Polyclonal activation of primed rat B cells

In recent years, murine and human virgin B lymphocytes have been used to examine the steps necessary for polyclonal activation. In these models mitogens are used in conjunction with lymphokines to determine which signals are responsible for regulating B-cell triggering, proliferation, and differentiation. While progress has been made in understanding these events as they occur in virgin B cells, very little evidence exists to suggest whether these models of activation also apply to the memory B-cell population. In this report we have described an antigen-specific, secondary in vitro immune response using cells isolated from lymph nodes draining the site of antigen injection. Unfractionated cells, B cells, and size-fractionated cells from dinitrophenyl-keyhole limpet hemocyanin (DNP-KLH)-primed rats were challenged in vitro with DNP-KLH, lipopolysaccharide plus dextran sulfate (LPS/DxS), and T-cell factors. We have consistently found, under all these conditions, that antigen challenge of primed cells results in the production of DNP-specific IgG antibody while stimulation with LPS/DxS plus T-cell factors results only in the polyclonal activation of virgin B cells; no antigen-specific IgG secretion is seen. This suggests that acquisition of memory status is associated with a loss in responsiveness to LPS/DxS-induced differentiation.     

Polyclonal activation of rat B cells. II. Dextran sulfate as a cofactor in mitogen-induced and antigen-induced differentiation of rat B lymphocytes

Salmonella typhimurium mitogen (STM) is a polyclonal activator of rat B lymphocytes, triggering them to proliferate, but not differentiate, to antibody-secreting cells. When lymphokines in the form of a supernatant from Con A-stimulated splenocytes (CAS) are added to B cell cultures activated by STM, only a small number of cells are driven to differentiate. Only with the addition of a third signal provided by the polyanionic polysaccharide dextran sulfate (DXS) is significant rat B cell differentiation observed. In this study, we have shown that this requirement for DXS is not unique to the STM mitogen. LPS, Staphylococcus aureus Cowan I-fixed cells, and anti-Ig antibody all induced rat B cell proliferation with little differentiation, even in the presence of CAS. DXS was necessary to induce differentiation in all cultures costimulated with mitogen and CAS. The requirement for DXS for optimal B cell differentiation is also observed with other lymphokine preparations such as the supernatants from PMA-stimulated EL-4 cells and PHA-stimulated human T cells. Furthermore, this augmentative effect of DXS in rat B cell differentiation was not confined to polyclonal activation systems. Ag-specific IgG secretion was also increased when DXS was added to Ag and CAS costimulated cultures of B cells harvested from the draining lymph nodes of rats immunized with DNP-keyhole limpet hemocyanin. Within the polyclonal activation system, a method of staged additions of STM, DXS, and CAS to B cell cultures was used to investigate the role of DXS during B cell differentiation. Optimal differentiation occurred only when DXS was present in the B cell cultures in conjunction with CAS. The augmentation in differentiation seen with DXS did not appear to be due to the recruitment of an additional CAS-responsive B cell subset, because cycling, low density B cell blasts showed large increases in IgM secretion with subsequent exposure to DXS and CAS. These studies suggest tha DXS acts as a cofactor to various differentiation factors, augmenting polyclonal and Ag-specific rat B cell differentiation. The relevance of DXS to in vivo immune responses is discussed.     

Identification of two distinct factors, B151-TRF1 and B151-TRF2, inducing differentiation of activated B cells and small resting B cells into antibody-producing cells

