IL-3 promotes production of IL-4 by splenic non-B, non-T cells in response to Fc receptor cross-linkage

A spleen cell population that lacks CD3, CD4, CD8, Thy-1, B220, and class II major histocompatibility complex cell-surface markers (non-B, non-T cells) produces IL-4 when cultured in wells coated with IgE. Their production of IL-4 in response to plate-bound (PB)-IgE is strikingly enhanced by IL-3, and in the presence of IL-3, these cells also produce IL-4 in response to PB-IgG2a. The effect of IL-3 is not mimicked by IL-1, IL-2, IL-5, IL-6, IL-7, granulocyte-macrophage CSF (GM-CSF) or IFN-gamma. Non-B, non-T cells cultured with IL-3 for 12 h acquire the capacity to produce enhanced amounts of IL-4 in response to subsequent culture with PB-Ig even if IL-3 is omitted from the second culture. Irradiated cells also respond to IL-3 with enhanced capacity to produce IL-4 to PB-Ig, indicating that cell proliferation is not required for the effect of IL-3. The IL-3 effect can be obtained in vivo; treatment of mice with a total dose 90,000 U of synthetic IL-3 over a 3-day period results in the presence of splenic and peritoneal cavity non-B, non-T cells that produce enhanced amounts of IL-4 in response to PB-Ig. The FcR that mediates the response to PB-IgE appears to be Fc epsilon RI because cells can be sensitized with IgE anti-DNP mAb, washed, cultured for 15 h at 37 degrees C, washed again, and stimulated to produce IL-4 with 0.1 to 1 ng/ml of TNP10-OVA. IL-3 does not appear to mediate its function by increasing the number of Fc epsilon RI because it can exert its effect when cultured with non-B, non-T cells after they have been sensitized with IgE anti-DNP. However, IL-3 pretreatment does affect the signaling process in that non-B, non-T cells sensitized with IgE anti-DNP show strikingly reduced production of IL-4 to concentrations of TNP10-OVA of 100 ng/ml or more whereas cells pretreated with IL-3 show little or no diminution in IL-4 production at concentrations of TNP10-OVA up to 1 microgram/ml.     

IgE formation and Fc receptor-positive lymphocytes in normal, immuno-deficient, and auto-immune mice infected with Nippostrongylus brasiliensis

The IgE serum levels and IgE FcR-positive lymphocytes (Fc epsilon R) in the spleen and mesenteric lymph nodes (MLN) of normal and immunologically mutant strains of mice were determined before and 14 days after infection with Nippostrongylus brasiliensis (Nbr) parasites. By IgE rosetting of cells immunofluorescently stained for sIg. Thy-1.2, Lyt-2, and L3T4, only sIg+ IgE rosetting lymphocytes were detected in both normal and Nbr-infected mice. IgE high responder mice had the same percentage of Fc epsilon R+ spleen and MLN lymphocytes as low responder mice. After Nbr infection, the percentages of splenic and MLN Fc epsilon R+ cells increased in parallel to a similar increase of sIg+ B cells. Athymic C57BL/6J-nu mice had 62% Fc epsilon R+ spleen and 85% Fc epsilon R+ MLN cells before and after Nbr infection, but IgE serum levels were less than 5 ng IgE/ml. C57BL/6J mice with the viable moth-eaten mutation mev which have almost exclusively Ly-1+ B cells, had less than 1% Fc epsilon R+ lymphocytes and formed only small amounts of IgE. C57BL/6J mice with the lymphoproliferation (lpr) or generalized lymphoproliferative disease (gld) mutations had low numbers of Fc epsilon R+ cells but formed 15 to 30 times more IgE after Nbr infection than control C57BL/6J mice. The IgE response of mice with the beige mutation (bg) did not differ from control mice. Mice with the xid mutation had few Fc epsilon R+ and sIg+ cells but showed high IgE responses. These data demonstrate that Fc epsilon R are typical cell surface markers for approximately 90% of murine Ly-1-, sIg+ B cells and that the number of Fc epsilon R+ cells does not correlate with the capacity of the mice to form IgE. The IgE response to Nbr infection is normal in mice homozygous for the bg mutation, elevated in mice homozygous for the xid, lpr, and gld mutations, and decreased in mice homozygous for the mev and nu mutations.     

