appeared derived from a portion of the antibody-secreting cells present on day 3 in that 1) treatment of the cultures on day 0 with BuDr and light equally inhibited the first and second rounds of antibody synthesis; 2) when isolated from the blood, both B cell subsets were in the large cell fraction after 1 X G sedimentation; and 3) under conditions of limiting numbers of cells, the cells responsible for the second wave of antibody production were almost exclusively found in cultures positive for a B cell that had produced antibody on days 1 to 3. Although only a portion (10 to 30%) of the LB B cells present on day 0 had the capacity to again produce antibody on days 8 to 12, the two cells were capable of producing similar quantities of antibody on a per cell basis. These results indicate that the mature circulating LB cell induced in vivo by immunization is not terminally differentiated, but under appropriate conditions has the capacity to give rise to additional antibody-secreting cells.     

Optimization of an ovine antibody-secreting cell assay for detection of antigen-specific immunoglobulin production in peripheral blood leukocytes

Enumeration of antibody-secreting cells in peripheral blood by enzyme-linked immunospot (ELISPOT) has been used in human studies to detect antigen-specific antibody production at mucosal tissue sites. An alternative assay for detecting and quantitating antigen-specific antibody responses involves culturing circulating peripheral blood antibody-secreting cells and quantitating specific antibody production in culture supernatant by ELISA. In the present study, antigen-specific peripheral blood lymphocytes were isolated from subcutaneously immunized sheep and the parameters for maximizing in vitro antibody production by in vivo-induced antibody-secreting cells optimized for this species. Maximum antibody-secreting cell responses were observed in peripheral blood collected four days after antigen challenge. The addition of lipopolysaccharide and antisheep immunoglobulin had no effect on in vitro antibody secretion by blood antibody-secreting cells, while the effects of pokeweed mitogen were highly variable. However, the combination of anti-Ig and recombinant ovine interleukin-6 to peripheral blood lymphocyte cultures was found to markedly and consistently enhance specific antibody production. In unstimulated cultures, the optimal peripheral blood lymphocyte concentration for generating the greatest antibody responses was 5.0 x 107 cells per mL, but in cultures stimulated with recombinant ovine interleukin-6/antisheep immunoglobulin, the optimal cell concentration was lowered to approximately 1.0 x 107 cells per mL. In vitro, peak immunoglobulin production was usually achieved by day one in unstimulated cultures. In recombinant ovine interleukin-6/antisheep immunoglobulin-stimulated cultures, antibody levels were similar to unstimulated cultures by day one, however, the levels continued to rise during incubation to reach a maximum between days four and five of incubation. This optimized antibody-secreting cell culture assay is amenable for increasing the sensitivity and reducing the cell numbers required for quantitating antigen-specific antibody induction in large-scale immunization trials in sheep and other large animal species.     

Selective activation of antigen-specific human B cells in recently immunized individuals by nonspecific factors in the absence of antigen

The in vitro effect of nonspecific factors (derived from mixed lymphocyte culture [MLC] supernatants) on human B cell responses was studied in individuals recently immunized in vivo to keyhole limpet hemocyanin, tetanus toxoid, and/or diphtheria toxin. In T cell-depleted fractions of peripheral blood mononuclear cells, nonspecific factors alone, without antigen, selectively induced a specific antibody response to the antigen to which the individual had been recently immunized, at dilutions that did not generate a significant polyclonal response in the remainder of the B cell repertoire. The source of these factors, with respect to MLC donors, did not affect the antibody response. Supernatants of MLC from nonimmunized individuals induced a specific antibody response as effectively as supernatants of MLC from immunized individuals, when added to B cells plus monocytes from recently immunized individuals. Studies in which the same individuals were followed over time showed that these factor-sensitive B cells are seen in the peripheral blood of recently immunized individuals for only a finite period of time. Thus, in vivo immunization with a specific antigen results in the transient appearance in the peripheral blood of B cells that are specific for the antigen in question. These B cells are probably preactivated in that nonspecific factors selectively induce in vitro their further differentiation into antibody-secreting cells, in the absence of added antigen or mitogen. These studies may add further insight into our understanding of the sequential steps involved in the activation and differentiation of human B lymphocytes and provide a model for the combined in vivo and in vitro study of human B cell physiology.     