We demonstrated previously that cellfree supernatant of the B151K12 T cell hybridoma (B151-CFS) contained T cell-replacing factor (here in after referred to as B151-TRF1) capable of inducing growth and differentiation of antigen-activated B cells into antigen-specific plaque-forming cells (PFC). In the present study, we have identified in B151-CFS another unique lymphokine activity (referred to as B151-TRF2), which induces polyclonal differentiation of unstimulated B cells into IgM-secreting cells without concomitant stimulation of antigen, mitogen, or anti-Ig antibody. The B151-TRF2 activity induced polyclonal IgM PFC responses via the action on surface Ig-positive small resting B cells from normal unprimed mice. This activation was effective across an H-2 barrier, and apparently independent of the presence of T cells and accessory cells. Interestingly, the B151-TRF2 activity notably stimulated B cells of neonatal and mutant DBA/2Ha mice, which are nonresponders to B151-TRF1, whereas it failed to activate the xid B cells from CBA/N mice. To substantiate that B151-TRF1 and B151-TRF2 activities are mediated by mutually distinguishable molecules, an absorption experiment of B151-CFS was performed by utilizing DBA/2Ha B cells which are lacking in B151-TRF1 receptor. It was found that DBA/2Ha B cells could absorb B151-TRF2 activity but not B151-TRF1 activity. In contrast, murine chronic B cell leukemia BCL1 cells, which were shown to differentiate into IgM-secreting cells by stimulation with B151-CFS, selectively removed B151-TRF1 activity but not B151-TRF2 activity. Furthermore, biochemical analysis revealed that the B151-TRF2 was a heat (56 degrees C for 30 min)-sensitive protein with an apparent m.w. of 30,000 by gel filtration, whereas B151-TRF1 was a heat-resistant glycoprotein with m.w. of 50,000. In addition, it was shown that prostaglandin E2 selectively inhibited B151-TRF2-mediated B cell responses. These results demonstrate clearly that B151-TRF1 and B151-TRF2 are distinct B cell differentiation factors involved in the different activation pathways of distinct B cell subpopulations. The immunologic implication of B151-TRF2 activity in B cell differentiation is discussed in comparison with other lymphokines so far reported to activate small resting B cells.     

Antigen-initiated B lymphocyte differentiation. IX. Characterization of memory AFC progenitors by buoyant density and sedimentation velocity separation.

The characteristics of memory B cell antibody-forming cell (AFC) progenitors from long-term hapten-primed CBA mice were investigated by using sedimentation velocity and buoyant density separation to isolate physically distinct B cell sub-sets. The isolated fractions were assayed by the adoptive immune response to NIP-POL antigen, under conditions where neither T cells nor other accessory cells were limiting the IgM or IgG AFC responses. The results were compared to previous studies on the IgM AFC-progenitors of unprimed adult mice. Splenic IgM and IgG memory AFC-progenitor activity was largely found among the typical B cells of slow to medium sedimentation rate, in contrast to the fastre sedimenting IgM AFC-progenitor activity of unprimed animals. Splenic IgM and IgG memory AFC-progenitor activity was found among the medium to light density cells, and so resembled by this parameter the IgM AFC-progenitor activity in unprimed animals. Thoracic duct lymphocytes from hapten-primed mice also exhibited memory IgM and IgG AFC-progenitor activity in the slow-medium sedimentation range. However, in contrast to spleen, the IgM and IgG memory AFC-progenitor activity in lymph was found among very dense B cells. Two physically distinct sub-populations of memory B cells have thus been identified, namely: i) small, medium-light density, presumably tissue-resident B lymphocytes found in spleen; and ii) small, dense, presumably recirculating B lymphocytes found in lymph. Both physical forms include IgM and IgG progenitors. Both forms are distinct from the larger, medium-light density "virgin" AFC-progenitors in the spleen of unprimed adult mice.     

Antigen-initiated B lymphocyte differentiation. V. Electrophoretic separation of different subpopulations of AFC progenitors for unprimed IgM and memory IgG responses to the NIP determinant.

