T cell regulation of interferon-alpha/beta (IFN-alpha/beta) production by alloantigen-stimulated bone marrow cells

We have previously reported that mouse bone marrow cells produce high levels of interferon-alpha/beta (IFN-alpha/beta) after 5 to 6 days of in vitro culture with irradiated allogenic spleen cells. The current study was initiated to determine whether or not T cells are important for alloantigen-induced IFN-alpha/beta production by mouse bone marrow cells. Bone marrow cells and spleen cells were obtained from C57BL/6 mice. These cells were treated with different monoclonal antisera and complement, and then were cultured 5 to 6 days with irradiated DBA spleen cells. The results from these experiments indicated that optimal IFN-alpha/beta production by alloantigen-stimulated bone marrow cells required Lyt-1+2+ T cells. In addition, when bone marrow cells obtained from nu/nu B10 mice were cultured with alloantigen, only low levels of IFN were produced when compared with IFN production by bone marrow cells obtained from normal littermate B10 mice. The addition of nylon wool-enriched splenic T cells to cultures containing bone marrow cells and alloantigen resulted in an augmentation of IFN-alpha/beta production by three-fold to fivefold. Furthermore, bone marrow cells obtained from alloantigen-immunized mice produced much higher levels of IFN-alpha/beta and in a shorter period of time (2 to 3 days) when compared with bone marrow cells obtained from control or non-immunized mice. Cyclosporin A (CsA) has been shown to inhibit predominantly T cell-dependent responses. The effect of CsA on IFN production by alloantigen-stimulated bone marrow and spleen cells was investigated. The addition of CsA at concentrations as low as 0.1 micrograms/ml inhibited not only IFN-gamma production by alloantigen-stimulated spleen cells, but also IFN-alpha/beta production by alloantigen-stimulated bone marrow cells. In contrast, IFN-alpha/beta production by Newcastle disease virus-infected spleen cells, bone marrow cells, or L cells was not inhibited by the addition of CsA (1 microgram/ml). Thus, the ability of bone marrow cells to produce high levels of IFN-alpha/beta after in vitro culture with alloantigen is dependent upon T cells resident in the bone marrow. IFN-alpha/beta production by alloantigen-stimulated bone marrow cells may play a major role in the pathogenesis associated with graft-vs-host disease and in T cell regulation of hematopoiesis.     

Interleukin 2 induces interferon alpha/beta production in mouse bone marrow cells

We have previously reported that mouse bone marrow (BM) cells stimulated with alloantigen produce cytotoxic effector T-cell activity and produce interferon (IFN-)alpha/beta. In this report we show evidence suggesting that interleukin 2 (IL-2) may play a role in this IFN-alpha/beta production by alloantigen-stimulated BM cells. Alloantigen-induced IFN production by bone marrow cells was completely inhibited when cultures were supplemented with antisera to IL-2. Cell-free supernatants obtained at 2 days from cultures containing C57BL/6 BM cells and irradiated DBA/2J spleen cells were also shown to contain low levels of IL-2 activity and induced significant IFN production in fresh BM cells. Different IL-2 preparations were tested for their ability to induce IFN-alpha/beta production in mouse BM cells. Mouse BM cells cultured with recombinant human IL-2 or highly purified mouse IL-2 produced high levels of IFN-alpha/beta activity after 2-3 days of culture with significant IFN activity being detected as early as 24 hr of culture. IL-2-induced IFN-alpha/beta production was partially resistant to irradiation. In contrast, irradiated (2000 rad) bone marrow cells failed to produce any IFN when cultured with alloantigen in the absence of IL-2. T-cell-depleted BM cells or BM cells obtained from C57BL/10 nude mice produced high levels of IFN-alpha/beta following stimulation with IL-2. In addition, bone marrow cells depleted of Ia+, Qa 5+, or Asialo GM+1 cells produced IFN in response to IL-2. Thus, neither T cells nor NK cells are required for IL-2-induced IFN-alpha/beta production by BM cells. The action of IL-2 on bone marrow cells to induce IFN production was mediated by the classical IL-2 receptor, since monoclonal antibodies to the IL-2 receptor present on T cells blocked this response and since bone marrow cells depleted of IL-2 receptor-bearing cells failed to produce IFN when cultured with IL-2. These results suggest that non-T cells resident in the BM have receptors for IL-2 and can produce IFN-alpha/beta upon stimulation by IL-2. Since IFN has been shown to affect different aspects of hematopoiesis, the production of IFN by BM cells stimulated by IL-2 may be important in the control of hematopoiesis. In addition, IL-2-induced IFN production may play a role in graft-versus-host disease.     

