Specific mitogenic activity of 8-Br-guanosine 3',5'-monophosphate (Br-cyclic GMP) on B lymphocytes.

8-Br-cyclic GMP has been found to be a specific B cell mitogen; it triggers athymic nude mice spleen cells and "B mice" spleen cells, nylon adherent, anti-theta and complement-treated cells to proliferate. It does not stimulate thymocytes or purified T cells. The kinetics of the response to Br-cyclic GMP and LPS are almost identical. The mitogenic effect of LPS and Br-cyclic GMP is additive when the two mitogens are given together to cells. Spleen cells (C3H/HeJ strain) that did not respond to LPS were triggered by Br-cyclic GMP to make DNA. In order to achieve maximal stimulation by Br-cyclic GMP, the drug had to be in contact with the cells for more than 24 hr. Br-cyclic GMP was found to be mitogenic for spleen cells from five different mouse strains, but not for human leukocytes. DB-cyclic AMP was found to inhibit the DNA synthesis of T lymphocytes after they interacted with Con A; DB-cyclic AMP had no effect on the ability of the B lymphocytes to be transformed by LPS. The differential effects of cyclic nucleotides on B vs. T lymphocytes are discussed.     

LPS regulation of the immune response: separate mechanisms for murine B cell activation by lipid A (direct) and polysaccharide (macrophage-dependent) derived from Bacteroides LPS

Lipopolysaccharide (LPS) derived from Bacteroides fragilis has been reported to stimulate mitogenic responses in spleen cell cultures from the classical LPS-hyporesponsive C3H/HeJ mouse strain; however, we have shown that purified splenic B cells from C3H/HeJ mice are hyporesponsive to phenol-water extracted LPS from B. fragilis ATCC 25285 (B-LPS). In the present study, B-LPS and its purified lipid A and polysaccharide components were tested for their ability to induce mitogenic and polyclonal IgM synthesis in spleen cell and purified splenic B cell cultures from classical LPS-responsive and -hyporesponsive mice. Mitogenic responses to B-LPS and E. coli K235 LPS(Ph) of whole spleen cells (2 X 10(5) cells/culture) or purified B cells (5 X 10(5) cells/culture) from classical LPS-responsive mouse strains (C3H/HeN, BALB/c, C57BL/6J, C57BL/10Sn, and DBA/2), F1 mice (derived from crosses between LPS responsive and C3H/HeJ mice), and classical LPS-hyporesponsive mice (C3H/HeJ and C57BL/10ScN) were high, intermediate, and low, respectively. When a higher number of whole spleen cells (5 X 10(5) cells/well) were cultured, B-LPS induced high mitogenic responses in C3H/HeN, intermediate responses in F1, and lower but significant responses in C3H/HeJ cultures. Similar results were obtained when polyclonal IgM synthesis was assessed in cultures containing 1 X 10(6) cells/culture. In contrast, the purified lipid A component of B-LPS failed to induce mitogenic responses in either whole spleen or purified B cell cultures. The addition of purified splenic B cells from C3H/HeJ mice to C3H/HeN or C3H/HeJ splenic adherent cells resulted in mitogenic responses to B-LPS, implying that the hyporesponsiveness to B-LPS seen in whole spleen cell cultures from C3H/HeJ mice at the lower cell concentration was due to limiting numbers of M phi. When splenic B cells and M phi from either C3H/HeN or C3H/HeJ mice were incubated with the lipid A or the polysaccharide moiety of B-LPS, lipid A induced mitogenic responses only in C3H/HeN cultures, whereas the polysaccharide moiety induced similar responses in both C3H/HeN and C3H/HeJ cultures. These results suggest that Bacteroides lipid A does not stimulate B cells from the classical LPS-hyporesponsive C3H/HeJ mouse strain, whereas the polysaccharide moiety of B-LPS is biologically active and mediates B cell stimulation via M phi.     

Activation to IgG secretion by lipopolysaccharide requires several proliferation cycles.