Spleen cells from CBA mice were separated by continuous, free-buffer film cell electrophoresis, and the capacity of cells in different fractions to mount an adoptive immune response specific for the NIP hapten determined. Experimental conditions were such that AFC progenitor B cells were measured, rather than helper or suppressor T cells. The IgM response of unprimed animals (a virgin or antigen inexperienced population) and the IgG response of long-term hapten-primed animals (a B memory cell population) were compared. The results indicated physical and biological heterogeneity in splenic B cells, with AFC progenitors for unprimed IgM and memory IgG responses being extensively separated.AFC progenitors for a primary IgM response in normal, germ-free and athymic mouse spleen, and bone marrow, separated into three distinct populations. Two of these were of much higher mobility than the typical splenic B cells and separated in the T cell zone. These cells produced a relatively early peak response of AFC after stimulation.AFC progenitors for a secondary IgG response were predominantly typical low-mobility B cells. Three regions of activity were separated, one overlapping part of the IgM progenitors. The slowest migrating activity peaks corresponded to the mobility of some recirculating B cells. These cells produced a more delayed AFC response after stimulation.AFC from the spleens of immunised mice separated as a single, broad, mediummobility peak distinct from most B cells and AFC progenitors. IgM and IgG (memory) AFC had similar electrophoretic characteristics.     

The direct effects of interleukin 1, interleukin 2, interferon-alpha, interferon-gamma, B-cell growth factor, and a B-cell differentiation factor on resting and activated human B cells

A wide variety of cytokines have been demonstrated to affect B-cell function. However, it is unclear which of these mediators actually exert direct effects on the B cells themselves. In the present study, the direct role of interleukin (IL) 1, IL-2, Interferon-gamma, or Interferon-alpha in human B-cell activation, proliferation, or differentiation was examined and compared with the effects of a B-cell growth factor (BCGF) or a B-cell differentiation factor (BCDF). Highly purified human B lymphocytes were separated according to size into two nonoverlapping populations. The fraction of small B cells was incubated with IL-1, IL-2, Interferon-gamma, Interferon-alpha, BCGF, or BCDF, and cell size changes, RNA synthesis, DNA synthesis, or supernatant immunoglobulin (Ig) production were measured. Neither IL-1, IL-2, Interferon-alpha, Interferon-gamma, nor the BCGF induced substantial cell size changes, RNA synthesis, DNA synthesis, or Ig production by the small fraction of B lymphocytes; however, the BCDF could directly activate a proportion of resting B lymphocytes to secrete Ig. The fraction of large B cells was also incubated with these cytokines. While neither IL-1, Interferon-alpha, nor Interferon-gamma enhanced DNA synthesis or Ig production by the fraction of large B lymphocytes, DNA synthesis was augmented 23-fold by BCGF and IgG production was increased 7-fold by BCDF. Additionally, IL-2 slightly enhanced both proliferation and differentiation of large B cells but substantially less so than BCGF and BCDF; DNA synthesis was increased 4-fold, while Ig production in the presence of IL-2 was increased by approximately 50%. Thus, the most important lymphokines modulating the function of these two fractions of tonsillar lymphocytes were a BCGF and a BCDF.     

Umbilical cord mesenchymal stem cells suppress B-cell proliferation and differentiation

Mesenchymal stem cells (MSCs) may be obtained from umbilical cord as an abundant and noninvasive source. However, the immunomodulatory properties of umbilical cord-MSCs (UC-MSCs) were poorly studied. In this study, we aimed to investigate the effects of UC-MSCs on B-cell proliferation and differentiation. UC-MSCs were found to suppress the proliferation of B cells isolated from murine spleen. Moreover, UC-MSCs markedly suppressed B-cell differentiation as shown by the decreased number of CD138+cells and reduced levels of IgM and IgG production in coculture. As revealed by transwell experiments, soluble factors produced by UC-MSCs might be involved in mediating B-cell suppression. The Blimp-1 mRNA expression was suppressed whereas the PAX-5 mRNA expression was induced in coculture. Finally, UC-MSCs modified the phosphorylation pattern of Akt and p38 pathways, which were involved in B-cell proliferation and differentiation. These results may further support the potential therapeutic use of UC-MSCs in treating autoimmune disorders.     

