Separable helper factors support B cell proliferation and maturation to Ig secretion

The 24-hr culture supernatant of Con A-activated spleen cells (SN) contains helper factors that enable maturation to high-rate polyclonal Ig secretion and enhance proliferation in cultures of mouse B cells activated with the F(ab')2 fragment of class-specific rabbit antimouse IgM antibody (anti-Ig). When interleukin 2 (IL 2), also called T cell growth factor, is removed from SN by absorption with an IL 2-dependent cell line at either 4 degrees C or 37 degrees C, all the helper activity for anti-Ig-activated B cells is also removed. Partial removal of IL 2 results in partial removal of helper activity for B cells. However, the IL 2-depleted SN appears to contain another helper factor, TRF, that enables anti-Ig-activated B cell cultures to mature to high-rate Ig secretion. This TRF activity is revealed by adding purified human IL 2 or an IL 2-containing supernatant of a cloned, lectin-activated T cell hybridoma line (FS6-14.13) to Il 2-depleted SN, which restores the polyclonal antibody response to anti-Ig. The hybridoma supernatant by itself supports proliferation of anti-Ig-activated B cell cultures, as measured by an increase in cell number, but not maturation to Ig secretion. This proliferative response is likewise IL 2 dependent, although purified IL 2 with anti-Ig is not sufficient. These experiments define separable combinations of factors acting on anti-Ig-activated B cell cultures, one of which (SN) results in both proliferation and maturation to high-rate Ig secretion, whereas the other (hybridoma supernatant) results in proliferation only. IL 2 appears to be an essential component of both combinations, although the target cell for IL 2 action in this system remains to be determined.     

Failure of B lymphocytes in human blood to regenerate surface immunoglobulin after its removal by antibody.

In culture, human blood B cells regenerated surface IgM and IgD after their removal by a brief treatment with pronase. In contrast, surface Ig was poorly reexpressed after interaction with specific antibody. Both classes of surface Ig were suppressed after treatment with antibody specific for only one. B lymphocytes from spleen and tonsils regenerated surface Ig after treatment with either pronase or anti-Ig. We suggest that the particular sensitivity of circulating B cells to anti-Ig-surface Ig interaction may be reflection of their state of maturation.     

IgM expressed by leukemic CD5(+) B cells binds mouse immunoglobulin light chain

Mouse immunoglobulin (Ig) molecules have previously been shown to bind to the surface of CD5(+) B cells from patients with B-cell chronic lymphocytic leukemia (B-CLL). The results indicated that surface IgM was involved in the interaction and suggested the phenomenon was an example of the polyreactive binding capacity of the surface Ig (sIg) expressed by these malignant cells. This article describes the further characterization of the interaction between human IgM and mouse Ig molecules and subunits. Mouse Ig molecules of both kappa and lambda light chain classes bound to the B-CLL cell surface. The dissociation constant for the interaction of mouse IgG1 (K121) with the B-CLL cell surface was 3.6 x 10(-7) M. To confirm the involvement of the human IgM expressed by the B-CLL cells in the interaction, the malignant cells were stimulated in vitro to induce secretion of human IgM. Enzyme immunoassay was used to show that secreted human IgM bound to intact mouse Ig, as occurred with the cell surface analysis. The mouse Ig epitope recognized by the purified secreted human IgM was shown by Western blot analysis to be located on the light chain of the mouse Ig molecule and to be conformationally dependent. K121 light chain was cloned and expressed in E. coli and the recombinant light chain bound to the surface of CLL B cells. The results confirm that human IgM is the reactive ligand in the interaction with mouse Ig and indicate that the interaction of polyreactive IgM with mouse IgG occurs via the light chain component of IgG.     