Alteration of allospecific t-cell receptors after differentiation from prethymic precursor cells in semiallogeneic environments

Murine bone marrow cells (strain A) have been allowed to differentiate in vivo in syngeneic (A) or semiallogeneic hosts (A × B) to produce mature splenic T lymphocytes. After stimulation of these cells with irradiated allogeneic (C) spleen cells in tissue cultures, the cytotoxic T-cell blasts (CTL) were purified by velocity sedimentation and used to immunize (A × C) F₁ hybrid mice, to produce antisera recognizing the receptor structure (for C) on the relevant A cytotoxic cells (and their precursors). Using these sera we have been able to show that the T-cell receptor for alloantigen C on strain A cytotoxic precursor lymphocytes (CTLp) seems to differ according to the host environment in which those T cells differentiate from immature bone marrow precursors.     

BP-3 alloantigen. A cell surface glycoprotein that marks early B lineage cells and mature myeloid lineage cells in mice

To explore the cell surface molecules expressed on pre-B cells we have produced a panel of alloantibodies against transformed pre-B cells from BALB/c mice by immunizing a wild mouse, Mus spretus. One of these antibodies, BP-3, recognized glycoproteins of Mr 38,000 to 48,000 on pre-B cells transformed either by the Abelson murine leukemia virus or an erb B oncogene construct. Removal of N-linked oligosaccharides from the BP-3 Ag revealed a single core protein of Mr 32,000. The Ag was expressed by bone marrow cells in all but one (A/J) of the inbred mouse strains tested and in wild mice of biochemical groups Mus-1 and Mus-2. Analysis of the tissue distribution revealed expression of the BP-3 reactive molecule on normal pre-B and B cells in the bone marrow, 35% of B cells in the circulation, 30% of the B cells in the spleen, and less than or equal to 20% of B cells in lymph nodes, peritoneal cavity, and Peyer's patches. The subpopulation of BP-3+ B cells in bone marrow and peripheral tissues displayed an immature phenotype (IgM IgD +/- ). Examination of a panel of transformed B lineage cells confirmed the early stage-specific expression of the BP-3 alloantigen. In addition, a myeloid cell line and normal myeloid cells were found to express the BP-3 alloantigen. In contrast to B lineage cells, the level of BP-3 expression increased as a function of myeloid cell differentiation. Myeloid cells in the bone marrow expressed relatively little Ag, whereas circulating neutrophils and peritoneal macrophages expressed relatively high levels of the BP-3 alloantigen with Mr 38,000, 41,000, and 46,000. The data suggest that this variably glycosylated cell surface protein could play different roles in the differentiation of B lineage and myeloid lineage cells. The BP-3 alloantigen appears to be a useful marker for virgin B cells that have recently migrated from the bone marrow to the periphery.     

Identification of a histamine release inhibitory factor (HRIF) and an inhibitor of histamine releasing factor synthesis (IHS) produced by guinea pig lymphoid cells

