Selective production of interleukin 3 (IL3) and granulocyte-macrophage colony-stimulating factor (GM-CSF) in vitro by murine L3T4+ T cells: lack of spontaneous IL3 and GM-CSF production by Ly-2-/L3T4- lpr subset

Murine spleen and lymph node L3T4+ T cells were found to spontaneously produce high levels of interleukin 3 (IL3) and granulocyte-macrophage colony-stimulating factor (GM-CSF) in cultures containing 10% fetal calf serum (FCS) in the absence of other stimulation. The IL3 and GM-CSF activities in culture supernatants peake between the fifth and seventh day of culture. The specificity of the bioassays was attested by the use of rabbit anti-IL3 and anti-GM-CSF antibodies, as well as by the detection of a maximal accumulation of IL3 and GM-CSF mRNA on the fourth day. In contrast, no significant activities of IL2, IL4 or interferon-gamma were detected in these culture supernatants. The markedly limited production of IL3 and GM-CSF in cultures performed in 1% autologous normal mouse serum and the inhibitory effect of anti-Ia or anti-L3T4 monoclonal antibody strongly suggest that the selective production of most, if not all IL3 and GM-CSF by L3T4+ T cells is a result of activation of L3T4+ T cells by fetal calf serum. All the strains of mice tested except athymic nude mice produced substantial amounts of IL3 and GM-CSF during the culture. This is in contrast to a previous report (Palacios, Eur. J. Immunol. 1984. 14: 599), indicating that only spleen cells of the MRL strain homozygous for the lpr gene spontaneously release IL3 in cultures. We found that spleen and lymph node cells from MRL/MpJ-lpr/lpr or C57BL/6J-lpr/lpr mice released, in fact, much less IL3 and GM-CSF in cultures. This was, however, due to the high proportion of the peculiar lpr Ly-2-/L3T4-T cells in spleen and lymph nodes, since after depletion of this lpr T cell subset, lymph node cells from C57BL/6J-lpr/lpr mice produced IL3 and GM-CSF at levels comparable to those in C57BL/6J-+/+ mice. These results further support the notion that the lpr Ly-2-/L3T4- T cell subset is immunologically nonfunctional and its accumulation dilutes functional L3T4+ T cells in mice bearing the lpr mutation.     

Cytotoxic cells induced during lymphocytic choriomeningitis virus infection of mice: natural killer cell activity in cultured spleen leukocytes concomitant with T-cell-dependent immune interferon production

The characteristics and specificities of spleen and peritoneal cytotoxic cells generated during lymphocytic choriomeningitis virus (LCMV) infection of C3H/St mice were examined. Activated natural killer (NK) cell activity was identified in fresh leukocyte populations from the 2nd to 8th days postinfection, whereas virus-specific cytotoxic T-cell activity was detected from the 6th to 14th days. When leukocytes were cultured overnight at 37 degrees C before assay, T-cell activity was still observed, but nonspecific activated NK cell-like cytotoxicity was only detected on the 6th and to a lesser degree the 8th day postinfection. Overnight culture of leukocytes taken earlier in the infection eliminated their NK cell activity. Similar activities were seen with spleen cell, plastic-adherent peritoneal cell, and nonadherent peritoneal cell populations. The virus-specific cytotoxicity observed with adherent peritoneal cells was due to contamination with cytotoxic T cells, as shown by H-2-restricted cytotoxicity and sensitivity to anti-theta antibody and complement. The nonspecific cultured day 6 effector cell from either the spleen or peritoneum displayed killing specificities and other physical properties identical to those of activated NK cells, but had sensitivities to anti-theta antibody and complement intermediate between activated day 3 NK cells and cytotoxic T cells. Culture stable NK-like cells were not found in athymic nude mice, suggesting a T-cell-dependent mechanism. Whereas LCMV spleen homogenates contained 10-fold-higher levels of interferon at day 2 than at day 6 postinfection, substantially more (nearly 20-fold) interferon was made in cultures of day 6 cells than day 2 cells. Spleen interferon was predominantly type I, whereas the culture interferon was predominantly type II, as shown by acid lability studies. Significant levels of interferon were produced by nylon-wool-passed day 6 spleen cells, and virtually all interferon production was eliminated by treatment of either day 2 or day 6 cells with antibody to theta antigen and complement, suggesting that T cells produced the interferon in vitro. Furthermore, athymic nude mice had no culture-stable NK cells 6 days postinfection, and spleen cells from them failed to produce significant levels of interferon in vitro. Addition of interferon (type I, fibroblast) to cultured C3H spleen cells affect the already elevated levels of cytotoxicity in day 6 cultures, suggesting that the NK cells in the day 6 culture were already activated. Our results suggest that T cells responding to LCMV infection secrete interferon type II which causes the continued activation of NK cells in culture. The resulting population of activated NK cells therefore appears to be relatively stable in culture and to express more theta antigen because of this T-cell dependence. Although one could mistakenly or allospecific cytotoxic T cells or cytotoxic macrophages, more careful examination shows that they are most likely activated NK cells...     