IL-4 requirements for the generation of secondary in vivo IgE responses.

IL-4 has been shown to induce B lymphocytes to switch from the expression of membrane IgM to the expression of membrane IgE and to be required for the generation of primary polyclonal and secondary Ag-specific IgE responses in mice. To further define the role of IL-4 in the generation of memory IgE responses, we investigated the ability of a combination of anti-IL-4 and anti-IL-4R mAb to block the generation of secondary IgE responses induced by: 1) a second infection with the nematode parasites Nippostrongylus brasiliensis or Heligmosomoides polygyrus; or 2) injection of anti-IgD antibody-primed mice with anti-IgE antibody. The latter stimulus was designed to induce intrinsic membrane IgE-expressing B cells to differentiate into IgE-secreting cells. Although the IgE responses induced by a second nematode infection were completely inhibited by the combination of anti-IL-4 and anti-IL-4R mAb, anti-IgE antibody-induced IgE responses in anti-IgD primed mice were not inhibited by these antibodies to a large degree. Additional experiments demonstrated that the anti-IgE antibody-induced memory IgE response was dependent on CD4+ T cells but did not involve the low affinity B cell Fc epsilon RII. Taken together, these observations provide evidence that IL-4 is required for virgin B lymphocytes to develop into IgE-expressing cells, but is not required for B cells that express intrinsic membrane IgE to differentiate into IgE-secreting cells in a T-dependent response. Furthermore, these data suggest that secondary IgE responses in the parasite models that we have studied develop from B cells that had not previously switched to the expression of IgE.     

Effect of B cell stimulatory factor-1 (interleukin 4) on Fc epsilon and Fc gamma receptor expression on murine B lymphocytes and B cell lines

Culture of murine splenic B cells with interleukin 4 (IL-4) caused the up-regulation of the lymphocyte Fc receptor for immunoglobulin E (IgE) (Fc epsilon R) over a similar dose range as required for Ia up-regulation. However, the expression level of the Fc receptor for immunoglobulin G (Fc gamma R) did not increase, rather IL-4 caused a slight but consistent decrease in the Fc gamma R level on the B cells. Fc epsilon R+ B hybridoma cells also responded to IL-4 by exhibiting increased Fc epsilon R expression; with the hybridoma cells Fc gamma R levels were unaffected. IL-4 caused an increase in the number of Fc epsilon R per cell and the highest levels of expression were obtained by having both IgE and IL-4 present in the culture. The specificity of the increase was demonstrated by blocking IL-4-mediated actions with monoclonal anti-IL-4 (11B11). Experiments following the incorporation of [35S]methionine into the Fc epsilon R demonstrated that IL-4 increased the rate of Fc epsilon R biosynthesis; this provides an explanation for the IL-4-induced increase in Fc epsilon R expression. IL-4, unlike IgE, had no effect on the rate of degradation of the Fc epsilon R. Interferon-gamma (IFN-gamma) totally abrogated IL-4-mediated Fc epsilon R up-regulation; at the same concentration of IFN-gamma Ia up-regulation is also suppressed, although not as effectively. IFN-gamma was shown to directly suppress Fc epsilon R synthesis, thereby explaining the inhibitory action on Fc epsilon R levels. Finally, it was shown that 11B11 inhibited the increased expression of Fc epsilon R on B cells obtained from mice during the early, but not the late, stages of Nippostrongylus brasiliensis infection. This latter finding suggests that the high Fc epsilon R levels seen early in parasite infections are dependent upon IL-4. The results overall provide further insight into the biologic activities of IL-4.     