Guinea pig spleen cells, thymocytes, and blood mononuclear cells have been shown to produce a histamine releasing factor (HRF) spontaneously or after stimulation with PHA or specific antigens. In this study we have shown that antigenic stimulation of spleen cells obtained from animals immunized with high doses of antigen suppresses the spontaneous HRF production. Likewise, stimulation with Con A of spleen cells also inhibits the spontaneous HRF production. When the supernatants from Con A- and antigen-stimulated cultures were added to fresh thymocyte cultures, a significant inhibition of HRF production was observed. These supernatants also inhibited HRF-induced histamine release from mast cells. We have identified an inhibitor of HRF synthesis (IHS) and also a histamine release inhibitory factor (HRIF) by gel chromatography. Virtually all mitogen- and antigen-stimulated culture supernatants elaborated the activities of HRF, IHS, and HRIF in various quantities depending on the dose of antigen and the kind of adjuvant used for immunization. IHS has a MW of 22K-35K and 10K. This cytokine also inhibits DNA synthesis by thymocytes. HRIF has a MW of 15K-20K and 10K. It inhibits both HRF- and antigen-induced histamine release from lung mast cells. These results suggest that lymphocytes produce a variety of factors which function to regulate histamine release from mast cells.     

Purified Fc epsilon R+ bone marrow and splenic non-B, non-T cells are highly enriched in the capacity to produce IL-4 in response to immobilized IgE, IgG2a, or ionomycin.

Non-B, non-T cells from spleen and bone marrow cells produce IL-4 in response to cross-linkage of high affinity receptors for Fc epsilon R or Fc gamma RII, and to treatment with calcium ionophores. Cells bearing high affinity Fc epsilon R constituted 1 to 2% of non-B, non-T cells of spleen and of total bone marrow cells from naive donors. In mice whose immune systems had been polyclonally activated by injection with anti-IgD antibodies or had been infected with Nippostrongylus brasiliensis larvae, the frequency of Fc epsilon R+ cells in splenic non-B, non-T cells was also 1 to 2% but in bone marrow from anti-IgD-injected mice donors the frequency was approximately 5%. Cell sorting experiments revealed that all of the capacity to produce IL-4 in response to immobilized IgE or IgG2a or to ionomycin was found in the Fc epsilon R+ fraction. Among the Fc epsilon R+ spleen cells from naive donors, the frequency of IL-4-producing cells was 1/20 to 1/40 whereas in mice that had been injected with anti-IgD or infected with N. brasiliensis, the frequency of IL-4 producing cells in the Fc epsilon R+ population was approximately 1/5.     

Migration and differentiation of bone marrow lymphocytes: development of surface immunoglobulin, Fc receptor, complement receptor, and functional responsiveness as studied with anti-allotype serum

Immunofluorescent studies using fluorescein isothiocyanate-conjugated mouse anti-allotype antibody were carried out to study the migration pattern and the development of surface Ig (SIg), Fc receptor for IgG (FcR gamma), and complement receptor (CR) or mouse bone marrow lymphocytes following intravenous injection into congenic mice. After transfer of bone marrow cells from CSW mice into untreated congenic CWB mice, the absolute number of donor-type SIg-bearing (SIg+) cells and the proportion of either FcR gamma- or CR-bearing (FcR gamma+ or CR+) cells in donor-type SIg+ cells were evaluated in the recipient spleen and the results were compared with those obtained after the transfer of CSW spleen cells. After injection of donor bone marrow cells, detectable donor-type SIg+ cells, although few initially, increased from day 1 to Day 2 and reached a plateau thereafter. The proportion of FcR gamma+ cells in donor-type SIg+ cells, although very low in the donor marrow inoculum, increased progressively after 1 day to reach a maximum at Day 5 (90%). On the other hand, following the transfer of spleen cells, the proportion of FcR gamma+ cells remained at high levels (90%) for 5 days after transfer. Likewise, the proportion of CR+ cells in donor-type SIg+ cells was very low (less than 1%) in the original donor bone marrow cells but high (60%) in the donor spleen cells. However, in transferring bone marrow cells this proportion also increased in the recipient spleen to reach a maximum (49%) at Day 5 although it was lower compared to the percentage of FcR gamma+ cells in donor SIg+ cells. Furthermore, the ability of functional responsiveness to antigen was also examined in the same system by detecting plaque-forming cells (PFC) from donor origin. In transferring donor bone marrow cells into recipient, the participation of donor cells in the PFC response was very low when the recipients were primed with sheep red blood cells at Day 3 after transfer. However, when the recipients were primed at Days 7 to 21 after transfer, increasing numbers of the donor marrow-derived cells were involved in the PFC response. Thus, the present study demonstrates that the bone marrow-derived lymphocytes, albeit lacking both distinctive surface receptors (IgM, FcR gamma, CR) and the functional responsiveness to antigen, continue their development along the B-cell lineage after migrating into the spleen, as evidenced by the surface receptor expression and participation in the antibody response.     