The role of immunoglobulin receptors and T cell mediators in B lymphocyte activation. I. B cell activation by anti-immunoglobulin and anti-idiotype reagents

The possibility that the failure of anti-mouse immunoglobulin (Ig) antibody to induce antibody synthesis by B cells might be due to reversible receptor blockade was investigated. Murine spleen cells were cultured for 3 days in the presence of minute quantities of intact of (Fab') fragments of rabbit anti-mouse Ig antibody. Thereafter, the cells were washed and either trypsin treated or not before reculturing for 18 hr. Only cells that had been trypsinized after culturing with either intact or fragments of anti-Ig gave a vigorous polyclonal antibody response. This response was extremely T dependent, since T cells or culture supernatants from Con A-activated T cells were required for the B cell response. Moreover, anti-delta was much more effective than anti-mu in inducing antibody synthesis. Finally, the use of three different anti-idiotypic antisera rather than anti-Ig reagents selectively activated the specific idiotype in each instance. The findings demonstrate that anti-Ig reagents can potentiate the response of B cells to signals delivered by T cells.     

Immunoglobulin M and immunoglobulin G secretion by human B cells exposed to RU 41.740, a glycoprotein extract from Klebsiella pneumoniae

RU 41.740, a glycoprotein extract from Klebsiella pneumoniae, was seen to activate human B cells to immunoglobulin secretion in vitro. The effects of RU 41.740 on human B cells were compared to those induced by pokeweed mitogen, a T-cell-dependent polyclonal B-cell activator, and Epstein-Barr virus, a T-cell-independent polyclonal B-cell activator. Exposure of human B cells to all of these agents resulted in increased immunoglobulin M (IgM) and immunoglobulin G (IgG) secretion. IgM and IgG secretion induced by RU 41.740 appeared to be T cell dependent when B cells were isolated from human peripheral blood. However, this activity may have been T cell independent when B cells were isolated from human spleen. RU 41.740-induced IgM secretion by peripheral blood B cells was seen to peak after 6 days in culture; IgG secretion peaked after 7 days in culture. The optimal concentration of RU 41.740 for the induction of IgM and IgG secretion by human B cells in vitro was seen to be 200 micrograms/ml.     

Regulation of mucosal B cell immunoglobulin secretion by intestinal epithelial cell-derived cytokines

Intestinal epithelial cells (IEC) secrete a variety of cytokines and, because of their close proximity to B cells in the lamina propria, may affect local antibody production via these cytokines. However, studies have not yet addressed which and to what extent these IEC-derived cytokines may affect B cell antibody production. In this study, rat mesenteric lymph node B cells were cultured with culture supernatants from the rat IEC-6 intestinal epithelial cell line to determine their effect on immunoglobulin (Ig) secretion. Unstimulated IEC-6 cells were found to secrete sufficient levels of IL-6 to enhance IgA, IgG and IgM secretion by unstimulated B cells. However, culture of lipopolysaccharide (LPS)-stimulated B cells with the unstimulated IEC-6 supernatant resulted in an enhancement of IgA secretion while IgM secretion was significantly suppressed. Depletion of the IEC-6 supernatant using cytokine specific antibodies revealed that both interleukin 6 (IL-6) and transforming growth factor beta (TGF-beta) were responsible for the enhanced IgA secretion while TGF-beta suppressed IgM secretion. More importantly, culture supernatants from LPS stimulated IEC-6 cells contained enhanced levels of IL-6 which enhanced both IgG and IgA production and partially overcame the suppressive effect of TGF-beta on IgM secretion. These results suggest that intestinal epithelial cells may secrete IL-6 and TGF-beta to regulate local B cell antibody secretion and their effect may be highly dependent upon the activation state of the epithelial cells.     

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.     

Expression of an unidentified immunoglobulin isotype on rabbit Ig-bearing lymphocytes.

A non-IgM immunoglobulin molecule was found on most rabbit Ig-bearing lymphocytes isolated from mesenteric lymph nodes. Membrane bound immunoglobulin light chains and heavy chains were detected by immunofluorescence and by rosetting with antibody-coated erythrocytes on mesenteric lymph node cells stripped of IgM by anti-IgM allotype antibodies. The percentage of cells bearing these residual immunoglobulin molecules was similar to the percentage of cells bearing immunoglobulin before "stripping" with anti-IgM antibody. These residual immunoglobulin molecules were not IgA nor IgG and are believed to be the rabbit analogue of human IgD.     