Interleukin 6 is essential for antibody secretion by human in vivo antigen-induced lymphoblastoid B cells

In vivo immunization of normal subjects with a variety of antigens generates circulating lymphoblastoid (LB) B cells, which in vitro spontaneously secrete significant levels of specific antibody. Since activation and initial differentiation of these cells occurs in vivo, they provide a useful model for the study of the later stages of B cell maturation. In the present study, we investigated the requirement of interleukin 6 (IL-6) for the "spontaneous" in vitro production of IgG-Tet by LB B cells. Addition of IL-6 to cultures of LB B cells in medium supplemented with 10% fetal calf serum failed to increase the levels of IgG-Tet produced in vitro. However, addition of anti-IL-6 antibodies decreased IgG-Tet production as much as 70%, and this inhibition could be reversed by the addition of IL-6. LB B cells cultured in serum-free medium in order to restrict endogenous IL-6 production secreted only low levels of antibody, unless exogenous IL-6 was added. Addition of 2.5 units/ml of IL-6 to serum-free cultures induced an increase in IgG-Tet secretion nearly comparable to that seen in cultures supplied with serum. The magnitude of the increase in IgG-Tet secretion in response to exogenous IL-6 was inversely related to the number of cells in culture, which was due in part to increased endogenous IL-6 production in cultures with higher cell concentrations. Experiments including hydroxyurea in serum-free cultures indicated that IL-6-dependent enhancement of LB B cells' IgG-Tet secretion was not primarily mediated by cell growth. These observations suggest that in vivo generated LB B cells are not totally committed to antibody secretion, and that IL-6 is essential for in vivo antigen-induced LB B cells to reach the antibody-secreting stage.     

Generation of nondividing high rate Ig-secreting plasma cells in cultures of human B cells stimulated with anti-CD3-activated T cells.

The capacity of human B cells to differentiate into high rate nondividing antibody-secreting plasma cells was investigated. Highly purified human peripheral blood B cells were stimulated with polyclonal B cell activators in the presence of a variety of recombinant cytokines (IL-2, IL-4, IL-6). Maximal production of Ig of all isotypes was observed when B cells were stimulated with intact T cells that were activated with mAb to the CD3 molecular complex. In these cultures, Ig production continued for more than 16 days. Moreover, differentiation to nondividing high rate Ig-producing cells was induced, as evidenced by a ninefold increase in the amount of Ig produced per Ig-secreting cell and the acquisition of resistance of ongoing Ig secretion to the inhibitor of DNA synthesis, hydroxyurea. To determine whether intact T cells were required for the entire culture period to achieve maximal Ig production, B cells were cultured with activated T cells for various lengths of time, reisolated and cultured with fresh activated T cells or various cytokines, then analyzed for Ig secretion. B cells preactivated for 6 days with anti-CD3-stimulated T cells required contact with intact T cells for continued Ig secretion. However, after 9 days of preactivation, dividing B cells responded maximally to anti-CD3-stimulated T cells, whereas cytokines were able to drive continued IgG secretion by nondividing B cells in the absence of intact T cells. IL-6 alone, or in combination with either IL-2 or IL-4, was the major cytokine driving ongoing Ig secreting by nondividing preactivated B cells. These results suggest that continued clonal expansion of Ig-secreting B cell blasts requires intact anti-CD3-activated T cells, whereas terminal differentiation of B cells into plasma cells after extensive clonal expansion is driven by cytokines, most notably IL-6.     