Comparison of allogeneic and self-restricted stimulation of lymphokine production by dual-reactive cloned T cells

Murine T cell clones were derived that proliferated in response to stimulation by alloantigen or by ovalbumin (OVA) in the presence of irradiated syngeneic spleen cells. Two cloned cell lines of strain B10.BR (H-2k) proliferated in response to alloantigen encoded by I-Ab, whereas the response to OVA was restricted by an element encoded by I-Ak. A cloned cell line of strain B10.A (H-2a) proliferated in response to alloantigen encoded by I-As, whereas the response to OVA was restricted by an element encoded by I-Ak. Cloned cells were stimulated by alloantigen or by OVA to produce lymphokines and to incorporate thymidine. Culture supernatants were collected 24 hr later and were assayed for interleukin 2, colony stimulating factor, interferon, Ia-inducing activity, and interleukin 3; thymidine incorporation was measured 72 hr after stimulation. For each clone tested, stimulation by alloantigen or by OVA led to the production of an identical array of lymphokines. Likewise, the strength of stimulation by alloantigen was approximately equal in magnitude to the strength of stimulation by a particular concentration of OVA. Lymphokine production and thymidine incorporation were co-variant measures of the intensity of stimulation. These data, in combination with data linking OVA reactivity and alloreactivity to identical regions of the major histocompatibility complex, suggest that dual reactivity represents a cross-reaction between alloantigen and self determinants associated with nominal antigen.     

Effect of hydrocortisone and bacterial lipopolysaccharide on colony-stimulating activity production from mouse marrow adherent cells, spleen cells and peritoneal macrophages in vitro

The effect of hydrocortisone (HC) on colony-stimulating activity (CSA) production from mouse bone marrow adherent cells, spleen cells and peritoneal macrophages with or without bacterial lipopolysaccharide (LPS) stimulation was studied. CSA in the supernatant from bone marrow adherent cells incubated with HC was found to be five times higher than CSA from cultures without LPS stimulation. In contrast, the CSA production by spleen cells and peritoneal macrophages were significantly suppressed by HC in both LPS-stimulated and non-stimulated cultures. These studies suggest that the effect of HC on CSA production was quite different depending on the target cells.     

LOCAL AND SYSTEMIC CONTROL OF GRANULOCYTIC AND MACROPHAGE PROGENITOR CELL REGENERATION AFTER IRRADIATION

Agar cultures of C₅₇BL bone marrow cells were used to determine colony stimulating factor (CSF) and serum CSF-inhibitor levels in C₅₇BL and BALB/c mice following irradiation. Whole-body irradiation caused an acute, dose-dependent, rise in serum CSF levels and fall in CSF-inhibitor levels. The regeneration of granulocytic and macrophage progenitor cells ( in vitro CFCs) in the femur after 250 rads whole-body irradiation was preceded or paralleled by a fall in serum CSF-inhibitors and a dramatic rise in the capacity of bone-adherent cells in the marrow ('stromal cells') to produce material with colony-stimulating activity. No comparable changes were observed in the activity of marrow haemopoietic cells during regeneration or in the lungs or spleen. A similar rise in the activity of bone-adherent cells was observed in shielded femurs during regeneration of in vitro CFCs.
Regeneration of granulocytic and macrophage progenitor cells following irradiation may be regulated by fluctuations in circulating CSF-inhibitor levels and local production of CSF within the marrow cavity.     