Interferon Production by Corynebacterium Parvum and BCG-Activated Murine Spleen Macrophages

Macrophages were identified to be a major source of interferon produced in murine spleen cell cultures after intravenous injection of Corynebacterium parvum (C. parvum), strain CN 6134 or Bacille Calmette Guérin (BCG). Another strain of C. parvum, CN 5888, which lacks RES stimulating activity and adjuvant activity in vivo, was not effective when injected intravenously. Protein synthesis was required for interferon activity to be produced and protein synthesis was also required for the antiviral state to be expressed. The antiviral activity was relatively stable to pH 2 and neutralized by an antiserum against virus-induced fibroblast interferon, thus exhibiting some properties of type I interferon. In vitro only CN 6134, the biologically active strain, could induce small amounts of interferon in spleen macrophage cultures. Macrophages from CN 6134 or BCG-infected athymic nu/nu mice produced similar interferon titers as their controls. It is concluded that infection with certain immunomodulators can activate splenic macrophages via a predominantly T-cell independent mechanism. Interferon in turn may operate locally as a mediator of immunoregulation.     

Induction of Colony-Stimulating Factor(s) After Administration of A Traditional Chinese Medicine, Xiao-Chai-Hu-Tang (Japanese Name: Shosaiko-To)

Colony stimulating factor (CSF)-rich serum was obtained from mice injected intraperitoneally (ip) with shosaiko-to, a traditional Chinese herbal medicine. Transfer of the CSF-rich serum into naive mice augmented the resistance against Listeria monocytogenes. A dose-dependent induction of CSF was observed in mice given shosaiko-to via intravenous route as well as via intraperitoneal route. Since the serum CSF induction was observed in both lipopolysaccharide (LPS)-responder C3H/He mice and LPS-non-responder C3H/HeJ mice, the effect of shosaiko-to seemed to be independent of possibly contaminating LPS. the level of serum CSF induced by shosaiko-to in athymic nude mice was similar to that in control euthymic mice, and the induction of CSF was completely blocked by the previous administration of carrageenan, a selective macrophage-blocker. In mice treated ip with shosaiko-to CSF activity was detected in the peritoneal cavity, the site of injection, and the time course was similar to that of serum CSF induction. In a bone marrow culture system, the composition of colonies formed by shosaiko-to-induced CSF was similar to that formed by standard GM-CSF. the CSF activity was scarcely affected by treatment of the sera with anti-M-CSF antibody. These results suggest that shosaiko-to augments the host defense by inducing mainly GM-CSF, and that CSF is produced by cells of macrophage lineage. In addition, it was shown that CSF could be induced even after oral administration of herbal medicines.     

Production of colony-stimulating factors during pneumonia caused by Chlamydia trachomatis.