We have investigated the relationship between IgG secretion and cell proliferation after polyclonal activation of murine spleen cells with lipopolysaccharide (LPS). It was found that IgG secretion was optimal when cells proliferated extensively. Under those conditions, DNA synthesis commenced 8 to 12 hr after exposure to LPS. Increased proliferative activity was observed up to day 3, when the majority of the lymphoblasts were mitotically active. Two inhibitors of DNA synthesis, thymidine (TdR) and hydroxyurea (HU) caused a reduction in both the IgM and the IgG response, but the latter was more severely reduced. The inhibition was strongest when TdR and HU were added to cultures early after exposure to LPS, indicating that the cells developing to Ig secretion were continuously proliferating. 5-bromo-2'-deoxyuridine (BrdU) caused a general inhibition of IgM and IgG secretion at high concentrations, and a selective inhibition at low concentrations. The selective inhibition of IgG secretion, when measured on day 4, was also observed after a pulse of BrdU on days 1 and 2. The data suggest that development to IgG secretion is a complex process, which requires several proliferation cycles.     

Differentiation of lymphoid cells: B cell as a direct target and T cell as a regulator in lipopolysaccharide-enhanced induction of immunoglobulin production.

The cells involved in the stimulatory effect of bacterial lipopolysaccharide (LPS) on the induction of immunoglobulin (Ig) production by rabbit spleen cells cultured in the absence of antigen has been analyzed. Addition of LPS caused a several-fold enhancement of both DNA synthesis and Ig production. These enhanced activities were not significantly affected by depletion of adherent cells in the spleen cell population. Although inactivation of splenic T cells by anti-thymocyte serum (ATS) treatment did not affect the enhancement of DNA synthesis due to LPS, such treatment did adversely affect the enhancement of Ig production by LPS. Furthermore, the enhancement of Ig production of ATS-treated spleen cells by LPS was found to be dependent on the number of thymocytes added. In addition, the prior incubation of ATS-treated spleen cells with LPS resulted in effective enhancement of Ig production when such ATS-treated spleen cells and thymocytes were combined after removal of LPS. An identical experiment, except that thymocytes instead of ATS-treated spleen cells received the prior incubation with LPS, did not result in enhancement of Ig production. Finally, the enhanced Ig production due to LPS was inhibited by hydroxyurea, a known inhibitor of cellular DNA synthesis. The relationship between the mitogenic activity of LPS on B cells, the regulatory function of T cells, and the enhancement of Ig production by LPS is discussed in relation to the contrasting reports concerning the cellular target of LPS.     

Mitogenic activity of Actinomyces viscosus. I. Effects on murine B and T lymphocytes, and partial characterization.

Actinomyces viscosus homogenate (AVIS) contins substance(s) which cause spleen cells from conventional and germfree mice to undergo increased DNA synthesis. This mitogenic effect is primarily on B cells since spleen cells from nude mice or T-depleted spleen cells from conventional mice respond as strongly as conventional (T + B) spleen cells. Mouse thymocytes do not respond mitogenically to AVIS. It is unlikely that the mitogenic acitivity is due to the presence of LPS, since A. viscosus is Gram-positive and is not known to have an LPS cell wall component. Also, AVIS is not inactivated by polymyxin B, as are some preparations of LPS, and C3H/HeJ mouse splenocytes respond strongly to AVIS but not to LPS. The activity is heat stable, is not lost upon dialysis, and is not affected by lysozyme. Mitogenic activity is partially lost when AVIS is digested with nonspecific bacterial protease or treated with metaperiodate. Sodium hydroxide treatment completely abolishes mitogenic activity. Actinomycotic lesions are characterized by a long-tern inflammatory response involving a dense plasma cell infiltrate. We suggest that B cell mitogens form Actinomyces may play a role in the elicitation of the plasma cell component of these lesions.     