Skin allografts generate an enhanced production of histamine and histamine-producing cell-stimulating factor (HCSF) by spleen cells in response to T cell mitogens

In response to T cell mitogens, spleen cells produce a large amount of histamine, whereas no or a slight increase is observed after B cell mitogen stimulation. This increased histamine production results from the effect of a factor having all the characteristics of HCSF (histamine-producing cell-stimulating factor) already described in secondary MLC supernatant. This factor is produced by Thy-1, 2, Lyt-1, 2-positive cells. Spleen cell cultures derived from skin-allografted mice during rejection produce more histamine in response to T cell mitogens than do spleen cells from normal or syngeneic grafted mice. Such a phenomenon is not observed in response to B cell mitogens. A striking association is found between enhanced histamine synthesis and skin allograft rejection. This phenomenon results from a) a five to 10-fold increase in HCSF production by allograft recipient spleen cells in response to T cell mitogens, and b) an increase in HCSF sensitivity of these spleen cells.     

Antibody formation and B-cell migration from bone marrow to spleen in mice under conditions of stimulation and suppression of erythropoiesis]

The effect of erythropoietic stimulation and suppression on the production of antibody-forming cells (AFC) in the spleen and on the B-cell migration from the bone marrow to the spleen was investigated in the CBA mice. Erythropoiesis stimulation proved to sharply increase the AFC count in the spleen and the B-cell migration from the bone marrow to the spleen 1 and 4 days after the bleeding. Erythropoiesis suppression resulted in a slight increase of the AFC count in the spleen 4 and 7 days after the transfusion of syngeneic red blood cells. However, the erythropoietic suppression inhibited the B-cell migration from the bone marrow to the spleen. Possible mechanisms of the effect of the erythropoietic stimulation and suppression on the antibody production are discussed.     

Characterization of cytotoxic cells generated from in vitro cultures of murine bone marrow cells

Bone marrow cells cultured for 5-6 days generate cytotoxic activity against a number of natural killer (NK)-susceptible tumor cells. In this study, these bone marrow cytotoxic cells were compared to cells with NK activity obtained either from spleen cells activated in vitro with interferon (IFN-alpha/beta) or mitogen or from peritoneal exudate cells (PEC) obtained 4 days after bacillus Calmette-Guerin (BCG) infection. Splenic and PEC cytotoxic cells were shown to be Thy 1.2+, NK 1.1+, Asialo GM+1, Lyt 1.2-, Lyt 2.2-. In contrast, bone marrow cytotoxic cells were Thy 1.2+, NK 1.1-, Lyt 1.2-, Lyt 2.2- and expressed low levels of Asialo GM1 antigen (Asialo GM +/- 1). Precursor cells for bone marrow cytotoxic activity were shown to be Thy 1.2-, NK 1.1-, Lyt 1.2-, Lyt 2.2- but also expressed low levels of Asialo GM1 antigen (Asialo GM +/- 1). Cytotoxic activity for both bone marrow and spleen cells peaked in the low-density fractions of discontinuous Percoll density gradients. The cytotoxic activity of these bone marrow cells was augmented by pretreatment with IFN (-alpha/beta, -gamma) or soluble factors (IFN free) from activated EL-4 thymoma cells. Surprisingly, the ability of bone marrow cells to generate high levels of cytotoxic activity following in vitro culture appeared to be associated primarily with mice which were of the H-2b haplotype.     

Inhibition by dexamethasone of histamine production in allergic inflammation in rats.

In an allergic inflammation model of air pouch type in rats, histamine level in the pouch fluid and histidine decarboxylase activity of pouch wall tissues in the postanaphylaxis phase were increased. Although treatment with dexamethasone failed to inhibit histamine release from mast cells in the anaphylaxis phase, histamine production in the postanaphylaxis phase was inhibited dose dependently. Histamine production-increasing activity in the pouch fluid collected 8 h after the Ag challenge, which was estimated by an activity to stimulate histamine production by bone marrow cells, was decreased by the administration of dexamethasone at the time of the Ag challenge. The addition of steroidal antiinflammatory drugs, dexamethasone, prednisolone, or hydrocortisone, into the incubation medium inhibited the pouch fluid-induced histamine production by bone marrow cells. Hydrocortisone mesylate antagonized the inhibitory effect of dexamethasone on histamine production by bone marrow cells. However, hydrocortisone mesylate failed to recover the decrease in histamine production-increasing activity of the pouch fluid collected from dexamethasone-treated rats. In addition, the dialyzed sample of pouch fluid obtained from dexamethasone-treated nonsensitized rats did not reduce the stimulated histamine production by the pouch fluid sample obtained from the sensitized rats. However, increase in histamine production of bone marrow cells stimulated by the pouch fluid was not inhibited by cyclosporin A that inhibited histamine production induced by Con A. This observation indicates that the pouch fluid has no effect to induce production of the histamine production-increasing factor by bone marrow cells. Consequently, it is suggested that dexamethasone inhibits not only the production of histamine production-increasing factor but also the response of histamine-producing cells to this factor.     