Human peripheral blood lymphocytes from recently vaccinated individuals produce both type-specific and intertypic cross-reacting neutralizing antibody on in vitro stimulation with one type of poliovirus

An in vitro system of poliovirus-specific antibody production by peripheral blood B cells on stimulation by the virus has been developed. Virus-neutralizing antibodies in culture supernatant fluids, or virus-specific antibody-secreting cells (ASC) were detected by microneutralization assay and ELISA-SPOT test, respectively. After booster immunization with polio vaccine, anti-poliovirus-neutralizing ASC were present in circulation. This response was measurable between 5 and 12 days after booster vaccination. At between 12 and 90 days, another subset of B cells was found in peripheral blood that only produced poliovirus-specific neutralizing antibody after in vitro antigenic stimulation. The in vitro virus-induced response required B cells, monocytes, and T4+ (T helper) cells, and was shown to result from de novo protein synthesis. The anti-poliovirus-neutralizing response in vitro could be dissected in a type-specific and intertypic cross-reactive response by using various antigen concentrations for in vitro stimulation. Evidence was obtained by absorption studies for the existence of intertypic cross-reactive neutralization-inducing epitopes.     

In vivo effects of recombinant human interleukin 6, alone or in combination with local irradiation, on tumor growth in Lewis lung carcinoma-bearing mice

Lewis lung carcinoma (LLC)-bearing mice were used as a mouse model to evaluate effects of recombinant human (rh) interleukin (IL) 6 and local X-irradiation (LR) on the growth of primary tumors and lung metastases. Mice were inoculated s.c. with LLC tumor cells and then treated with rhIL-6 (100 ng/dose) s.c. twice a day (b.i.d.) for 5 days, beginning 6 days after tumor inoculation. LR (800 cGy) was administered to the site of the primary tumor 6 days after tumor inoculation and again 1 wk later. Mice were then observed for survival or sacrificed at day 21 after tumor inoculation to determine size of primary tumor, numbers and size of lung metastases, and other hematological parameters including numbers of granulocyte-macrophage progenitor cells (CFU-gm). The size of the primary tumor and numbers of lung metastases were reduced by rhIL-6. LR enhanced the antitumor effect of rhIL-6 significantly, while LR alone had only a slight antitumor effect. Tumor-associated increases in peripheral blood, femoral marrow, splenic-nucleated cellularity, and marrow and splenic CFU-gm were reduced in mice treated with rhIL-6 plus LR. Prolonged survival time was observed only in tumor-bearing mice treated with rhIL-6 in combination with LR. The antitumor effects in vivo of rhIL-6 appear to be mediated indirectly as rhIL-6 had no effect on proliferation of LLC cells in vitro as assessed by colony and 3H-thymidine incorporation assays. These studies suggest that rhIL-6 may have therapeutic value in the treatment of certain malignancies, especially if used in combination with LR.     

A novel human T cell antigen preferentially expressed on mature T cells and shared by both well and poorly differentiated B cell leukemias and lymphomas

A new lymphocyte differentiation antigen shared by all normal T cells and some malignant B cells was defined by a monoclonal antibody designated 12.1. This antibody reacted with all peripheral blood T cells but not with normal B cells and B cell lines. Analysis with a fluorescence activated cell sorter showed that the expression of 12.1 antigen changes during T cell maturation. Most thymocytes, blasts of acute T cell leukemia, and cells from established leukemic T cell lines bear a small amount of 12.1 antigen. In contrast the majority of peripheral blood T cells, activated T cells, and leukemic T cells of the Sezary syndrome bear a large amount of 12.1 antigen. Unexpectedly, antibody 12.1 reacted with leukemic cells from most patients with B-type chronic lymphocytic leukemia (CLL) and some patients with lymphosarcoma cell leukemia (LSCL). Among these leukemias, expression of the 12.1 antigen was not correlated with the stage of B cell maturation, with the amount of surface immunoglobulin on the cells, or with the presence or absence of monoclonal gammapathy. In a comparative serologic analysis the antigen defined by antibody 12.1 was distinct from the p67 T cell antigen (defined by monoclonal antibody 10.2) that is also known to be expressed by B-type CLL cells.     