A soluble factor produced by bone marrow natural suppressor cells blocks interleukin 2 production and activity

We previously reported that a population of Fc gamma-receptor+ (Fc gamma R+) suppressor cells present in normal unstimulated rabbit bone marrow inhibited the growth of autologous rapidly proliferating bone marrow cells devoid of Fc gamma R. It is now reported that the Fc gamma R+ bone marrow cells produced a soluble, nondialyzable suppressor factor(s) (SF) which blocked the proliferation of Fc gamma R- bone marrow cells. In addition, the Fc gamma R+ cells and SF significantly inhibited spleen cell proliferation in response to concanavalin A (Con A), phytohemagglutinin, and pokeweed mitogen. The bone marrow SF exhibited a dose-dependent suppression of the growth of IL-2-dependent T lymphocytes in the presence of IL-2. SF also completely blocked the production or release of IL-2 by Con A-stimulated T cells. Thus, these bone marrow natural suppressor cells produced a soluble factor, which regulated the growth of rapidly proliferating bone marrow cells and also regulated T cell reactivity by modulating IL-2 production and activity.     

In vivo and in vitro regulation of IgE production in murine hybridomas

Normal BALB/c mice injected i.p. with the IgE-secreting hybridomas B53 (epsilon, kappa anti-DNP), SE1.3 (epsilon, kappa, anti-arsonate) or A3B1 (epsilon, kappa, anti-TNP) were monitored for serum IgE concentrations and frequencies of splenic T lymphocytes with surface membrane receptors for the Fc portion of IgE (Fc epsilon R+ T lymphocytes). Mice with B53 or SE1.3 hybridomas initially developed high concentrations of IgE and CD8+ Fc epsilon R+ T lymphocytes, followed by a progressive decline in both serum IgE and expression of cytoplasmic epsilon-chains in the hybridoma cells. Serum IgE concentrations in mice with A3B1 hybridomas progressively increased without development of Fc epsilon R+ T lymphocytes nor a subsequent decline in IgE or change in cytoplasmic epsilon-chain expression in the A3B1 cells. An in vitro system in which the IgE-secreting hybridoma cells were cocultured with spleen cells harvested from mice with established B53 tumors was used to investigate the mechanisms involved in the inhibition of IgE production by the hybridoma cells. The results of these studies indicate that: 1) the induction/upregulation of Fc epsilon R on CD8+ T lymphocytes in vivo requires factors in addition to high serum IgE concentrations; 2) in addition to CD8+ Fc epsilon R+ T lymphocytes and monocytes, another, as yet unidentified, splenic cell component appears to contribute to the process by which epsilon-chain expression in IgE-secreting hybridoma cells is suppressed, and 3) a hybridoma (A3B1) that fails to induce CD8+, Fc epsilon R+ T lymphocytes in vivo and is not inhibited in IgE expression in vivo, nonetheless is inhibited in IgE expression in vitro when cocultured with spleen cells from mice with B53 tumors.     

Accelerated recovery of antigen-presenting cell activity by the administration of interleukin 1 alpha in 5-fluorouracil-treated mice

In this study, we investigated the effect of human recombinant interleukin-1 alpha (IL-1 alpha) on antigen-presenting cell (APC) activity of spleen cells in mice treated with 5-fluorouracil (5-FU). APC activity was determined by the antigen-specific proliferation of T cell clone D10.G4.1 cells. When mice were injected with 5-FU, APC activity of spleen cells was suppressed. The administration of IL-1 alpha accelerated the recovery from this suppression. The most accelerated recovery was observed when these mice were administered with IL-1 alpha both before and after the 5-FU treatment. The recovery was also accelerated when the mice were injected with IL-1 alpha after the 5-FU treatment, but not when injected before the 5-FU treatment. The injection of 5-FU also decreased the cell numbers of whole spleen cells, B cells, and non-T non-B cells (Ig- and Thy-1- cells). The administration of IL-1 alpha accelerated the recovery of the decreased cell numbers. Both B cells and non-T non-B cells possessed APC activity, but most APC activity of unseparated spleen cells was carried by non-T non-B cells. B cells possessed only 1/20 of the APC activity of non-T non-B cells. The injection of 5-FU decreased APC activity of both B cells and non-T non-B cells, but the administration of IL-1 alpha accelerated its recovery. Thus, the accelerated recovery of APC activity by IL-1 alpha was suggested to be due to the recovery in the numbers of APC activity-bearing cell subpopulations and also due to the recovery of the APC activity of each subpopulation. Possible mechanisms for the recovery were discussed.     