A B Lymphocyte Mitogen Extracted from a Fungus Peziza vesiculosa1

A water-soluble mitogen was extracted with hot-water from the fruiting bodies of a fungus, Peziza vesiculosa, collected in the wild. The active substance, named vesiculogen, was able to stimulate selectively murine B cells because mitogenic activity was observed in the spleen cell cultures of congenitally athymic nude mice, but not in the thymus cell cultures. The possibility that the mitogenicity of vesiculogen was due to lipopolysaccharide was denied completely by the following evidence: 1) lipopolysaccharide in vesiculogen was undetectable (less than 0.001% in the Limulus test), 2) vesiculogen was able to stimulate strongly DNA synthesis of spleen cells from C3H/HeJ mice, and 3) the mitogenic activity of vesiculogen was not inhibited by polymyxin B. Vesiculogen increased antigen-nonspecifically the number of direct plaque forming cells to sheep erythrocytes, horse erythrocytes, and trinitrophenylated-horse erythrocytes. This result shows that vesiculogen acts as a polyclonal B cell activator on murine spleen cells.     

LPS regulation of the immune response: Bacteroides endotoxin induces mitogenic, polyclonal, and antibody responses in classical LPS responsive but not C3H/HeJ mice

Recent studies have suggested that lipopolysaccharide (LPS) derived from gram-negative organisms such as Bacteroides, which are not members of the Enterobacteriaceae, stimulate B cells from the classic LPS-hyporesponsive C3H/HeJ mouse. In the present study, purified, phenol-water-extracted LPS from Bacteroides fragilis ATCC 25285 (B-LPS) was tested for its ability to induce in vivo and in vitro responses in classic LPS-responsive C3H/HeN, LPS-hyporesponsive C3H/HeJ, and (C3H/HeN X C3H/HeJ)F1 hybrid mice. B-LPS induced mitogenic responses in both C3H/HeN and C3H/HeJ spleen cell cultures when cells were cultured under standard conditions, i.e., 8 X 10(5) cells/well. Interestingly, when lower spleen cell numbers were tested with B-LPS, a typical responsive-nonresponsive pattern developed in which good mitogenic responses were induced by B-LPS in C3H/HeN cultures and in which low responses in C3H/HeJ spleen cell cultures were evident. In vivo immunization of mice with B-LPS resulted in high antibody responses in C3H/HeN, intermediate responses in F1, and low responses in C3H/HeJ mice. When purified splenic B cells were incubated with B-LPS, both mitogenic responses and polyclonal immunoglobulin M (IgM) synthesis occurred in C3H/HeN cultures, whereas intermediate responses were noted in F1 cultures and no response was seen in B cell cultures from C3H/HeJ mice. Furthermore, in vitro TNP-B-LPS responses were induced in C3H/HeN spleen cells or purified B cell cultures, and intermediate anti-TNP PFC responses occurred in F1 spleen cells or purified B cell cultures. The toxicity of B-LPS was tested in galactosamine-sensitized mice. The LD50 values for B-LPS in classic LPS-responsive C3H/HeN and C57BL/6J mice were 0.6 microgram and 1.1 microgram, respectively; F1 hybrid mice were approximately 15-fold more resistant, whereas C3H/HeJ mice gave an LD50 of 1650 micrograms. This study shows that phenol-water preparations of B-LPS are biologically active and induce responses in the classic LPS-responsive but not in the LPS-hyporesponsive C3H/HeJ mouse strain.     

Immunologic properties of bacterial lipopolysaccharide (LPS). IV. Cellular basis of the unresponsiveness of C3H/HeJ mouse spleen cells to LPS-induced mitogenesis.

Lymphoid cells obtained from the C3H/HeJ mouse strain respond abnormally to LPS in vitro, as shown by the fact that they are unable to make a mitogenic response to some LPS preparations and make only a low mitogenic response to other LPS preparations. In contrast, cells from a closely related C3H substrain, the C3H/St, are highly responsive to both types of LPS preparations. Experiments were carried out to determine the cellular basis of these genetically determined LPS response differences. This question was approached by studying the mitogenic response to LPS in cultures containing mixtures of various combinations of B cells, T cells, and macrophages from C3H/HeJ and C3H/St mice. Experiments utilizing an LPS preparation to which the C3H/HeJ is totally unresponsive (negative LPS) revealed, first, that either spleen cells, or partially purified T cells and/or macrophages obtained from C3H/St, could not restore the ability of C3H/HeJ spleen cells to respond to LPS, indicating that the C3H/HeJ is not deficient in an LPS-specific helper cell population which may be required for mitogenesis. Secondly, the addition of either spleen cells or partially purified T cells or macrophages from the C3H/HeJ to spleen cells from the C3H/St did not inhibit the mitogenic response to LPS, suggesting that the presence of suppressor cell activity is also not involved. Experiments analogous to those described, except utilizing another LPS preparation to which the C3H/HeJ is partially responsive (positive LPS), also failed to demonstrate reconstitutive or suppressive effects when C3H/HeJ and C3H/St spleen cells were admixed. The results obtained indicate that the defect in the C3H/HeJ mouse strain that limits its responsiveness to positive LPS and which renders it totally unresponsive to negative LPS appears to be an intrinsic defect in the capacity of B cells to react to the mitogenic stimulus of LPS.     