The colony-stimulating factors (CSFs) are cytokines involved in the production, differentiation, and activation of host phagocytes. During murine infection with Chlamydia trachomatis (MoPn), plasma CSF levels increased in euthymic (nu/+) and athymic (nu/nu) BALB/c mice. Levels declined later in infection, with the nu/+ mice resolving the infection but the nu/nu mice succumbing by day 16. Either live or heat-killed Chlamydia organisms could induce CSF increases on day 7 postchallenge in nu/+ mice; however, by day 14, only mice challenged with live organisms maintained high plasma levels. CSFs were also produced by spleen cells of nu/+ and nu/nu mice in response to Chlamydia antigen. Spleen cell CSF production was detectable by days 3 to 5 postinfection. In nu/+ mice, spleen cell CSF production was elevated throughout the rest of the time course but in nu/nu mice fell significantly at day 14. Like the plasma CSF activity (CSA) production, spleen cell CSA production on day 7 was seen in mice challenged with either live or heat-killed Chlamydia organisms, but on day 14 only nu/+ mice challenged with live organisms maintained significant CSA production. To further characterize the T-cell dependence of CSA production, spleen cells of nu/+ mice were depleted of T cells or T-cell subsets before producing supernatants. On day 14 postinfection, the CD4+ lymphocyte was the major producer of CSFs. Additionally, there were different types of CSFs secreted by nu/+ and nu/nu mice as determined by the ability of spleen cell supernatants to support the granulocyte-macrophage CSF/interleukin 3-dependent cell line FDCP-1. Supernatants from nu/+ mice had 4 to 8 times the level of FDCP-1 CSF activity of the supernatants from nu/nu mice. These results support the evidence that nu/+ mice were producing some CSFs by T-cell-dependent mechanisms. This is the first report of CSF production in vivo during Chlamydia infection. Furthermore, we show that CSFs are produced by both T-cell-dependent and T-cell-independent mechanisms. The capacity of the CSFs to increase the production and effector function of phagocytes may be important to host defenses.     

Immune interferon. I. Production by lymphokine-activated murine macrophages.

Unfractionated murine spleen cells produce immune interferon (type II) upon stimulation with antigen or mitogen. When spleen cells were passed over glass bead columns, interferon production decreased whereas the mitotic response to the stimulants drastically increased. When these cells were further purified over nylon wool columns, interferon production was totally abolished whereas thymidine incorporation in stimulated cultures was invariably high. Interferon production by nylon wool column-purified lymphocytes could be restored with macrophages grown from bone marrow cultures or spleen cells but not with macrophages from proteose peptone-induced peritoneal exudate cells. It was also found that pure macrophage cultures from spleens of BCG-immunized mice consistently produced interferon activity without any further stimulation. When culture supernatants of activated T lymphocytes, which did not contain any interferon activity, were transferred to macrophage cultures from different sources and incubated for 45 h, interferon activity could be detected in supernatants of macrophage cultures from bone marrow and spleen but not in those from proteose-induced peritoneal exudate cells. It is concluded that certain macrophage populations can be induced to produce interferon activity whereas others are refractory to this induction which appears to be linked to their differentiation state.     

Induction of interferon after administration of a traditional Chinese medicine, xiao-chai-hu-tang (shosaiko-to).