Polyclonal immunoglobulin response of thymic,hepatic and splenic lymphocytes from fetal,germ-free and conventionally reared pigs to different B-cell activators

Immunoglobulin (Ig) response to different polyclonal B-cell activators was measured by ELISA in cell culture media of thymocytes, splenocytes and liver cells isolated from pig fetuses, 8-d-old germ-free piglets and conventionally reared pigs. Both in fetal and in postnatal life polyclonally stimulated lymphocytes were found to produce predominantly the IgM isotype; the first IgM formation was detected in 50-d-old fetal liver (gestation in pigs lasts 114 d). Surprisingly, 73-d-old fetal thymic cells were shown to be induced to Ig synthesis and secretion. In contrast to splenocytes of the same age, which secreted exclusively IgM, fetal thymocytes produced IgM, IgG and IgA. Polyclonally stimulated splenic cells as compared with thymic cells started to produce IgA later in fetal ontogeny, whereas the IgG response was not detectable in splenic cell culture media during the whole embryonal development and appeared only after birth. The earliest and the highest Ig stimulation was found after cultivation of lymphocytes withNocardia delipidated cell mitogen. Interestingly, the moderate stimulatory effect of 65-kDa heat shock protein (Hsp-65) in polyclonal IgM response of fetal splenocytes was observed. We showed that thymic B lymphocytes represent probably the first maturing B cell population detectable in fetal life, which is able to differentiate after polyclonal stimulation into IgM as well as IgA and IgG producing cells. Dedicated to Professor J. Šterzl on the occasion of his 70th birthday     

Effects of GSM-modulated radiofrequency electromagnetic fields on B-cell peripheral differentiation and antibody production

We examined the effects of in vivo exposure to a GSM-modulated 900 MHz RF field on B-cell peripheral differentiation and antibody production in mice. Our results show that exposure to a whole-body average specific absorption rate (SAR) of 2 W/kg, 2 h/day for 4 consecutive weeks does not affect the frequencies of differentiating transitional 1 (T1) and T2 B cells or those of mature follicular B and marginal zone B cells in the spleen. IgM and IgG serum levels are also not significantly different among exposed, sham-exposed and control mice. B cells from these mice, challenged in vitro with LPS, produce comparable amounts of IgM and IgG. Moreover, exposure of immunized mice to RF fields does not change the antigen-specific antibody serum level. Interestingly, not only the production of antigen-specific IgM but also that of IgG (which requires T-B-cell interaction) is not affected by RF-field exposure. This indicates that the exposure does not alter an ongoing in vivo antigen-specific immune response. In conclusion, our results do not indicate any effects of GSM-modulated RF radiation on the B-cell peripheral compartment and antibody production and thus provide no support for health-threatening effects.     

The class of surface immunoglobulin on virgin and memory B lymphocytes.

The class of surface immunoglobulin receptors for antigen on B cell precursors of different classes of antibody-forming cells was determined by utilizing a technique of class-specific antigen suicide. Spleen cells are first treated with a class-specific antiserum under conditions that result in the stripping of that class from the cell surface. The cells are then permitted to bind a highly radioactive trinitrophenyl (TNP)-conjugated protein, which leads to lethal irradiation of all TNP-specific B cells except those whose TNP receptors had been removed by the class-specific stripping of surface immunoglobulin. In this way, the class of antibody-forming cells resulting from TNP stimulation of B cells with different classes of surface immunoglobulin can be examined. It was found that the virgin B cell precursors of IgM-producing cells are two types: cells bearing IgM receptors only and those bearing both IgM and IgD receptors. All virgin B cells that gave rise to IgG1 antibody-forming cells had both IgM and IgD on their surfaces, demonstrating that an antigen-dependent switch from IgM and IgD to IgG1 production is a common feature of B cell maturation. In contrast, memory B cell precursors of IgG1 antibody-forming cells had predominantly IgG1 as their surface antigen receptor. The implications of these findings on current models of B cell maturation are analyzed.     