Genetic control of responses to bacterial lipopolysaccharides in mice. II. A gene that influences a membrane component involved in the activation of bone marrow-derived lymphocytes by lipipolysaccharides.

C3H/HeJ mice contain a defect in a single autosomal locus which is not linked to the H-2 histocompatibility or the heavy chain allotype loci that restrict immune, mitogenic, and polyclonal responses to bacterial lipopolysaccharides (LPS). Adult thymectomized C3H/HeJ mice that have been irradiated and reconstituted with C3HeB/FeJ bone marrow cells respond well to LPS. Cell-mixing experiments using C3H/HEJ-C3HeB/FeJ spleen cultures show that the failure of C3H/HeJ spleen cells to support responses to LPS is not due to nonspecific or LPS-induced suppressive events, or the lack of accessory cell types. C3H/HeJ and C3HeB/FeJ spleen cells bind LPS and respond to other B cell mitogens equally well. We suggest that the B lymphocytes of C3H/HeJ mice have a defect in a membrane component that is activated via interaction with LPS, and initiates the intracellular events that lead to cell proliferation.     

Immunomodulatory role of IL-4 on the secretion of Ig by human B cells

The effect of IL-4 on the production of Ig by human B cells was examined. Highly purified B cells were stimulated with Staphylococcus aureus (SA) and IL-4 alone or in combination with various other cytokines and the supernatants assayed for Ig by isotype-specific ELISA. IL-4 (10 to 100 U/ml) did not support Ig secretion by SA-stimulated blood, spleen, or lymph node B cells, whereas IL-2 supported the production of all isotypes including IgE. Moreover, IL-4 suppressed the production of all isotypes of Ig by B cells stimulated with SA and IL-2 including IgG1, IgG2, and IgE. IL-4-mediated suppression was partially reversed by IFN-gamma or -alpha and low m.w. B cell growth factor. TNF-alpha and IL-6 did not reverse the IL-4-induced suppression of Ig production. The inhibitory action of IL-4 on Ig production appeared to depend on the polyclonal activator used to stimulate the B cells. Thus, Ig secretion by B cells activated by LPS and supported by IL-2 was not inhibited by IL-4. Whereas IL-4 alone supported minimal Ig production by LPS-activated B cells, it augmented production of all Ig isotypes in cultures stimulated with LPS and supported by IL-2. IFN-gamma further enhanced production of Ig in these cultures. When the effect of IL-4 on the responsiveness of B cells preactivated with SA and IL-2 was examined, it was found not to inhibit but rather to promote Ig production modestly. A direct effect of IL-4 on the terminal differentiation of B cells was demonstrated using B lymphoblastoid cell lines. IL-4 was able to enhance the Ig secreted by an IgA-secreting hybridoma, 219 and by SKW6-CL-4, an IL-6-responsive IgM-secreting EBV transformed B cell line. These results indicate that IL-4 exerts a number of immunoregulatory actions on human B cell differentiation. It interferes with the activation of B cells by SA and IL-2, but promotes the differentiation of preactivated B cells, B cell lines, and B cells activated by LPS without apparent isotype specificity.     