We examined the ability of a traditional chinese herbal medicine, xiao-chai-hu-tang (Japanese name: shosaiko-to) to induce IFN in mice. A maximum activity (105 units/ml) of interferon (IFN) appeared in the serum of mice 16 h after intraperitoneal (i.p.) treatment with 250 mg/kg of shosaiko-to. Addition of polymyxin B did not abrogate the ability of shosaiko-to to induced serum IFN. The IFN was identified as IFN-alpha/beta by neutralizing test using anti-IFN alpha/beta antibodies. Pretreatment of mice with carrageenan suppressed the IFN induction by shosaiko-to, whereas the IFN induction by shosaiko-to was impaired neither in mice treated with anti-asialo-GM1 antibody nor in T-cell-deficient athymic nude mice. IFN was produced in vitro by spleen cells obtained from shosaiko-to treated mice. Moreover, spleen cells from untreated mice could also produce IFN when they were cultured with shosaiko-to. Additionally, serum IFN was also induced by the adoptive transfer of spleen cells from shosaiko-to treated mice to normal mice. On the other hand, peroral administration of shosaiko-to also induced IFN-alpha/beta in the serum. While IFN activity induced by i.p. administration of shosaiko-to declined after repeated treatments, the activity induced by its peroral administration did not decline during a long term treatment. These results showed that shosaiko-to is an IFN-alpha/beta inducer capable of repeated peroral administration.     

Effects of granulocyte-macrophage colony stimulating factor (GM-CSF) in vivo on cytokine production and proliferation by spleen cells

GM-CSF is a potent stimulator of haematopoietic cells as well as some functions of granulocytes and macrophages. GM-CSF has many clinical uses; however, little is known about the effects of GM-CSF treatment in vivo on the responses of tissue lymphocytes in terms of secretion of Th-1 and Th-2 cytokines. We investigated this issue by measuring the responses of spleen cells from mice 24 h after treatment i.p. with saline or rmGM-CSF. GM-CSF at 16.7-50.0 microg/kg significantly increased (P < 0.01) spleen cellularity 2-2.5-fold and enhanced proliferative responses of non-stimulated (no mitogen) as well as concanavalin A (Con A)-stimulated spleen cells. Secretion of IFN-gamma by Con A (2.5 microg/ml)-stimulated spleen cells was significantly (P < 0.01) increased from 1.8 microg/ml by control spleen cells to 5.2 microg/ml by GM-CSF spleen cells. IL-10 production was greater (0.25 microg/ml, P < 0.05) by Con A-stimulated spleen cells from GM-CSF-treated mice compared to control spleen cells (0.06 microg/ml). By contrast, there were no significant differences in IL-4 production by Con A-stimulated spleen cells from the different groups. These results show that GM-CSF treatment increases spleen cellularity and primes lymphocytes for enhanced responses. The enhanced production of Th-1 cytokines by primed lymphocytes may partially explain the beneficial role of in vivo administration of GM-CSF in several clinical situations.     

The role of the thymus in modulating gammadelta T cell suppressor activity during experimental Trypanosoma cruzi infection

We have previously shown that splenic gammadelta T cells from young but not aged BALB/c mice possess suppressor activity in vivo and in vitro during the acute phase of Trypanosoma cruzi infection. The present work was undertaken to investigate the suppressor activity of gammadelta T cells from T. cruzi-infected euthymic or athymic mice and the role of the thymus in modulating non-adherent spleen cell suppressor activity during the acute phase of infection. Splenic gammadelta T cells from aged or athymic BALB/c mice reconstituted with total spleen cells or non-reconstituted did not exhibit suppressor activity when added to full allogeneic, mixed lymphocyte cultures. In contrast, splenic gammadelta T cells from young euthymic BALB/c mice showed suppressor activity in vitro. Thymectomy reduced the splenic gammadelta T cell suppressor activity of young BALB/c mice in a time-dependent manner, following a T. cruzi challenge. The continuous provision of thymocytes to aged mice, young thymectomized mice or total spleen cell- reconstituted athymic mice could re-establish the gammadelta T cell suppressor activity. Of particular significance was the observation that the depletion of gammadelta T cells during the acute phase of T. cruzi infection restored the capacity of these mice to mount a humoral immune response to a non-related antigen such as ovalbumin. These results indicate that gammadelta T cells of extrathymic origin cannot mediate suppression and that the thymus has a role in the regulation of suppression during the acute phase of T. cruzi infection.      