Lymphokine-like activity of 8-mercaptoguanosine: induction of T and B cell differentiation

Lymphocyte proliferation and differentiation result from ordered cellular interactions governed by soluble products (lymphokines). Dissecting the individual steps in these processes has been difficult, due to a paucity of pure lymphokines. Recently, it was reported that the derivatized ribonucleoside 8-mercaptoguanosine (8MGuo) has both mitogenic and differentiative effects on murine B cells. In the present studies, we tested 8MGuo for its ability to stimulate both B and T cell responses. In contrast to the murine studies, 8MGuo does not stimulate rat B cells to proliferate and, when tested for B cell growth factor-like activity, no stimulation was observed. The addition of 8MGuo (0.5 to 1 mM final concentration) to mitogen-stimulated B cells led to a marked increase in IgM and a modest increase in IgG secretion. When mixed with conditioned medium, 8MGuo acted synergistically in stimulating secretion of both isotypes, arguing that 8MGuo has both B cell-differentiating factor-mu (BCDF-mu) and BCDF-gamma activity. 8MGuo had no IL 2-like activity when tested on a mouse IL 2-dependent cell line, and no IL 1-like activity on addition to mouse thymocytes with or without submitogenic doses of lectin. However, when added to cultures of murine allogeneic cells in which the stimulating cell populations had been heat-inactivated, 8MGuo induced the generation of specific allogeneic cytotoxic T lymphocytes. Together, these results suggest that a simple derivatized nucleoside can induce both T and B cell differentiation without concomitant proliferation, and thus represent a unique probe for studying events in lymphocyte differentiation.     

The role of human interleukin-6 in B-cell isotype regulation and differentiation

Human Interleukin-6 (IL-6) is a cytokine secreted by T cells, as well as a variety of other cell types, which exhibits B-cell differentiating activity. The recent cloning of the gene that codes for this molecule has allowed us the opportunity to study the function of this molecule alone and in conjunction with other lymphokines in human B-cell isotype-regulation and differentiation. Recombinant human IL-6 enhances immunoglobulin (Ig) M and G secretion by B-cells activated by Staphylococcal A Cowan strain (SAC) and enhances IgM, IgG, and IgA secretion by B-cells activated by pokeweed mitogen. IL-6 also augments immunoglobulin secretion of differing isotypes from various Epstein-Barr Virus transformed B-cell lines. However, IL-6 does not alter the secreted isotype of naive surface IgM-positive B-cells. As human T-cells secrete other lymphokines in association with IL-6 after activation we examined the interaction of Interleukin-2 (IL-2) gamma-interferon (IFN-gamma) and Interleukin-4 (IL-4) with IL-6 on B-cell immunoglobulin secretion. IL-2 and IL-4 synergized with IL-6 in augmenting immunoglobulin secretion by SAC-activated B-cells. IFN-gamma significantly inhibited the Ig secretion of SAC-activated B-cells cocultured with IL-6 alone or in combination with IL-2. These results demonstrate that human recombinant IL-6 augments immunoglobulin secretion of isotype-committed B-cells but it does not induce a change in the isotype secreted. In addition, this lymphokine synergizes with IL-2 and IL-4 in supporting Ig secretion. However, IFN-gamma significantly inhibits IL-6 induced Ig secretion.     

Grb2 regulates B-cell maturation, B-cell memory responses and inhibits B-cell Ca2+ signalling

Grb2 is a ubiquitously expressed adaptor protein, which activates Ras and MAP kinases in growth factor receptor signalling, while in B-cell receptor (BCR) signalling this role is controversial. In B cell lines it was shown that Grb2 can inhibit BCR-induced Ca(2+) signalling. Nonetheless, the physiological role of Grb2 in primary B cells is still unknown. We generated a B-cell-specific Grb2-deficient mouse line, which had a severe reduction of mature follicular B cells in the periphery due to a differentiation block and decreased B-cell survival. Moreover, we found several changes in important signalling pathways: enhanced BCR-induced Ca(2+) signalling, alterations in mitogen-activated protein kinase activation patterns and strongly impaired Akt activation, the latter pointing towards a defect in PI3K signalling. Interestingly, B-cell-specific Grb2-deficient mice showed impaired IgG and B-cell memory responses, and impaired germinal centre formation. Thus, Grb2-dependent signalling pathways are crucial for lymphocyte differentiation processes, as well as for control of secondary humoral immune responses.     