Lymphocyte function in human bone marrow. I. Characterization of two T cell populations regulating immunoglobulin secretion

We analyzed the regulation of immunoglobulin (Ig) production in short-term cultures of human (rib) bone marrow cells. In contrast to blood or tonsil cell cultures, large quantities of IgG and IgA, but not IgM, were secreted by unstimulated marrow cells. The addition of pokeweed mitogen or phytohemagglutinin resulted in the suppression of this Ig secretion. Both mitogens induced the production of high levels of interleukin 2 (IL 2) in marrow cultures, and the addition of IL 2 alone mimicked the suppressive effect of mitogens. Incubation of marrow cells with Epstein Barr virus resulted in enhanced Ig secretion, primarily of the IgM isotype. The addition of mitogen or IL 2 suppressed Ig production in these cultures as well. The mitogen-induced suppression of Ig secretion in stimulated or unstimulated marrow cultures was inhibited by the monoclonal anti-TAC (IL 2 receptor) antibody. Cell separation experiments indicated that the induction of suppressor activity in marrow cultures involved two distinct populations of marrow-resident T lineage cells. The first population responds to activation by mitogens with the production of IL 2. This population has a surface phenotype appropriate for helper T cells. The second T cell population expresses T8 and TAC determinants. These cells acquire suppressor cell activity after exposure to IL 2. The expression of suppressor function does not require additional (e.g., mitogenic) activation signals. The IL 2-dependent marrow suppressor T cells represent a newly recognized T lymphocyte subset. The regulatory pathway delineated may be important for the regulation of antibody formation in bone marrow, the major site of Ig production in man.     

Anti-immunoglobulin autoantibodies are not preferentially induced in polyclonal activation of human and mouse lymphocytes, and more anti-DNA and anti-erythrocyte autoantibodies are induced in polyclonal activation of mouse than human lymphocytes

Using a plaque assay with immunoglobulin (Ig)-coated SRBC, we and others have previously reported that the majority of polyclonally activated mouse lymphocytes secreted antibodies that appeared to be IgM anti-IgG autoantibodies. Careful reexamination of this assay, with application of several highly purified mouse serum and myeloma IgG and IgM preparations, revealed that IgM, which was a minor contaminant of Ig preparations, rather than IgG, was responsible for the formation of these plaques. High numbers of plaques could also be detected in assays with polyclonally activated human lymphocytes, Ig-coated SRBC, and anti-Ig developing sera. Of all IgG-, IgM- or IgA-secreting cells, 40 to 100% were detected with SRBC coated with gamma-globulin or Ig of the same isotype as the isotype to which the developing serum was specific; in general, low proportions of all PFC were detected with SRBC coated with Ig of a different isotype. Studies on the sequence of events leading to the formation of plaques with Ig-sensitized SRBC (both in humans and mice) revealed that antibodies detected in these assays were not able to bind to the Ig-coated SRBC (without the presence of developing serum), and therefore were not anti-Ig autoantibodies. It is our conclusion that the plaque assays with Ig-coated SRBC represent another type of a reverse hemolytic PFC assay that detects cells secreting antibodies regardless of their specificity, and these plaques are formed due to the cross-linking by the anti-Ig developing serum of the Ig coated on SRBC and the Ig secreted by lymphocytes. Our results confirmed preferential induction of anti-DNA antibody secreting cells in mice by showing that these antibodies indeed bind to DNA coated on SRBC. In cultures of polyclonally activated human lymphocytes, anti-DNA and anti-erythrocyte autoantibody-secreting cells were over 10 to 100 times less frequent than in mice. These results, therefore, disprove the concept of preferential induction of anti-Ig autoantibodies in the polyclonal activation of mouse and human lymphocytes, and show that anti-DNA and anti-erythrocyte autoantibodies are easily induced in the polyclonal activation of mouse, but not human, lymphocytes.     