Correlation between DNA methylation and murine IFN-gamma and IL-4 expression

In order to determine the possible role of DNA methylation as a regulatory mechanism for the restricted pattern of lymphokine production among differentiated Th(1)and Th(2)cells, we examined the extent of methylation of the interferon gamma (IFN-gamma) and the interleukin 4 (IL-4) genes in fresh activated murine Th(0), Th(1)and Th(2)cells, unstimulated naive T cells, B cells, bone marrow derived non-B non-T cells, thymocytes and liver. All of the CpG dinucleotides examined in the IL-4 and the IFN-gamma genes, were fully methylated over the body of the gene in all of the examined cells. However, analysis of the promoter regions of these genes revealed a different pattern. While the IL-4 promoter is fully methylated in all of the examined cells, two adjacent CpG dinucleotides near the initiation point of the IFN-gamma gene were unmethylated in all T cells, including 17-day-old fetal thymocytes. In contrast, B cells, bone marrow non-B non-T cells and liver cells displayed a full methylated profile of the IFNgamma promoter. These results suggest that the mutually exclusive pattern of IFNgamma and IL-4 production in Th(1)and Th(2)cells is not regulated by differential demethylation of these two genes.     

Rabbit bone marrow suppressor cells block the production or release of a soluble bone marrow growth factor

Fc gamma-receptor (Fc gamma R)-bearing cells from normal rabbit bone marrow suppressed the constitutive proliferation rates of the remaining, Fc gamma R-, cells. In the absence of the suppressive influences of Fc gamma R+ cells, cells in the Fc gamma R- population spontaneously elaborated a soluble growth factor (GF) which induced the proliferation of unseparated bone marrow cells. To examine regulation by Fc gamma R+ bone marrow cells, graded numbers of the Fc gamma R+ cells were mixed with constant numbers of the FcR- cells. At 24 hr, supernates were collected and tested for GF activity. The Fc gamma R+ suppressor cells efficiently and in a dose-dependent fashion blocked GF production or release. The GF was nondialyzable and relatively heat stable. Supernates with GF activity also had colony-stimulating factor activity, but were negative in assays modified from murine interleukin 1 (IL-1) and IL-2 assays. Regulation of GF production or release represents a new function for bone marrow suppressor cells.     

Splenic NK1.1-negative, TCR alpha beta intermediate CD4+ T cells exist in naive NK1.1 allelic positive and negative mice, with the capacity to rapidly secrete large amounts of IL-4 and IFN-gamma upon primary TCR stimulation

Splenic NK1.1+CD4+ T cells that express intermediate levels of TCR alpha beta molecules (TCRint) and the DX5 Ag (believed to identify an equivalent population in NK1.1 allelic negative mice) possess the ability to rapidly produce high quantities of immunomodulatory cytokines, notably IL-4 and IFN-gamma, upon primary TCR activation in vivo. Indeed, only T cells expressing the NK1.1 Ag appear to be capable of this function. In this study, we demonstrate that splenic NK1.1-negative TCRintCD4+ T cells, identified on the basis of Fc gamma R expression, exist in naive NK1.1 allelic positive (C57BL/6) and negative (C3H/HeN) mice with the capacity to produce large amounts of IL-4 and IFN-gamma after only 8 h of primary CD3 stimulation in vitro. Furthermore, a comparison of the amounts of early cytokines produced by Fc gamma R+CD4+TCRint T cells with NK1. 1+CD4+ or DX5+CD4+TCRint T cells, simultaneously isolated from C57BL/6 or C3H/HeN mice, revealed strain and population differences. Thus, Fc gamma R defines another subpopulation of splenic CD4+TCRint cells that can rapidly produce large concentrations of immunomodulatory cytokines, suggesting that CD4+TCRint T cells themselves may represent a unique family of immunoregulatory CD4+ T cells whose members include Fc gamma R+CD4+ and NK1.1/DX5+CD4+ T cells.     