Differential effect of interferon-gamma and interleukin-2 on the induction of IgA and IgM anti-dextran responses

Supernatants from T-cell lines and T-cell hybridomas can substitute for T cells in the induction of the anti-alpha(1,3) Dextran B1355 plaque-forming cell response in culture. The present study sought to define the lymphokines required for the induction of IgA and IgM anti-alpha (1,3) dextran responses. Recombinant Interferon-gamma (IFN-gamma) supported the induction of low levels of IgA anti-alpha(1,3) dextran plaque-forming cells in splenic B-cell cultures. IgA responses were substantially increased when cultures containing IFN-gamma were supplemented with an interleukin 2 (IL-2)-containing supernatant from the murine T-cell hybridoma BW.Mls, purified murine IL-2, or recombinant human IL-2. In striking contrast, IgM anti-alpha(1,3) dextran plaque-forming cells were not produced in cultures containing IFN-gamma alone or in combination with purified or recombinant IL-2. However, substantial IgM responses could be produced in cultures containing IFN-gamma and BW.Mls supernatant. This data indicates that there may be different lymphokine requirements for the induction of IgA and IgM anti-alpha(1,3) dextran B cells, or alternatively, such B cells may be in different stages of differentiation and therefore, not respond to the same lymphokines.     

Preparation and analysis of antigen-specific memory B cells

A procedure has been developed for the enrichment of TNP-binding memory B cells (TNP-MABC) from spleens of immunized mice. More than 75% of the cells expressed surface IgM (sIgM) and IgD (sIgD) and about 9% expressed surface IgG (sIgG). The TNP-MABC consisted of small resting lymphocytes with high affinity antigen-binding receptors. These cells expressed increased densities of Ia antigens and decreased densities of sIgD. Adoptive transfer of the cells into irradiated, carrier-primed syngeneic recipients resulted in their differentiation into IgG anti-TNP antibody-secreting cells. TNP-MABC secreted high affinity IgG anti-TNP antibodies when cultured in vitro with carrier-primed T cells and antigen. Limiting dilution analysis revealed that TNP-MABC contained a relatively low frequency of precursors for IgG-secreting cells that had an exceptionally large clone size. These results show that a highly enriched population of antigen-specific memory B cells can now be prepared and used to analyze their activation requirements.     

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 B-lymphocyte activation, proliferation, and immunoglobulin secretion

Lymphocyte growth and differentiation are controlled by signals resulting from the interaction of antigen and cellular products, such as lymphokines, with specific cell membrane receptors. Resting B lymphocytes can be activated by low concentrations (1-5 micrograms/ml) of antibodies to membrane IgM, which is the B-lymphocyte receptor for antigen. The binding of anti-IgM to B cells causes a rapid increase in intracellular free calcium concentration ([Ca2+]i), in inositol phosphate concentration, and in protein kinase activity. Moreover, the effects of anti-IgM on B cells are mimicked by the combined use of calcium ionophores and phorbol esters. Since phorbol esters activate protein kinase c, this suggests that the increase in [Ca2+]i and in phosphatidylinositol metabolism stimulated by anti-IgM are critical events in B-cell activation. The entry into S phase of B cells stimulated with anti-IgM depends on the action of a T-cell-derived factor designated B-cell stimulatory factor (BSF)-1. This is a 20,000-Da protein which is a powerful inducer of class II major histocompatibility complex molecules. Although an important cofactor for B-cell proliferative responses to anti-IgM, its major locus of action is on resting B cells. B cells stimulated with anti-IgM and BSF-1 do not synthesize secretory IgM. However, if two additional T-cell-derived factors, B151-TRF and interleukin-2, are added to cultures, a substantial proportion of stimulated B cells produce secretory IgM. BSF-1 has also been shown to participate in the "switch" in Ig class expression. Resting B cells cultured with lipopolysaccharide will switch to IgG1 secretion in the presence of purified BSF-1.     