Induction of immunoglobulin-secreting cells in the allogeneic mixed leukocyte reaction: regulation by helper and suppressor lymphocyte subsets in man

The existence of functionally distinct T lymphocyte subsets in man, initially demonstrated with heteroantisera, has been confirmed with monoclonal reagents. Two major subsets have been defined: Leu-2 cells, which effect cell mediated lymphocytotoxicity (CML), and Leu-3 cells, which amplify CML and other T cell functions. This study is an effort to determine the effects of these subsets on the immunoglobulin secretion induced in the human mixed leukocyte reaction (MLR). T cells were separated from non-T cells by rosetting with sheep erythrocytes and were fractionated into Leu-2 and Leu-3 subsets by solid phase immunoabsorption with monoclonal antibodies. T cell subsets were cultured with autologous non-T cells and irradiated allogeneic stimulator non-T cells. Secretion of IgM and IgG was measured by a reverse hemolytic plaque assay. MLR-induced antibody secretion was specifically dependent on the Leu-3 T lymphocyte subset. The Leu-2 subset was incapable of generating large numbers of IgM- or IgG-secreting cells, and, in fact, suppressed the Leu-3-induced response. Exposure of Leu-3 cells to a dose of irradiation sufficient to prevent their proliferation in MLR did not reduce induced immunoglobulin secretion. Leu-2-mediated suppression, however, was sensitive to low dose irradiation. Thus Ig secretion in human MLR is regulated by a balance of helper activity from the Leu-3 subset and suppressor activity from the Leu-2 subset.     

Regulation of antibody release by naturally occurring anti-immunoglobulins in cultures of pokeweed mitogen-stimulated human peripheral blood lymphocytes

Immunoregulatory influences of human anti-immunoglobulins (anti-Ig) were studied in cultures of peripheral blood lymphocytes (PBL) from 11 normal donors. Pokeweed mitogen (PWM)-stimulated PBL released anti-Ig specific for Fab or Fc fragments of IgG, often within the first 24 to 72 hr in vitro. PBL that released more than 1 ng/ml IgM anti-Fab during the first 72 hr in vitro ultimately produced significantly less antibody (Ab) by the 12th day than PBL that released no detectable IgM anti-Fab during the first 3 days in culture. Adding affinity-purified human anti-Fab to PWM-stimulated PBL also suppressed the later Ab release by these cells. Suppression was polyclonal, affecting IgM anti-Fc, IgM anti-Fab, and IgM anti-tetanus toxoid Ab, and was directly dependent on the quantity of anti-Fab added. Anti-Fab Ab, isolated from single donor sera, were more suppressive, nanogram for nanogram, than were equal quantities of IgG anti-Fab obtained from Cohn Fraction II, when added to autologous donor PBL in vitro. Affinity-purified IgM anti-Fc, from pooled rheumatoid arthritis patient sera, also suppressed Ab release by PWM-stimulated PBL in a dose-dependent manner. These observations suggest that anti-Ig may exert a significant immunoregulatory role in man that can override to some extent the T cell-dependent stimulus for polyclonal B cell activation provided by PWM.     

The inhibition of T cell proliferative responses by crosslinking CD7 and IgM-Fc receptors.

Previous work from our laboratory described a human T cell soluble ligand that inhibited T cell proliferative responses to mitogen and alloantigen by interacting with CD7 and/or the receptor for the IgM-Fc portion (FcR mu) on T cells. In this report, we used mouse anti-human CD7 monoclonal antibodies (mAb) and purified human IgM (HIgM) to substitute for the human ligand and examined the possible involvement of these receptors in the inhibition of T cell proliferation. Preincubation of human T cells with mouse anti-CD7 mAb, HIgM, mouse anti-human IgM (MAH IgM) alone, or any of these combinations as a primary antibody did not inhibit mitogen- or alloantigen-induced T cell replication. Similar effects were seen with the pretreatment of T cells with an irrelevant negative control primary mAb or a secondary-step goat anti-mouse immunoglobulin (GAM Ig), goat anti-human IgM-Fc (GAH Fc mu), or both. In contrast, the pretreatment of T cells with anti-CD7 and/or HIgM followed by the appropriate secondary-step crosslinking antibody significantly reduced their proliferative responses to mitogen and alloantigen. Similarly, crosslinking of CD7 and FcR mu on human transformed T cell lines inhibited their spontaneous proliferation. The inhibitory effect of crosslinking CD7 and FcR mu was not due to cytotoxic effects of these antibodies and appears to be temperature sensitive. These findings suggest that crosslinking CD7 and/or FcR mu appears to have a novel role in down-regulating T cell proliferation.     