Synergy of helper factors in the differentiation of in vivo-preactivated antigen-specific human B cells

After in vivo immunization with antigen, B cells appear in the peripheral blood which can be induced in vitro by nonspecific factors found in mixed lymphocyte culture supernatants (MLC-SN) to differentiate and secrete antibody specific for the immunizing antigen. In order to further delineate the nature of the factors involved in the differentiation of these in vivo-activated B cells, various helper factors, including interleukin 1 and interleukin 2 (IL-1 and IL-2), B-cell growth factor (BCGF), and B-cell differentiation factor (BCDF) were added separately and in combination to cultures of these preactivated B cells. T-cell-depleted fractions of peripheral blood mononuclear cells were obtained from normal individuals immunized in vivo with keyhole limpet hemocyanin. MLC-SN alone, without the addition of antigen, selectively triggered an antibody response specific for the antigen used to immunize in vivo in the absence of a polyclonal B-cell response. In order to obtain responses equal to those seen with MLC-SN, a combination of BCGF, IL-2, and BCDF was required, although any two factors partially reconstituted the response. Exogenous IL-1 had the least effect but was suppressive in the presence of optimal concentrations of monocytes. Thus, for maximal in vitro differentiation of in vivo-preactivated B cells, a combination of at least three helper factors is required and acts in a synergistic manner to induce antigen-specific antibody responses.     

Human polysaccharide-specific B cells are responsive to pokeweed mitogen and IL-6

The responsiveness of polysaccharide-specific B cells to PWM was examined in vitro. Spleen cells from six patients immunized with Haemophilus influenzae type b-diphtheria toxoid, pneumococcal and meningococcal vaccines were T cell-depleted and separated by Percoll density gradient centrifugation. In each B cell fraction, spontaneous antibody production was demonstrated to capsular polysaccharides as well as diphtheria toxoid. The peak of spontaneous antibody production was demonstrated to be five to seven days after immunization. When T cells and PWM were added, the total Ig secretion increased in all B cell fractions. PWM also enhanced IgG antibody directed to each of three polysaccharide Ag measured. This enhancement was most noticeable for nonresting B cells. The PWM effect was not confined to IgG, as IgM and IgA to Neisseria meningitidis type C were measured and also enhanced. The kinetics of the PWM response demonstrated the most IgG antibody to polysaccharide Ag from spleens immunized five to seven days before splenectomy. When the patients were immunized either 2 days or 4 mo before splenectomy, no spontaneous IgG antibody to polysaccharides was detected although PWM induced small amounts of antibody. Finally, anti-IL-6 antibody blocked PWM-induced total and polysaccharide-specific antibody production. We conclude that human polysaccharide-specific B cells are responsive to PWM and IL-6. We suggest that polysaccharide B cells are not truly "T cell-independent" and may respond to T cell lymphokines and thus are similar to protein-specific B cells.     

Stimulation of human B cells specific for Candida albicans for monoclonal antibody production

Abstract The stimulation and immortalisation of human peripheral blood B lymphocytes specific for Candida albicans antigen were investigated. An in vitro immunisation system was employed which involved pretreatment of mononuclear cells with l -leucyl l -leucine methyl ester which removes the suppressive effects of CD8 + T cells, NK cells and monocytes. The remaining cells, CD4 + T cells, B cells and dendritic cells, were cultured with antigen and a mixture of cytokines. A mixture of IL-2, −4 and −6 was found to be optimal for antibody production as determined by an Elispot assay. Transformation of the activated B cells by Epstein Barr virus was found to be optimal after 2 days and lines secreting anti- Candida antibodies were established. These lines could form the basis for specific monoclonal antibody production by generating hybridomas, or by a newly described technique whereby cDNA encoding antibody Fab regions is transferred into phage display libraries. The overall strategy might be generally applicable for the generation of human monoclonal antibodies to infectious agents.     