Regulation of T15 idiotype dominance. III. Phosphocholine-specific B-cell activation in vivo requires major histocompatibility complex-restricted T-cell help

We have examined the requirement for major histocompatibility complex (MHC)-restricted T-cell help in the secondary in vivo antibody response to phosphocholine (PC). The memory response to PC has been demonstrated previously to be comprised of T15-dominant IgM and IgG3 plaque-forming cells (PFC) derived primarily from the Lyb-5+ B-cell subset, and IgG1 and IgG2 PFC, few of which bear the T15 idiotype and are predominantly derived from the Lyb-5- B-cell subset. Using carrier-primed (A X B)F1 T cells which have matured in a parentA chimeric environment so that "self" recognition is of the MHC determinants of parentA but not parentB, we have found that parentA PC-primed B cells, but not parentB PC-primed B cells, are activated. Even in the presence of an ongoing parentA anti-PC response, parentB PC-primed B cells were not activated, indicating that the restriction was between the helper T cell and the B cell, not between T-helper and accessory cells. MHC-restricted T-cell help was required by B cells producing T15+ and T15- IgM, IgG3, IgG1, and IgG2 responses.     

Extinction of B-cell surface differentiation markers in hybrids between murine B-lymphoma and myeloma cells

Fusion between murine B-lymphoma cells bearing membrane IgM with either IgG or light chain secreting myeloma, resulted in cell hybrids synthesizing and secreting large quantities of IgM. In contrast, the hybrids did not secrete IgD even though it is also present on the surface of the B-lymphoma cells. B-Cell surface markers such as the IgM, IgD, Ia and the Fc receptor, which were present on the B-lymphoma cells, but not the myeloma cells were not expressed on the surface of the hybrids. Hybrids which secrete IgM and retain the B-cell membrane differentiation antigens were not detected, even when selection was done under conditions which favor the growth of the lymphoma parental cells.     

Regulation of IgA differentiation in CH12LX B cells by lymphokines. IL-4 induces membrane IgM-positive CH12LX cells to express membrane IgA and IL-5 induces membrane IgA-positive CH12LX cells to secrete IgA

In these studies we utilized the Ag (SRBC)-reactive B cell line CH12LX to study isotype switching. CH12LX cells are a stable population of B cells mainly bearing membrane IgM (mIgM) (98 to 99%) with a small population of B cells bearing membrane IgA (mIgA) (1 to 2%). LPS induced a 5- to 10-fold increase in the secretion of both Ig, whereas a lymphokine-rich supernatant of D10 T cells induced a greater increase in the secretion of IgA than IgM. Analysis of the latter effect with recombinant lymphokines disclosed that rIL-4 induced an increase in the number of mIgA+ cells (6 to 15%) with minimal effect on IgA secretion, whereas IL-5 induced increased IgA secretion but had no effect on mIgA expression. The addition of both lymphokines induced increased mIgA expression and IgA secretion. No effect on mIgA expression or IgA secretion was seen with other lymphokines, including IL-1, IL-2, IL-3, IL-6, GM-CSF, and IFN-gamma. The rIL-4 effect on CH12LX cells represents true differentiation rather than selective proliferation for the following reasons: first, subclones of CH12LX cells respond to IL-4-containing T cell supernatant in the same fashion as the original cell line; second, culture of CH12LX cells with IL-4 causes the appearance of large numbers of dual-bearing mIgM/mIgA cells as well as mIgA+ cells and a dual-bearing mIgM/mIgA line was obtained by cloning CH12LX after stimulation with an IL-4-containing supernatant; third, sorted mIgA+ and mIgA- CH12LX cells had similar rates of proliferation in the presence or absence of IL-4. In further studies, it was found that IL-5 causes IgA secretion by mIgA+ but not mIgA- CH12LX cells indicating that it is acting as a post-isotype switch differentiation factor. These studies are consistent with the view that IL-4 and IL-5 act in a sequential fashion to induce IgA expression and secretion in CH12LX cells, IL-4 inducing differentiation of mIgM+ cells to mIgA+ cells and IL-5 enhancing the IgA secretion by the resulting mIgA-bearing cells.