Isolation, characterization, and expression of cDNA clones encoding the mouse Fc receptor for IgE (Fc epsilon RII)1

We have isolated cDNA clones encoding a mouse low affinity receptor for IgE (Fc epsilon RII) from a cDNA library of BALB/c splenic B cells activated with LPS and IL-4. The 2.2-kb cDNA clone encodes a 331 amino acid membrane glycoprotein that is homologous to human Fc epsilon RII (CD23) and a family of carbohydrate-binding proteins. COS7 cells transfected with the cDNA clones expressed a 45,000 m.w. protein that bound IgE and the anti-Fc epsilon RII mAb, B3B4. Fc epsilon RII mRNA was up-regulated in mouse B cells by culture with IL-4, but not in B cells cultured with IgE. Fc epsilon RII mRNA was detected in IgM+/IgD+ B cell lines, but not in pre-B cell lines or in B cell lines which have undergone differentiation to secrete Ig. The monocyte line P388D1, mast cell lines MC/9 and PT18, and peritoneal macrophages stimulated with IL-4 lacked detectable Fc epsilon RII mRNA, as did Thy-1.2+, CD4+, and CD8+ normal T cells and Thy-1.2+ T cells from Nippostrongylus brasiliensis-infected mice.     

Systemic, but not intestinal, IL-7 is essential for the persistence of chronic colitis

We previously demonstrated that IL-7 is produced by intestinal goblet cells and is essential for the persistence of colitis. It is well known, however, that goblet cells are decreased or depleted in the chronically inflamed mucosa of animal colitis models or human inflammatory bowel diseases. Thus, in this study, we assess whether intestinal IL-7 is surely required for the persistence of colitis using a RAG-1/2-/- colitis model induced by the adoptive transfer of CD4+CD45RBhigh T cells in combination with parabiosis system. Surprisingly, both IL-7-/-xRAG-1-/- and IL-7+/+xRAG-1-/- host mice developed colitis 4 wk after parabiosis to a similar extent of colitic IL-7+/+xRAG-1-/- donor mice that were previously transferred with CD4+CD45RBhigh T cells. Of note, although the number of CD4+ T cells recovered from the spleen or the bone marrow of IL-7-/-xRAG-1-/- host mice was significantly decreased compared with that of IL-7+/+xRAG-1-/- host mice, an equivalent number of CD4+ T cells was recovered from the lamina propria of both mice, indicating that the expansion of CD4+ T cells in the spleen or in the bone marrow is dependent on IL-7, but not in the lamina propria. Development of colitis was never observed in parabionts between IL-7+/+xRAG-1-/- host and noncolitic IL-7-/-xRAG-1-/- donor mice that were transferred with CD4+CD45RBhigh T cells. Collectively, systemic, but not intestinal, IL-7 is essential for the persistence of colitis, suggesting that therapeutic approaches targeting the systemic IL-7/IL-7R signaling pathway may be feasible in the treatment of inflammatory bowel diseases.     

Expression of B cell surface receptors. II. IL-4 can accelerate the developmental expression of the murine B cell IgE Fc receptor

The ability of IL-4 to influence the developmental expression of the murine B cell IgE Fc receptor (Fc epsilon R) was examined. Spleen cells from neonatal mice of increasing age were incubated overnight with IL-4 and subsequently examined with multicolor flow cytometry. The results demonstrate that IL-4 can significantly increase the number of maturing B cells which express the Fc epsilon R. This effect was only seen however, on those neonatal B cells which already displayed surface IgD. Splenic B cells which were IgM+, IgD- failed to express the Fc epsilon R when treated with IL-4, even though they responded by increasing their level of class II Ag expression. Further experiments showed that the inability of IgD- immature B cells to express the Fc epsilon R could not be entirely explained by their assignment to the Ly-1 lineage. Taken together, these results indicate that IL-4 can accelerate the developmental expression of the B cell Fc epsilon R, but only on those B cells that are mature enough to express IgD.     