Enhanced expression of mRNA for nuclear factor kappaB1 (p50) in CD34+ cells of the bone marrow in rheumatoid arthritis

Bone marrow CD34+ cells from rheumatoid arthritis (RA) patients have abnormal capacities to respond to tumor necrosis factor (TNF)-alpha and to differentiate into fibroblast-like cells producing matrix metalloproteinase (MMP)-1. We explored the expression of mRNA for nuclear factor (NF)kappaB in RA bone marrow CD34+ cells to delineate the mechanism for their abnormal responses to TNF-alpha. CD34+ cells were purified from bone marrow samples obtained from 49 RA patients and 31 osteoarthritis (OA) patients during joint operations via aspiration from the iliac crest. The mRNAs for NFkappaB1 (p50), NFkappaB2 (p52) and RelA (p65) were examined by quantitative RT-PCR. The expression of NFkappaB1 mRNA in bone marrow CD34+ cells was significantly higher in RA than in OA, whereas there was no significant difference in the expression of mRNA for NFkappaB2 and RelA. The expression of NFkappaB1 mRNA was not correlated with serum C-reactive protein or with the treatment with methotrexate or oral steroid. Silencing of NFkappaB1 by small interfering RNA abrogated the capacity of RA bone marrow CD34+ cells to differentiate into fibroblast-like cells and to produce MMP-1 and vascular endothelial growth factor upon stimulation with stem cell factor, granulocyte-macrophage colony stimulating factor and TNF-alpha without influencing their viability and capacity to produce beta2-microglobulin. These results indicate that the enhanced expression of NFkappaB1 mRNA in bone marrow CD34+ cells plays a pivotal role in their abnormal responses to TNF-alpha and, thus, in the pathogenesis of RA.     

Adenovirus-mediated BMP2 expression in human bone marrow stromal cells

Recombinant adenoviral vectors have been shown to be potential new tools for a variety of musculoskeletal defects. Much emphasis in the field of orthopedic research has been placed on developing systems for the production of bone. This study aims to determine the necessary conditions for sustained production of high levels of active bone morphogenetic protein 2 (BMP2) using a recombinant adenovirus type 5 (Ad5BMP2) capable of eliciting BMP2 synthesis upon infection and to evaluate the consequences for osteoprogenitor cells. The results indicate that high levels (144 ng/ml) of BMP2 can be produced in non-osteoprogenitor cells (A549 cell line) by this method and the resultant protein appears to be three times more biologically active than the recombinant protein. Surprisingly, similar levels of BMP2 expression could not be achieved after transduction with Ad5BMP2 of either human bone marrow stromal cells or the mouse bone marrow stromal cell line W20-17. However, human bone marrow stromal cells cultured with 1 microM dexamethasone for four days, or further stimulated to become osteoblast-like cells with 50 microg/ml ascorbic acid, produced high levels of BMP2 upon Ad5BMP2 infection as compared to the undifferentiated cells. The increased production of BMP2 in adenovirus transduced cells following exposure to 1 microM dexamethasone was reduced if the cells were not given 50 microg/ml ascorbic acid. When bone marrow stromal cells were allowed to become confluent in culture prior to differentiation, BMP2 production in response to Ad5BMP2 infection was lost entirely. Furthermore, the increase in BMP2 synthesis seen during differentiation was greatly decreased when Ad5BMP2 was administered prior to dexamethasone treatment. In short, the efficiency of adenovirus mediated expression of BMP2 in bone marrow stromal cells appears to be dependent on the differentiation state of these cells.     