Polyclonal B cell stimulation and interleukin 1 induction by the mucoid exopolysaccharide of Pseudomonas aeruginosa associated with cystic fibrosis

Mucoid exopolysaccharide isolated from Pseudomonas aeruginosa obtained from colonized cystic fibrosis patients was found to be a potent mitogen for mouse lymphocytes. The responding lymphocyte was a B cell, and we found no evidence that T cell could proliferate or synergize with B cells in response to the mucoid exopolysaccharide. Proliferation was not inhibitable by polymyxin B, which blocks lipopolysaccharide (LPS)-induced proliferation, indicating that a minor LPS contaminant in the purified exopolysaccharide was not the mitogenic component. Mucoid exopolysaccharide induced secretion of IgG, suggesting that it is polyclonal mitogen. It also induced splenic adherent cells (macrophages) to produce interleukin 1. We propose that mucoid exopolysaccharide produced by P. aeruginosa present in the lungs of cystic fibrosis patients may have potent in vivo consequences resulting in aberrant immunoregulation and inhibition of effective immune elimination of P. aeruginosa.     

Polyclonal activation of murine B lymphocytes by Fc fragments. I. The requirement for two signals in the generation of the polyclonal antibody response induced by Fc fragments

Fc fragments derived from human IgG1 induce murine splenic B lymphocytes to undergo proliferation and differentiation to antibody-secreting cells. The polyclonal antibody response was found to require both the presence of macrophages and T cells. Spleen cell cultures from nude mice or T cell-depleted normal mice proliferate to the level of untreated control mice but do not produce polyclonal antibody unless T cells are added. Regulation of the Fc fragment induced B cell differentiation to antibody synthesis apparently occurs through two distinct signals. One signal is provided by Fc fragments for proliferation and the other by T cells for differentiation. This suggestion is supported by the observation that spleen cell preparations, devoid of T cells, are capable of proliferation to the level of normal spleen cell cultures in response to Fc fragments, but are incapable of making a polyclonal antibody response. The cell population that responds to the differentiation signal also responds to the proliferative signal. "Hot pulse" experiments demonstrated that proliferation precedes polyclonal activation.     

Polyclonal activation of the murine immune system by an antibody to IgD. VII. Demonstration of the role of nonantigen-specific T help in in vivo B cell activation

Previous studies from this laboratory have shown that the injection of mice with an affinity-purified goat antibody to mouse IgD (GaM delta) induces T-independent polyclonal increases in: 1) B cell DNA synthesis, and 2) expression of surface Ia antigen and receptors for T helper factors, 1 to 2 days after injection. In addition, T-independent polyclonal increases in B cell number and IgG1 secretion are observed 6 to 7 days after injection. The administration of normal goat IgG (GIgG) along with GaM delta has been shown to augment GaM delta-induced polyclonal IgG1 secretion. To obtain information about the characteristics of the T help that is required for polyclonal antibody production in this model system, we investigated: 1) the length of the period during which GaM delta must be present to induce day 7 polyclonal antibody production, and 2) the kinetics of the induction of splenic T cell DNA synthesis. We found that GaM delta can be neutralized 3 days after injection by the administration of IgD without decreasing day 7 polyclonal IgG1 secretion, as long as mice are given GIgG at the time that GaM delta is neutralized. In contrast, polyclonal IgG1 secretion is greatly inhibited if GaM delta is neutralized 1 to 2 days after injection or if GaM delta is neutralized 3 days after injection, but GIgG is not administered at this time. Because GIgG can stimulate activated GIgG-specific T cells to secrete helper factors, but, unlike GaM delta cannot focus GIgG-specific T help polyclonally onto B cells, these findings suggest that nonspecific T help, rather than antigen-specific T help, is required in this system after day 3 for the induction of polyclonal IgG1 secretion. Determination of the kinetics of the induction of T cell DNA synthesis in this system by in vivo [3H] thymidine incorporation studies, as well as dual laser fluorescence-activated cell sorter analysis of T and B cell DNA content, indicate that T cells are induced to synthesize DNA 2 days after GaM delta injection and reach plateau rates of DNA synthesis 3 days after injection. Taken together, the GaM delta neutralization experiments and DNA synthesis studies suggest that one reason that GaM delta is required for 3 days in this system is to allow maximal activation of GIgG-specific T cells, which when stimulated later by GIgG secrete nonantigen-specific helper factors that induce GaM delta-activated B cells to secrete IgG1.     