Influence of recombinant IL-4, IFN-alpha, and IFN-gamma on the production of human IgE-binding factor (soluble CD23)

This study documents the influence of rIL-4, IFN-gamma, and IFN-alpha on the production of IgE-BF and the expression of lymphocyte receptor for IgE or CD23 Ag (Fc epsilon R II) by human mononuclear cells. IL-4 increases the secretion of IgE-binding factor (BF) by highly purified B lymphocytes, adherent cells, and U937 monoblastic cells. The effect of IL-4 on purified B cells is augmented by costimulating the cells with F(ab')2 anti-IgM. IFN-gamma, IL-2, IL-1-alpha, or IL-1 beta and the low m.w. B cell growth factor have no effect on IgE-BF production by purified B cells even when they are used in combination with anti-IgM. Stimulation of purified T cells with IL-4 or IL-4 plus PMA leads to the production of very small amounts of IgE-BF that might well be derived from the contaminating non-T cells. IFN-gamma increases IgE-BF synthesis by unfractionated PBMC, T cell-depleted PBMC, adherent cells, and U937 cells suggesting that it induces monocytes to release IgE-BF, IFN-gamma suppresses the IL-4-induced Fc epsilon R II expression and IgE-BF production by highly purified B cells but not by PBMC or their T cell-depleted fractions. IFN-alpha inhibits IgE-BF production by IFN-gamma-stimulated PBMC and by IL-4-stimulated cells suggesting that it exerts its effect on B cells and on monocytes. Moreover IFN-alpha suppresses the IL-4-induced expression of Fc epsilon R II on B cells. Both IFN-alpha and IFN-gamma suppress the synthesis of IgE by PBMC in response to IL-4. Taken collectively the results indicate that: 1) IL-4 induces IgE-BF production by both B cells and monocytes, 2) IFN-gamma stimulates IgE-BF synthesis by monocytes but suppresses its production by IL-4-stimulated B cells, and finally 3) IFN-alpha inhibits IgE-BF synthesis in response to either IFN-gamma or IL-4.     

Basophils support the survival of plasma cells in mice

We have previously shown that basophils support humoral memory immune responses by increasing B cell proliferation and Ig production as well as inducing a Th2 and B helper phenotype in T cells. Based on the high frequency of basophils in spleen and bone marrow, in this study we investigated whether basophils also support plasma cell survival and Ig production. In the absence of basophils, plasma cells of naive or immunized mice rapidly undergo apoptosis in vitro and produce only low amounts of Igs. In contrast, in the presence of basophils and even more in the presence of activated basophils, the survival of plasma cells is markedly increased and continuous production of Igs enabled. This effect is partially dependent on IL-4 and IL-6 released from basophils. Similar results were obtained when total bone marrow cells or bone marrow cells depleted of basophils were cultured in the presence or absence of substances activating basophils. When basophils were depleted in vivo 6 mo after immunization with an Ag, specific Ig production in subsequent bone marrow cultures was significantly reduced. In addition, depletion of basophils for 18 d in naive mice significantly reduced the number of plasma cells in the spleen. These data indicate that basophils are important for survival of plasma cells in vitro and in vivo.     

Mice infected with Schistosoma mansoni develop a novel non-T-lymphocyte suppressor population which inhibits virus-specific CTL induction via a soluble factor.