Studies of the producer cell of herpes simplex virus-induced interferon in mouse spleen cell cultures

The producer cell of type I interferon was studied in spleen cell cultures of C57BL/6 mice stimulated by inactivated Herpes Simplex Virus (HSV). Interferon production was not abolished by pretreatment of the spleen cells by anti-theta serum plus complement. The producer cell of interferon was not removed by plastic adherence and was not destroyed by the addition of silica. It was present in spleens of 3 day old C57BL/6 mice and in spleens of nu/nu mice. It was not inactivated by treatment of nu/nu spleen cells by anti-theta serum plus complement. HSV-induced interferon production was abolished by passage of the spleen cells through nylon wool columns and by irradiation (1000 R) of the spleen cells. Collectively these data suggest that in murine spleen cell cultures type I interferon is produced by B cells. However, our data do not allow to rule out that the interferon producing cell may be an immature macrophage or an immature T cell.     

Dextran-triggered T cells heighten T- and B-cell reactions to mitogens.

Dextran administered to mice of six strains has been found to cause enhanced responses of spleen cells to the mitogens Con A and LPS. When added to cultures of spleen cells in vitro in a wide range of concentrations dextran, alone, was neither mitogenic nor toxic. The enhancement is mediated through T cells since it was absent in spleen cells from dextrantreated athymic mice. Furthermore, for the enhanced response to LPS, T cells from dextran-treated mice apparently must be in close association with B cells for longer than 2 h. The enhancement is accomplished through a humoral factor(s) produced by splenic T cells. The T cell-derived enhancing factor(s) has been shown to affect allogeneic as well as isogeneic T and B cells.     

Mitogenicity of Naegleria fowleri extract for murine T lymphocytes

The whole-killed pathogenic free-living amoeba, Naegleria fowleri, contained mitogenic activity (NFM) for mouse spleen cells. Similar preparations from the non-pathogenic amoeba N. gruberi and the pathogenic Acanthamoeba culbertsoni lacked mitogenic activity. Fluids from N. fowleri cultures, containing amoeba antigens, also failed to cause proliferation of mouse spleen lymphocytes. Spleen cells from athymic nude mice failed to respond to NFM. In addition, nylon wool non-adherent, but not the adherent, spleen cell subpopulation proliferated in the presence of NFM. These results show that the factor(s) is mitogenic for T lymphocytes. The spleen cells from mice treated with cyclophosphamide doses known to deplete T suppressor cell activity from this organ failed to respond to NFM, indicating that NFM may be mitogenic for T suppressor cells.     

Presence of a very small population of Thy-1+, L3T4+ cells producing large amounts of IL-3 in young athymic nude mice.

A mixture of phorbol myristate acetate (PMA) and ionomycin was found to stimulate spleen and lymph node cells (LNC) from 6 to 8 week-old-athymic BALB/c nude mice, as well as from control +/+ mice, to secrete interleukin-3 (IL-3) in vitro. The specificity of the IL-3 bioassay was attested to by the use of rabbit anti-IL-3 antibodies, and by the detection of an accumulation of IL-3 mRNA. Cytotoxic treatment with relevant antibodies showed that the cells responsible for the IL-3 production in athymic nude mice was Thy-1+, L3T4+, Ly2-, while both L3T4+ and Ly 2+ cells produced IL-3 in control +/+ mice. Although the levels of IL-3 secreted by nude LNC varied among experiments, nude LNC were able to produce IL-3 at a level comparable to or higher than +/+ LNC. In addition, nude LNC consistently secreted two to three times more granulocyte-macrophage colony-stimulating factor (GM-CSF) than +/+ LNC, and the majority of GM-CSF secretion was dependent on the presence of L3T4+ cells. In contrast, IL-2 production by nude LNC was markedly limited. Since the flow microfluorometry analysis failed to demonstrate the presence of L3T4+ cells (less than 1%) in nude LNC, compared with 40-50% L3T4+ cells in +/+ LNC, our results suggest that athymic nude mice have a small population of Thy-1+, L3T4+ cells characterized by its ability to secrete IL-3 and GM-CSF at a very high rate.     