Comparison of the influenza virus-specific effector and memory B-cell responses to immunization of children and adults with live attenuated or inactivated influenza virus vaccines

Cellular immune responses to influenza virus infection and influenza virus vaccination have not been rigorously characterized. We quantified the effector and memory B-cell responses in children and adults after administration of either live attenuated (LAIV) or inactivated (TIV) influenza virus vaccines and compared these to antibody responses. Peripheral blood mononuclear cells were collected at days 0, 7 to 12, and 27 to 42 after immunization of younger children (6 months to 4 years old), older children (5 to 9 years old), and adults. Influenza virus-specific effector immunoglobulin A (IgA) and IgG circulating antibody-secreting cells (ASC) and stimulated memory B cells were detected using an enzyme-linked immunospot assay. Circulating influenza virus-specific IgG and IgA ASC were detected 7 to 12 days after TIV and after LAIV immunization. Seventy-nine percent or more of adults and older children had demonstrable IgG ASC responses, while IgA ASC responses were detected in 29 to 53% of the subjects. The IgG ASC response rate to LAIV immunization in adults was significantly higher than the response rate measured by standard serum antibody assays (26.3% and 15.8% by neutralization and hemagglutination inhibition assays, respectively). IgG ASC and serum antibody responses were relatively low in the younger children compared to older children and adults. TIV, but not LAIV, significantly increased the percentage of circulating influenza virus-specific memory B cells detected at 27 to 42 days after immunization in children and adults. In conclusion, although both influenza vaccines are effective, we found significant differences in the B-cell and antibody responses elicited after LAIV or TIV immunization in adults and older children and between young children and older age groups.     

Recombinant human (rh)IL-4-mediated apoptosis and recombinant human IL-6-mediated protection of recombinant human stem cell factor-dependent human mast cells derived from cord blood mononuclear cell progenitors.

Although stem cell factor (SCF) appears to be the major growth factor for human mast cells, other factors undoubtedly play important roles in the development, survival, and function of these cells. The current study examined the effects of recombinant human (rh) IL-4 and rhIL-6 on rhSCF-dependent development and survival of human mast cells derived in vitro from cord blood progenitor cells. After 4-8 wk of culture with rhSCF and various amounts of rhIL-4, a dramatic decline in mast cell numbers was observed with rhIL-4, the EC50 being about 0.1 ng/ml. Numbers of other cell types remained high. Mast cells derived from cord blood progenitors after 7 wk of culture with rhSCF alone displayed an MCT phenotype and expressed Kit, FcepsilonRI, and IL-4R on their surface. Mast cells examined after purification by immunomagnetic sorting became apoptotic within hours after exposure to rhIL-4, a phenomenon blocked by anti-IL-4 Ab. Because rhIL-4-dependent apoptosis but not the loss of mitochondrial membrane potential was prevented by the pan-caspase inhibitor benzyloxycarbonyl-Val-Ala-Asp-(Z-VAD)-fluoromethylketone, mitochondrial perturbation most likely preceded caspase activation. Consistent with this conclusion was the observation that both apoptosis and loss of mitochondrial membrane potential (Deltapsim) were inhibited by cyclosporin A in combination with aristolochic acid. rhIL-6 protected cord blood mast cells from rhIL-4-induced apoptosis. Thus, IL-4 can cause both maturation and apoptosis of human mast cells, the latter effect being abrogated by IL-6.     