We previously observed that Schistosoma mansoni-infected mice were deficient in their ability to mount a CTL response to unrelated viral antigens and to clear a vaccinia viral infection. Here, we explore the mechanism of that deficiency. Mixing experiments showed that splenocytes from S. mansoni-infected mice actively suppress stimulation in vitro of both viral-peptide specific CTL in spleen cells from virus-infected mice, and allospecific CTL. The mechanism of suppression involves at least in part a soluble factor, in that it can occur across a 0.4-microm membrane which prohibits direct cell contact. However, the inhibition is not alleviated by blocking with antibodies to IL-4, IL-10 or TGF-beta. Fractionation of the splenocyte population from S. mansoni-infected mice shows that the suppression is mediated by a non-B, non-T cell that expresses CD16 and Mac-1, but not FcepsilonR or NK1.1. This represents a novel suppressor population that is distinct from the FcepsilonRI(+) populations of non-B, non-T cells in the spleens of S. mansoni-infected mice that provide a major source of IL-4 in these animals. Similar cells in schistosome-infected humans could affect susceptibility to other infections or responsiveness to vaccines.     

Administration of IL-7 to mice with cyclophosphamide-induced lymphopenia accelerates lymphocyte repopulation

Lymphopenia was induced in mice by a single injection of cyclophosphamide. IL-7 or a control protein were administered to the mice twice daily and the cellularity and composition of the spleen, lymph node, bone marrow, and thymus were determined at various time points thereafter. In comparison to the control cyclophosphamide-treated mice, animals receiving cyclophosphamide and IL-7 had an accelerated regeneration of splenic and lymph node cellularity. There was no significant difference in the rate of recovery of the bone marrow and thymus of the control and IL-7-treated mice. Assessment of the pre-B cell compartment revealed a dramatic increase in total pre-B cell numbers in the spleen and bone marrow of the IL-7-treated mice as measured by both flow microfluorimetry and a pre-B cell colony-forming assay. This was followed in a few days by a significant increase in surface IgM+B cell numbers to levels above normal values in both the spleen and lymph node. IL-7 administration to cyclophosphamide-treated mice also resulted in an accelerated recovery of peripheral CD4+ and CD8+ cell numbers in the spleen and lymph node. The numbers of CD8+ cells were increased by twofold over normal levels in cyclophosphamide-treated mice receiving IL-7. Myeloid recovery was determined in cyclophosphamide treated mice by assessing the numbers of CFU-granulocyte-macrophage and Mac 1+ cells. There was no significant difference in myeloid recovery between cyclophosphamide-treated mice receiving IL-7 or control protein. These results suggest that administration of IL-7 after chemical-induced lymphopenia may have therapeutic benefits in shortening the period required to achieve normal lymphoid cellularity.     

IL-6 augments Fc IgE receptor (Fc epsilon RII/CD23) expression on human monoblastic/monocytic cell lines U937, THP-1, and Mono-Mac-6 but not on blood monocytes. Regulatory effects of IL-4 and IFN-gamma.

Human monoblastic/monocytic leukemia cell lines U937, THP-1, Mono-Mac-6, and blood monocytes were incubated with various concentrations of human rIL-6 and other cytokines and analyzed for their capacity to bind several anti-Fc epsilon RII/CD23 mAb. A marked and dose-dependent increase in the percentage of CD23+ cells, as well as in the mean channel fluorescence intensity, as demonstrated by FACS analysis, was noted after 8- to 72-h incubation of U937 cells with 1 to 1000 U/ml of human rIL-6. Furthermore, rIL-4 synergized with rIL-6 and rIFN-tau in augmenting the Fc epsilon RII expression on U937 cells, whereas rIFN-tau and rIL-6 showed rather additive effects. The enhancement of CD23 expression on IL-6-treated U937 cells was blocked by anti-IL-6 antibodies. Northern blot analysis, employing cDNA probes for Fc epsilon RII, showed that U937 cells contain Fc epsilon RII-specific mRNA. The level of Fc epsilon RII-encoding mRNA was evidently increased by treatment of U937 cells with human rIL-6, rIL-4, or with rIL-6 + rIL-4. The expression of CD23 on THP-1 and Mono-Mac-6 cells was increased slightly by rIL-6 and markedly by rIL-4, rIFN-tau, or a mixture of them. Approximately 14% of blood monocytes, isolated from apparently healthy donors, constitutively possess Fc epsilon RII. In contrast to the cell lines, the Fc epsilon RII density and the percentage of blood monocytes bearing Fc epsilon RII was not augmented by IL-6. Furthermore, rIL-6, and more evidently rIFN-tau, down-regulate rIL-4-driven Fc epsilon RII expression on monocytes but not on monocytic cell lines. Our findings point to differences in the capability of mononuclear phagocytes to respond to cytokine treatment, which may be differentiation dependent, and suggest separate regulatory pathways.     