In vitro alloreactivity of mouse bone marrow lymphocytes

Before characterizing alloreactive cells of the bone marrow, it was necessary to reevaluate the alloantigen response in this tissue. The results of previous studies using the parental-F₁ system in the mixed-lymphocyte reaction (MLR) are open to question because of the recently documented proliferation of F₁ stimulator cells (W. H. Adler, T.Takiguchi, B. Marsh, and R. T. Smith,J. Immunol. 105, 984, 1970; P. F. Piguet, H. K. Dewey, and P. Vassalli, J. Exp. Med. 146, 735, 1977). The culture system was optimized for measuring the MLR of bone marrow lymphocytes enriched on sucrose density gradients. The proliferative response of the enriched fraction (BML) to 2000-R irradiated allogeneic spleen cells was three times as high as the response of unfractionated bone marrow. For maximal responses, antigen concentration had to be twice as high for the BML as for the lymph node, and in a time course study the highest [³H]TdR uptake occurred on Day 3 in BML cultures and on Day 5 in the LN. In lymph node semiallogeneic cultures stimulator cell proliferation can be disregarded, while semiallogeneic BML MLR err significantly on the high side. When BML were matched with allogeneic stimulator cells at the H-2 locus, they gave good MLR responses, provided there was a minor Mls histocompatibility locus difference, while in the lymph node the response was greatly diminished in similar mixtures. The differences in the BML and lymph node alloantigen responses with respect to antigen concentration, kinetics and susceptibility to F₁ and Mls stimulation, suggest that the bone marrow alloantigen response is mediated by a cell population that is different than alloresponsive cells in the lymph node.     

Antigen-binding cells in central and peripheral lymphoid tissues of the rabbit

The rosette assay was used to study antigen-binding activity by cells in lymphoid tissues of rabbits immunized with sheep red blood cells and in unimmunized controls. Percentages of rosette-forming cells (RFC) observed were compared with those of cells which secreted antibody (plaque-forming cells, PFC) and cells which both bound antigen and secreted antibody. Rosette-forming cells and PFC were shown to be two distinct reactive cell populations. Thus, in the spleen less than 1% of RFC also formed plaques. Immediately following antigen stimulation, the number of RFC in the bone marrow decreased to below detectable limits. After an initial rise, the number of RFC in the appendix declined similarly. In contrast, RFC levels in the spleen rose steadily from the time of immunization. These patterns suggest that bone marrow and appendix may function as a reservoir of antigen-binding cells which are released to other sites following antigenic stimulation. Rosette-forming cells were rarely observed in the thymus. Rosette-inhibition studies using antisera specific for bone marrow-derived cells (anti-B) and thymus-derived cells (anti-T) revealed a markedly greater proportion of T-RFC in the appendix than in the spleen.     

Interferon gamma priming is not critical for IL-12 production of murine spleen cells

Interferon gamma (IFN-gamma) priming is considered to be critical for interleukin 12 (IL-12) production of murine macrophages and human monocytes by lipopolysaccharide (LPS) stimulation. In our present experiments, freshly prepared spleen cells (f-spleen cells) were confirmed not to produce detectable level of IL-12 by LPS stimulation, although they produced significant amount of IL-12 by the stimulation with LPS plus IFN-gamma. However, the stimulation only with LPS induced IL-12 production of spleen cells preincubated in the absence of IFN-gamma. Findings on IL-12 p40 mRNA accumulation were consistent with their IL-12 production. Essentially the same results were obtained using spleen cells from IFN-gamma deficient mice. In the presence of anti-IL-10, f-spleen cells produced IL-12 upon LPS stimulation, indicating that the failure of f-spleen cells in IL-12 production is caused by IL-10 produced by themselves upon LPS stimulation. In addition, f-spleen cells produced IL-12 upon CD40 ligand stimulation, and the production was hardly affected by the presence of IFN-gamma or preincubation. These results indicate that IFN-gamma priming is not critical for IL-12 production of spleen cells stimulated with LPS or CD40 ligand, although IFN-gamma enhances the production, especially, in response to LPS stimulation.     

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.