IgE class switching is critically dependent upon the nature of the B cell activator, in addition to the presence of IL-4.

Cross-linkage of membrane IgD on resting murine B cells, by anti-IgD mAb conjugated to dextran (alpha delta-dex), induces high levels of proliferation, and in the presence of IL-2 or IL-5, Ig secretion in vitro. The structural and functional similarities between alpha delta-dex and TNP-Ficoll for B cell responses led us to propose that alpha delta-dex could provide a model system for studying B cell activation induced by T cell-independent, type II Ag. In this report, we study the effects of Ig class switch and differentiation factors on Ig isotype production by murine B cells activated by alpha delta-dex, and directly compare these to responses obtained after activation by LPS. We show that an IL-4-containing CD4+ T cell supernatant (Th2 SN) stimulates large increases in IgG1 and IgE production by LPS-activated B cells, but fails to stimulate detectable levels of IgE by alpha delta-dex-activated cells, despite inducing high levels of secreted IgM and IgG1. This is correlated with undetectable steady state levels of both germ-line and rearranged (productive) IgE-specific RNA in B cells stimulated with alpha delta-dex + Th2 SN. Alpha delta-dex is selective in its failure to costimulate IgE production in that IFN-gamma-containing T cell supernatant (Th1 SN) and transforming growth factor-beta-supplemented Th2 SN selectively stimulate a large IgG2a and IgA secretory response, respectively. Anti-IgD conjugated to Sepharose beads, in distinct contrast to dextran, costimulates a strong IgE response. These findings underscore the importance of the specific B cell activator, in addition to IL-4, in the regulation of IgE production.     

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.     

A polyclonal model for B cell tolerance. I. Fc-dependent and Fc-independent induction of nonresponsiveness by pretreatment of normal splenic B cells with anti-Ig.

We have developed a simple and adaptable, polyclonal model for B cell nonresponsiveness that is based on the inhibitory activity of anti-Ig as a surrogate for Ag. In our system the induction phase (treatment with anti-Ig) is separated from the challenge phase (Ag or mitogen), so that the critical events in each phase can be evaluated. Our results show that T cell-depleted B cells precultured for 18 to 24 h with rabbit anti-Ig reagents are rendered unresponsive to challenge with either Ag, fluorescein coupled to Brucella abortus (FL-BA), or mitogen (LPS). This state of nonresponsiveness (anergy) is reflected by an inhibition of a prototype response to the fluorescein hapten, as well as total Ig and IgG synthesis, but no reduction in proliferation to LPS. Interestingly, mitogen-induced polyclonal antibody formation was consistently reduced by 90% by treatment with either F(ab')2 or intact IgG anti-Ig. In contrast, the Ag-driven (FL-BA) response of pretreated B cells was inhibited by only 50 to 70%. Moreover, the latter effect usually required pretreatment with intact IgG anti-Ig, a result that suggests the importance of an Fc-dependent negative signal affecting the B cell's response to FL-BA. Furthermore, pretreatment and coculture of B cells with IL-4 blocked the Fc-dependent inhibition of the FL-BA responsiveness. These results, as well as kinetics experiments establishing a 4-h latent period, suggest that simple blocking of surface Ig receptor on target B cells is not responsible for the induction of anergy. Pretreated B cells displayed unique phenotypic changes after treatment with anti-Ig, including a diminution of Thy-1 expression in response to LPS + IL-4, as well as a reduction in membrane IgM and J11d expression (i.e., they were IgMlo, IgDmed, and J11dlo, as recently reported for anergic B cells in transgenic mice). These results suggest that B cell anergy can be induced in mature B cells by both Fc-dependent and Fc-independent processes that lead to unique phenotypic changes and may reflect egress from G0 in the absence of T cell help. The significance of these changes to tolerance mechanisms is discussed.     