Differential regulation of activation, clonal expansion, and antibody secretion in human B cells

Limiting dilution analysis, hemolytic plaque assay, and ELISA procedures were used to study the recruitment, clonal expansion, and antibody secretion in human TNP-specific B cells activated in the presence of TNP-ovalbumin (TNP-OA), pokeweed mitogen (PWM), or regulatory T cells. TNP-OA-responsive, hapten-specific PFC precursor cells occupy approximately 0.5% of all sIgM+/sIgD+ B cells in cord blood, bone marrow, peripheral blood, and tonsil. The PWM-responsive, hapten-specific PFC precursor pool is 70 to 90% smaller and does not express sIgD. Antigen-reactive B cells go through a minimum of three divisions in culture (six to nine PFC per clone), and antibody secretory rates of about 10(4) molecules IgM/cell/hr are achieved. In contrast, PWM-induced clone sizes were at least 60 PFC per clone, with antibody secretory rates of approximately 6 to 7 X 10(4) molecules IgM/cell/hr. Addition of high-dose carrier-primed suppressor T cells to limit dilution cultures reduced PFC precursor cell recruitment by up to 99%. However, in the few clones escaping from suppression, both clonal expansion and antibody secretory rates were much higher than in suppressor cell-free cultures, generating 30 to 60% of the antibody secreted in controls but with consequently much more restricted clonal diversity. When limiting dilution cultures were compared with standard microcultures of 2 X 10(5) cells, both clonal expansion and antibody secretory rates were much lower than expected, with a culture efficiency calculated to be 10 to 20% of that in low-density cultures. Our data suggest that the B cell subsets activated by antigen and by mitogen differ in their abilities for clonal expansion and antibody secretion. The hapten-specific and -responsive B cell family is expressed early in ontogeny, and in adults it is distributed evenly throughout the body. These limiting dilution experiments revealed that the primary effect of regulatory T cells is a drastic reduction in clonal diversity, and much less a mere reduction in overall response magnitude.     

In vitro induction of a Haemophilus influenzae type b polysaccharide-specific antibody response in human peripheral blood lymphocytes of individuals recently vaccinated with an oligosaccharide-protein conjugate.

In this paper an in vitro culture system for the induction of an antibody response to the Haemophilus influenzae type b polysaccharide (PRP) is described. Anti-PRP IgM and IgG antibody-secreting cells (ASC) and anti-diphtheria toxoid (DT) IgG ASC were detected in cultures of blood B and T cells derived from donors 4 to 6 wk after immunization with Haemophilus influenzae type b oligosaccharide-mutant diphtheria toxin (CRM197) conjugate (HbOC) and required in vitro restimulation with HbOC. When lymphocytes from HbOC-vaccinated donors were stimulated with PRP, anti-PRP IgM and IgG ASC could be detected in 50% offGe cases. Lymphocytes from PRP-vaccinated donors or non-vaccinated donors consistently failed to generate anti-PRP antibodies after in vitro stimulation with HbOC. Optimal in vitro responses were observed at concentrations of 0.06 to 0.6 micrograms/ml of Ag. At higher doses of Ag (6 micrograms/ml) anti-PRP and anti-DT antibody responses were suppressed. The in vitro generation of anti-PRP and anti-DT ASC, as detected by a spot-forming cell assay was shown to be T cell dependent, Ag dependent, and Ag specific. This culture system provides a model for the study of human B cell activation and immunoregulation by polysaccharide-protein conjugates and polysaccharides.     

Sequential effect of a high molecular weight B cell growth factor and of interleukin 2 on activated human B cells

A high m.w. B cell growth factor (50,000 BCGF) prepared from lectin-activated human peripheral blood lymphocyte culture supernatants acts only on B cells preactivated by a first signal. This first signal can be delivered in vitro (with anti-mu antibody (Ab)) or in vivo. Upon costimulation with anti-mu Ab the 50,000 BCGF induces an early and transient proliferative response, whereas the response to interleukin 2 (IL-2) develops more progressively. To determine the respective targets of the 50,000 BCGF and of IL-2, B cells were activated with anti-mu Ab and separated according to the expression of the IL-2 receptor (cluster designation (CD)25 antigen). CD25+ B cells do not respond to the 50,000 BCGF and do not acquire this responsiveness after an additional culture with IL-2. CD25- B cells respond to the 50,000 BCGF and not to IL-2. However, when CD25- B cells are cultured for 3 days with the 50,000 BCGF they become responsive to IL-2. These results demonstrate a pathway of B cell activation based on the ordered and sequential action of anti-mu Ab, the 50,000 BCGF, and IL-2.     