F(ab')2 reagents are not required if goat, rather than rabbit, antibodies are used to detect human surface immunoglobulin.

The present report provides evidence that whole goat anti-human immunoglobulin, unlike similar reagents produced in the rabbit, binds both to the same number of and the same individual cells as the F(ab')2 fragments of rabbit or goat anti-human immunoglobulin. These results suggest that goat IgG has a lower affinity for the Fc receptors of human lymphocytes and monocytes than rabbit IgG. Because of this property, whole goat antibodies against human immunoglobulin can be used as simple, convenient relatively inexpensive reagents for the routine detection of immunoglobulin on cell surfaces by immunofluorescence microscopy. The preparation of F(ab')2 fragments of anti-immunoglobulin, which are necessary when rabbit antibodies are used, does not appear to -e required if goat antibodies can be empolyed. This observation has multiple practival applications in cellular immunology.     

Cell membrane IgD: demonstration of IgD on human lymphocytes by enzyme-catalyzed iodination and comparison with cell surface Ig of mouse, guinea pig, and rabbit.

A substantial fraction of human cord blood and peripheral blood lymphocytes have recently been shown to bear IgD. Although IgD has not been identified in mice, it has been suggested that it is also a major surface immunoglobulin of murine lymphocytes. Thus, lactoperoxidase-catalyzed iodination of surface immunoglobulin of mouse spleen and lymph node cells reveals the existence of an IgH chain differing from mu, gamma, and alpha-chain both antigenically and by mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. This new H chain class has been previously proposed to be the mouse homologue of delta-chain. In this paper, we analyzed human, mouse, guinea pig, and rabbit lymphoid cell membrane Ig by lactoperoxidase-catalyzed iodination, extraction with non-ionic detergent precipitation with a variety of specific anti-Ig sera, and electrophoresis of dissolved reduced precipitates on sodium dodecyl sulfate-polyacrylamide gels. Our studies confirm the previous reports of a new mouse cell membrane H chain with a mobility more rapid than that of mu-chain. However, we fail to detect a molecule with this electrophoretic mobility on the surface of guinea pig or rabbit lymph node and spleen cells. Moreover, neither anti-kappa nor anti-delta antibody precipitates a molecule with an H chain of this mobility from labeled extracts of human cord blood or peripheral blood lymphocytes. Cell surface delta was identified on both human cord blood and peripheral blood lymphocytes, but it proved to have mobility similar to human and mouse mu-chain. This result indicates either that mouse delta-chain has an electrophoretic mobility on sodium dodecyl sulfate-polyacrylamide gels which differs appreciably from that of human membrane delta-chain or that the newly described mouse H chain is not the homologue of human delta-chain.     

Modulation of ongoing human immunoglobulin synthesis by natural killer cells

Freshly separated human NK cells (NKH-1+) inhibited IgE synthesis from IgE myeloma U266/AF-10 as much as 70% whereas they enhanced IgG and IgA synthesis 200 and 500% from the lymphoblastoid cell lines GM-1500 and GM-1056, respectively. The inhibition of IgE synthesis by NK cells was due to a direct cytolytic effect on AF-10. This could be reversed using K562 cells in a cold target competition assay. NK cells also inhibited spontaneous IgE as well as IgG and IgA synthesis from B cells of highly atopic donors. On the other hand the enhancement of Ig secretion by NKH-1+ cells was shown to be mediated by soluble factors released from NK cells. Furthermore when NK cells were preincubated with immune complexes (IgE-IC) constructed of human IgE and mouse IgG1 monoclonal anti-human IgE, inhibition of IgE synthesis was reversed, and in some cases actual enhancement of IgE synthesis was observed, while enhancement of IgG and IgA synthesis was not affected. In contrast to NK cells, T cells depleted of NK cells (T-NK), when activated by IgE-IC, suppressed IgE synthesis in an isotype specific fashion. Thus, NK and T-cell modulation of ongoing Ig synthesis involve distinct mechanisms.     