Regulation of isotype production by IL-4 and IL-5. Effects of lymphokines on Ig production depend on the state of activation of the responding B cells

The effects of IL-4 and IL-5 on the production of Ig of different isotypes was investigated. We compared B cells from spleen and from Peyer's patches either stimulated with LPS or without added polyclonal stimulation. We also compared high density (small) and low density (large) B cells. The effect of lymphokines depended on the size and source of the B cells as well as on whether LPS was added. As expected, small B cells from either lymphoid compartment responded to LPS alone and IL-4 suppressed IgM and IgG3 production and enhanced IgG1. In contrast, when large B cells were examined, the suppressive effects of IL-4 were much less apparent but the enhancement of IgG1 was still marked. IL-5 alone had only minimal effects in LPS-stimulated cultures but the combination of IL-4 plus IL-5 appeared to overcome much of the IL-4-mediated suppression of IgM, and IgA production was enhanced. In the absence of LPS, a quite different profile is seen. First, small B cells make little if any response. Second, there is dramatic synergy between IL-4 and IL-5 in the response of large B cells, which is independent of isotype. Third, IL-4 does not suppress any isotype in the absence of LPS. Fourth, IL-4 plus IL-5 stimulate large Peyer's patch B cells to produce 10 times more IgA but three times less IgM than large spleen B cells. Fifth, Th2 cells directly stimulate both large and small B cells.     

Cellular mechanism of endotoxin unresponsiveness in C3H/HeJ mice.

B cells from C3H/HeJ mice fail to respond to an endotoxin (LPS K235) which is mitogenic for normal mice including the closely related C3H/HeN strain. The cellular basis for this unresponsive state has been investigated. The C3H/HeJ mice have normal numbers of B cells, which are capable of normal responses to other B cell mitogens, such as polyinosinic acid (Poly I). Addition of normal macrophages or spleen cells fails to reconstitute the normal response. Furthermore, neither macrophages nor spleen cells from the C3H/HeJ strain suppress the normal C3H/HeN spleen cells. Finally, spleen cells enriched for B cells by the removal of macrophages or T cells demonstrate the same differences in responsiveness to LPS. These results indicate that LPS unresponsiveness is a defect of the B cell itself and not due to suppressor cells or the absence of helper cells. When LPS is added to Poly I-stimulated cultures, there is additional enhancement of the response of normal C3H/HeN spleen cells. However, LPS causes a dose-dependent suppression of the Poly I response of C3H/HeJ spleen cells. This suppression is dependent on the time of addition of LPS to the Poly I-stimulated cultures. These data are interpreted as indicating that the binding of LPS to the membrane of C3H/HeJ B cells results in their inactivation or suppression, and that this is the basis of LPS unresponsiveness in this mouse strain.     

Role of DNA synthesis in secretion of immunoglobulin from murine B cells stimulated by T cell derived lymphokines

We have investigated whether cell division is required for induction of Ig secretion from three types of B cells, which represent distinct activation states: normal splenic B cells, anti-Ig-treated B cells, and a monoclonal murine B cell tumor, BCL1. Polyclonal Ig secretion was stimulated in vitro by LPS or by lymphokines produced by EL-4 cells (EL-4 SN), which includes B cell growth factor II (BCGF II). LPS and EL-4 SN were mitogenic for all three cell populations and stimulated substantial IgM secretion from both B cells and anti-Ig blasts. Aphidicolin, a reversible inhibitor of DNA synthesis, abolished IgM secretion from B cells and anti-Ig blasts induced by either mitogen, indicating that Ig-secreting cells in these cultures are part of a cycling population. BCL1 tumor cells respond to BCGF II (but not to interleukin 2 or B cell stimulatory factor 1) with IgM secretion and cell division, allowing a direct assessment of the influence of BCGF II-stimulated cell division on secretion of IgM. Secretion by these cells during the first 24 hr of culture was not substantially affected by aphidicolin, but secretion at 48 or 72 hr was markedly inhibited. Culture of BCL1 cells for 48 hr with aphidicolin alone had no effect on cell viability or on subsequent responsiveness if the drug was removed, eliminating non-specific toxicity as an explanation of the drug's effect. Addition of aphidicolin during the last 24 hr of culture to either normal B cells or BCL1 cells was much less effective at inhibiting IgM secretion. These results indicate that the cells that secrete IgM in response to BCGF II also synthesize DNA when exposed to this factor. Thus, induction of high-rate Ig secretion from murine B cells by some stimuli, including BCGF II, may require at least one round of cell division.