Inhibition of in vitro erythropoiesis by soluble mediators in Plasmodium chabaudi AS malaria: lack of a major role for interleukin 1, tumor necrosis factor alpha, and gamma interferon.

By using erythropoietin-dependent proliferation of splenic erythroid cells as an in vitro erythropoiesis model system, we demonstrate that spleen cells from Plasmodium chabaudi AS-infected C57BL/6 mice potently inhibited erythroid cell proliferation. Inhibitory activity was detected in spleen cell conditioned media (SPCM) prepared from infected mice but not from uninfected mice. The inhibitory activity in SPCM was characterized as being heat sensitive, macromolecular, and host derived. The inhibitory activity was not reversed by increasing the erythropoietin concentration and was found to be specific for the late erythroid lineage. Mouse strains, which differ in their resistance to P. chabaudi AS infection, produced and responded to the inhibitory activity to a similar extent. Putative immune mediators, interleukin 1 alpha, interleukin 1 beta, and gamma interferon, were found to be potent inhibitors of erythroid cell proliferation. However, antibody neutralization experiments failed to demonstrate a major role for these cytokines in the inhibitory activity of SPCM. Our results suggest that the elaboration of inhibitor(s) of erythropoiesis in hemopoietic organs of Plasmodium-infected mice may impair erythroid regeneration. The identity of the inhibitory mediator(s) is presently unknown but is distinct from interleukin 1, tumor necrosis factor alpha, and gamma interferon.     

Gamma interferon suppresses acute and chronic Trypanosoma cruzi infection in cyclosporin-treated mice.

To determine if exogenous gamma interferon is effective in immunosuppressed mice infected with Trypanosoma cruzi, recombinant murine gamma interferon was administered to cyclosporin-treated mice with either acute or chronic T. cruzi infection. Gamma interferon significantly decreased parasitemia and prevented death in acutely infected mice. Parasitemias and mortality of mice treated with both gamma interferon and cyclosporin were similar to those of immunocompetent controls. In chronically infected mice, cyclosporin treatment produced significantly more organ explant cultures positive for T. cruzi. Fewer positive cultures, particularly for spleen and heart, were obtained from cyclosporin-treated mice when they also received gamma interferon. Ketoconazole treatment of mice resulted in no positive cultures. Cyclosporin treatment did not prevent activation of peritoneal macrophages by parenteral gamma interferon, nor did it have a consistent effect on serum titers of alpha/beta or gamma interferon in response to a second challenge inoculum of T. cruzi. These data indicate that exogenous gamma interferon suppresses acute and chronic T. cruzi infection in cyclosporin-treated mice but that gamma interferon is not as effective as the relatively specific antimicrobial ketoconazole. Gamma interferon activates macrophages despite cyclosporin treatment, and its effects appear to be tissue specific.     

Production of gamma interferon by natural killer cells from Toxoplasma gondii-infected SCID mice: regulation by interleukin-10, interleukin-12, and tumor necrosis factor alpha.