Long-lived lymphocytes include lipopolysaccharide-reactive B cells

We have used a new protocol of prolonged in vivo hydroxyurea (HU) administration which eliminates all cycling and short-lived cells. This treatment kills 99% of non-B non-T bone marrow cells, and it leaves in spleen and bone marrow "long-lived" B- and T-cell populations which represent 33 and 59%, respectively, of the total numbers of lymphocytes found in untreated controls. The relative proportions of B and T cells in spleen or blood of HU-treated mice were practically unaffected, while an increased blood-to-marrow permeability results in markedly abnormal proportions of B and T lymphocytes in bone marrow. Mitogen reactivities of these long-lived lymphocytes recovered either in spleen or bone marrow of HU-treated animals were studied. The results show that such B cells respond perfectly well to the B-cell mitogen lipopolysaccharide, by proliferation and differentiation into Ig-secreting cells, and that T cells proliferate at nearly control levels in response to concanavalin A. This protocol of long-term HU treatment offers the possibility of studying selected long-lived lymphocyte populations, the clonal repertoires and functional properties of which can now be readily approached.     

Thymus-dependent in vivo suppression of IgE synthesis in a murine IgE-secreting hybridoma

In previous studies we demonstrated that BALB/c mice bearing ascitic tumors of the IgE-secreting hybridoma B53 (epsilon, kappa, anti-dinitrophenyl) developed large numbers of Lyt-1-2+ Fc epsilon R(+) T lymphocytes (T cells with membrane Fc receptors) in response to the elevated serum IgE concentration. The development of Fc epsilon R(+) T lymphocytes was followed by a progressive decrease in the levels of serum IgE in spite of continued proliferation of the hybridoma cells. This sequence of events suggested that the IgE-secreting hybridoma triggered a suppressive immunoregulatory circuit of the host that inhibited IgE expression by the hybridoma cells. The present studies were undertaken to investigate the basis for the subsequent decline in serum IgE levels in mice with B53 tumors and to identify host factors that might be involved in this process. We observed that ascitic B53 cells recovered at increasing time points from BALB/c mice exhibited a selective decline in steady state levels and rates of synthesis of epsilon-heavy chain protein and mRNA. The expression of kappa-light chain protein and mRNA appeared relatively unchanged. The decrease in epsilon-heavy chain gene expression did not occur when B53 tumors were passaged in nu+/nu+ mice or in BALB/c mice depleted of Lyt-2+ cells (suppressor/cytotoxic cell lineage), but did occur in nu+/nu+ mice reconstituted with neonatal BALB/c thymus and in BALB/c mice depleted of L3T4+ cells (helper/inducer cell lineage). That Fc epsilon R(+) T lymphocytes were directly involved in the inhibition of IgE expression was supported by the earlier and more pronounced inhibition of B53 IgE in mice infused with Fc epsilon R(+) T lymphocytes. We conclude from these findings that: 1) the decline in serum IgE levels that occurs toward the end of each generation of in vivo passage of the B53 hybridoma is due to decreased production of IgE by the hybridoma cells, 2) the decreased production of IgE is due to a selective loss of epsilon mRNA expression, 3) the decrease production of IgE by B53 cells is dependent on the presence of Lyt-2+ cells, and 4) Fc epsilon R(+) T lymphocytes participate in the mechanism by which IgE production is suppressed.