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.     

Characterization of a human B lymphocyte-specific antigen

A human B lymphocyte-specific antigen (B1) was identified and characterized by the use of a monoclonal antibody. By indirect immunofluorescence, cytotoxicity, and quantitative absorption, B1 was present on approximately 9% of the peripheral blood mononuclear cell fraction and >95% of B cells from blood and lymphoid organs in all individuals tested. Monocytes, resting and activated T cells, null cells, and tumors of T cell and myeloid origin were B1 negative. B1 was distinct from standard B cell phenotypic markers, including Ig and Ia antigen. Removal of the B1 positive population in peripheral blood eliminated all B cells capable or responding to pokeweed mitogen by maturation to Ig-producing cells.     

Dual fluorochrome analysis of human B lymphocytes: phenotypic examination of resting, anti-immunoglobulin stimulated, and in vivo activated B cells

B cell-enriched preparations were prepared from human peripheral blood and lymphoid tissues by the depletion of T cells and monocytes. Only B cells by virtue of their staining with anti-B1 conjugated to fluorescein were additionally examined. Dual fluorescence staining and flow cytometric analysis demonstrated that the majority of "resting" human peripheral blood and splenic B cells co-express the B cell-restricted B1 and B2 antigens and lack B5, a B cell-restricted activation antigen, and interleukin 2 receptor (IL 2R). In contrast, nearly 2/3 and 1/3 of B1+ cells isolated from lymph node expressed IL 2R and B5 antigens, respectively. When B1+ B cells from peripheral blood and spleen were "activated" by anti-Ig, they lost the B2 antigen and acquired the B5 and/or IL 2R antigens. 2/3 of B1+ cells strongly expressed IL 2R, and up to 1/2 of B1+ cells co-expressed B5. Delineation of increased numbers of B1+ cells that co-express B5 and/or IL 2R within lymphoid tissues obtained from patients with diseases characterized by "activated" B cells provides in vivo confirmation that these phenotypic changes correlate with B cell activation. We believe that the identification and isolation of these and similar subsets of cells defined by differing cell surface phenotypes should further our understanding both of normal B cell activation and the pathophysiology of B cell disease states.     

IgE enhances antibody and T cell responses in vivo via CD23+ B cells

IgE Abs, passively administered together with their specific Ag, can enhance the production of Abs recognizing this Ag by >100-fold. IgE-mediated feedback enhancement requires the low affinity receptor for IgE, CD23. One possible mechanism is that B cells take up IgE-Ag via CD23 and efficiently present Ag to Th cells, resulting in better Ab responses. To test whether IgE Abs have an effect on Th cells in vivo, mice were adoptively transferred with CD4+ T cells expressing a transgenic OVA-specific TCR, before immunization with IgE anti-TNP (2,4,6-trinitrophenyl) plus OVA-TNP or with OVA-TNP alone. IgE induced a 6- to 21-fold increase in the number of OVA-specific T cells. These cells acquired an activated phenotype and were visible in splenic T cell zones. The T cell response peaked 3 days after immunization and preceded the OVA-specific Ab response by a few days. Transfer of CD23+ B cells to CD23-deficient mice rescued their ability to respond to IgE-Ag. Interestingly, in this situation also CD23-negative B cells produce enhanced levels of OVA-specific Abs. The data are compatible with the Ag presentation model and suggest that B cells can take up Ag via "unspecific" receptors and activate naive T cells in vivo.