Previous studies of mice have implicated natural killer (NK) cells as mediators of protective activity against Toxoplasma gondii through their production of gamma interferon (IFN-gamma). In the present study, we have compared NK-cell activity in infected and uninfected SCID mice. Our data reveal that infection results in increased levels of IFN-gamma in serum and elevated NK-cell activity but that these NK cells were not cytotoxic for T. gondii-infected P815 cells. Treatment with anti-IFN-gamma antibody abrogated the increase in NK-cell activity and resulted in earlier mortality of infected mice. In vivo treatment with anti-asialo GM1 antiserum reduced NK cell activity and levels of IFN-gamma in serum but did not alter time to death. Spleen cells from infected mice produced higher levels of IFN-gamma than those from uninfected mice when stimulated in vitro with live T. gondii or parasite antigen preparations. Further analysis revealed that interleukin 10 (IL-10) inhibited, whereas tumor necrosis factor alpha (TNF-alpha) and IL-12 enhanced, IFN-gamma production by spleen cells from infected or uninfected mice. The combination of IL-12 and TNF-alpha induced higher levels of IFN-gamma from whole spleen cells of infected mice than from those of uninfected mice. Depletion of the adherent cell population from the spleen cells of infected mice led to a significant reduction in the levels of IFN-gamma produced after stimulation with IL-12 plus TNF-alpha. Similar results did not occur with cells from uninfected mice. These data indicate that other cytokines produced by the adherent cell population from infected mice may be involved in maximal production of IFN-gamma by NK cells stimulated with IL-12 and TNF-alpha. To assess the importance of endogenous IL-12, a polyclonal anti-IL-12 was administered to infected SCID mice. This treatment led to earlier mortality, indicating that endogenous IL-12 mediates resistance to T. gondii.     

Sex hormone modulation of interferon (IFN) alpha/beta and gamma production by mouse spleen cell subsets following picornavirus infection

Replication of the diabetogenic variant of encephalomyocarditis virus (EMCV-D) in spleen cells and its association with subpopulations of spleen cells (L3T4+, Lyt-2+, Mac 1+, 33D1+ and AGM1+ cells) from both sexes of ICR Swiss mice were examined. Virus replication was limited to less than 0.5 log in suspensions of whole spleen cells, nonadherent cells or a B cell subfraction from both sexes of ICR Swiss mice following infection with EMCV-D at an MOI of 10; no virus replication was seen in adherent spleen cells from either sex. After 1 hour adsorption of EMCV-D onto spleen cells at a multiplicity of infection (MOI) of either 10 or 0.1, virus-associated cells were isolated using a monoclonal murine anti-EMCV-D and anti-mouse IgG conjugated to magnetic beads. Using an MOI of 0.1, less than 1% of spleen cells bound virus particles after 1 hour adsorption at 4 degrees C. Among the virus-positive cells, relatively higher percentages of adherent cell populations (Mac 1+ and 33D1+ cells) of both sexes bound virus particles within the first hour post-infection (PI) than did the other spleen cell subpopulations. Interferon (IFN) alpha/beta production was detected as early as 4 hours PI in female spleen cell cultures infected with EMCV-D at an MOI of 0.1 while no IFN alpha/beta activity was found in comparably infected male spleen cell cultures. Inhibiting IFN alpha/beta activity in the virus-infected spleen cell cultures during the first 20 hours of infection using polyclonal rabbit anti-mouse IFN alpha/beta serum eliminated production of IFN gamma as well as IFN alpha/beta. Spleen cell cultures depleted of adherent cells were unable to produce IFN alpha/beta or IFN gamma in the first 24 hours PI. The capacity to produce IFN gamma at 12 hours after virus infection of spleen cells from both sexes of mice was restored to adherent cell-depleted cultures by addition of mouse IFN alpha/beta at the time of infection. These results suggest that IFN alpha/beta and adherent cells play critical roles in the early production of IFN gamma (less than 16 hours PI) characteristic of the infected spleen cell cultures of females. Production of IFN alpha/beta and IFN gamma by spleen cells from both sexes of ICR Swiss mice was enhanced by administrating estrone to donor mice during the week before harvesting spleen cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Production of gamma interferon in mice immune to Rickettsia tsutsugamushi.