In vitro studies of the rabbit immune system. IV. Differential mitogen responses of isolated T and B cells.

The mitogenic responses of separated rabbit lymphocyte populations functionally analogous to mouse T and B cells have been tested in vitro. Purified T cells were prepared by passage over nylon wool (NW) and purified B cells prepared by treatment with antithymocyte serum and complement (ATS + C). ATS + C kills 70% of peripheral blood lymphocytes (PBL's) and 50% of the spleen cells while passage over NW yields 40% of the applied PBL's and 5–23% of the applied spleen cells. NW-purified T cells from the spleen or PBL's respond fully to concanavalin A (Con A) but have a reduced response to phytohemaglutinin (PHA) and little or no response to goat anti-rabbit immunoglobulin (anti-Ig). PBL's that survive ATS + C (B cells) are stimulated by anti-Ig but not by Con A or PHA. B cells purified from spleen do not respond to Con A or PHA but will respond to anti-Ig under appropriate conditions. A full spleen B-cell response to anti-Ig required removal of Ig produced by the cultures that blocked anti-Ig stimulation. It is concluded that, for rabbit lymphocytes, Con A and PHA are primarily T-cell mitogens and that anti-Ig is primarily a B-cell mitogen. However, the mitogen response of unfractionated PBL or spleen cell populations indicates an overlap in reactivity. This could be due to cells sharing T and B properties, alteration of cell populations by the fractionation procedures used, or recruitment of one population in the presence of a mitogenic response of the other population.     

Separation of various B-cell subpopulations from mouse spleen. I. Depletion of B cells by rosetting with glutaraldehyde-fixed, anti-immunoglobulin-coupled red blood cells.

Mouse spleen cells were depleted of immunoglobulin (Ig)-bearing B cells by rosetting with glutaraldehyde-fixed, tannic acid-treated RBC coupled with antibody to mouse Ig (anti-Ig) and removing the rosetted cells by density gradient centrifugation. The method was routinely greater than 90% effective in removing B cells as assayed by the failure of anti-Ig rosette-depleted primed spleen cells to generate antibody-producing cells in vitro in response to specific antigen or of anti-Ig rosette-depleted nonprimed spleen cells to generate a polyclonal antibody response. T cells were not removed by the rosetting procedure as measured by helper T-cell activity. The greater effectiveness of the rosetting procedure in removing potential IgG-secreting, non-IgM-bearing B cells is shown relative to other commonly used B-cell depletion procedures. Because the RBC in the rosetting reagent are fixed with glutaraldehyde, the rosetting reagent is stable for many months. Such stability makes constantly available a convenient means for B-cell removal, as well as reducing consumption of antisera.     

Helper cell function of human fetal thymocytes

The role of human fetal thymocytes in the regulation of IgG and IgM production was examined. In pokeweed mitogen (PWM)-driven cocultures between thymocytes and normal adult peripheral blood mononuclear cells (PBMs) significantly enhanced secretion of both IgM (350% expected; P < 0.02) and IgG (450% expected; P < 0.001) was observed. In contrast, adult PBMs or adult T cells neither suppressed nor enhanced IgM or IgG production in coculture with allogeneic adult PBMs. Enhanced immunoglobulin secretion was not found when fetal thymocytes were cocultured with the T-cell-depleted fraction of adult PBMs. These results suggest that human fetal thymocytes (as early as 12 weeks gestational age) can provide helper cell function for both IgM and IgG secretion in PWM-driven cell cultures; however, a more mature T-cell effector is required for expression of this helper function.