C3H/He mice immunized by subcutaneous infection with Rickettsia tsutsugamushi Gilliam were examined for the production of immune interferon after intravenous administration of irradiated strain Gilliam antigen, in supernatants of immune lymphocytes stimulated with specific antigen, and after a secondary challenge with viable rickettsiae. Mice administered various doses of irradiated whole-organism antigen 28 days after immunization showed circulating levels of interferon which peaked 4 h after inoculation and were antigen dose dependent. The interferon produced was pH 2 sensitive and stable at 56 degrees C for 1 h and was neutralized by antiserum directed against immune, but not against alpha/beta, interferon. The production of another lymphokine, macrophage migration inhibition factor, paralleled that of interferon. The interferon produced by cultures of spleen cells obtained from immune animals was antigen specific and dose dependent. Peak levels were obtained 48 to 72 h after the addition of antigen. The interferon produced by spleen cell cultures after stimulation with Gilliam antigen was characterized as immune interferon by the same physical and antigenic criteria used for serum interferon. Interferon was produced in vitro by the Thy-1.2+ lymphocyte and required the presence of a spleen-adherent cell population. Immune mice produced high circulating levels of immune interferon after intraperitoneal challenge with viable rickettsiae, which suggested a possible role for interferon in the resistance of immune mice to rechallenge with R. tsutsugamushi.     

T-T cell interactions during in vitro cytotoxic T cell responses. VI. The role of T cell-derived colony-stimulating factor in helper T cell activation

A limiting dilution culture system has been used to analyze the role of T cell-derived colony stimulating factor (CSF) during the activation of IL 2-producing helper T lymphocytes (HTL). EL4 thymoma-derived supernatant (EL4-SN) increased about 4-fold the frequency of HTL precursors responding to metabolically active allogeneic stimulator cells. Upon biochemical separation this biological activity within the EL4-SN segregated from interleukin 2 (IL 2) and gamma interferon but was associated with or identical to CSF. Further, a comparable rise in HTL precursor frequencies was observed when semipurified interleukin 1 (IL 1) derived from the P388 D1 cell line was added to limiting dilution cultures. In contrast to IL 1, semipurified CSF failed to facilitate the activation of HTL precursors when heat-treated allogeneic spleen cells were used as stimulator cells. Because EL4-derived CSF was found to induce IL 1 production by macrophages we conclude that T cell-derived CSF amplifies, via stimulation of antigen-presenting cells the number of inducible HTL precursors. Therefore, the CSF/IL 1-dependent increase in HTL precursor frequencies reported here may reflect the differential activation threshold of HTL-precursors, most of which will not be activated by antigen per se but only in presence of additional cytokines.     

Lectin-induced cytotoxic activity in spleen cells from young and old mice. Age-related changes in types of effector cells, lymphokine production and response.

Concanavalin A (Con A)-induced cytotoxic activity, interferon (IFN) and interleukin-2 (IL-2) levels in cultures of spleen cells from young (2-3 months) and old (22-24 months) C57BL/6 female mice were studied. Con A-activated spleen cells from old mice attained significantly higher cytotoxic activity compared with activated spleen cells from young mice. Activated spleen cells from old and young mice showed differences in their ability to lyse different types of target cells. Both could lyse P-815 cells, neither could lyse K562 cells, and only activated cells from old mice could lyse EL-4 cells. Cytotoxic spleen cells from the old mice were more sensitive to anti-asialo-GM-1 and anti-Lyt-2.2 plus complement (C) treatment. While levels of IL-2 produced by spleen cells from young mice were higher, the addition of exogenous IL-2 had no effect on cytotoxic activity of the spleen cells from old mice. Exogenous IL-2, however, could lower cytotoxic activity of Con A-activated spleen cells from young mice. Activated spleen cells from old mice generated higher levels of IFN-gamma while the addition of an anti-IFN-gamma antibody boosted the level of cytotoxicity by Con A-activated spleen cells from young mice. These results suggest that IFN-gamma may act as a feedback inhibitory signal regulating the levels of cytotoxicity induced in spleen cells from young mice in response to Con A. The cytotoxic activity generated in Con A-activated spleen cells from old mice reflects a defect in this feed-back regulation.