Plasmodium falciparum schizont sonic extracts suppress lymphoproliferative responses to mitogens and antigens in malaria-immune adults.

Cellular immune responses to malaria antigens are suppressed during acute Plasmodium falciparum infection, and evidence from both murine and human studies suggests that parasite-derived factors may be directly immunosuppressive. In this study we have shown that P. falciparum schizont sonic extract will suppress in vitro lymphoproliferative responses to purified malaria antigens and other soluble antigens. The degree of suppression appears to correlate with the level of the lymphoproliferative response to the schizont preparation and is correspondingly more marked in malaria-immune donors than in nonimmune individuals. The effect can be transferred with primed mononuclear cells and is partially abrogated by removal of CD8+ lymphocytes. The suppressive component of the schizont preparation is nondialyzable and partially heat labile and comigrates with hemoglobin-derived proteins in the molecular mass range 10 to 20 kilodaltons.

Differential antigen presentation by cloned populations of mouse splenic macrophages.

Soft agar colonies of mouse splenic macrophages differ in their ability to process and present complex Ag to T cell hybridomas. To determine if the basis for this differential activity was the synthesis of molecules that might interfere with the activity of either the hybridoma or the indicator cells used for the bioassay of IL-2, culture supernatants were compared from Ag-presenting and nonpresenting cultures for their content of suppressor activity, using mitogen-treated mouse SC. No correlation was found between a colony's Ag-presenting activity and its secretion of suppressor factors, nor did colonies unable to present Ag release factors that interfered with the detection of IL-2. In a second approach, paired subcultures from individual colonies were tested for their ability to present, to the same hybridoma, both native Ag and the "preprocessed" peptide of the Ag. The presentation of native Ag was restricted to the progeny of a minority of the cloned macrophage progenitors, but all of the progeny cultures presented the peptide. Together, these results suggest that the basis for differential Ag presentation may be in the manner in which the cloned macrophages degrade and process ingested Ag.

Monoclonal anti-idiotypic antibodies regulate the expression of virus-induced murine myocarditis.

A monoclonal anti-idiotypic antibody (anti-Id), produced by electrofusion and designated anti-Id88, was able to modulate expression of murine autoimmune myocarditis mediated by coxsackievirus B3 (CVB3). The anti-Id was characterized as an immunoglobulin G2b species possessing kappa light chains and was able to reduce expression of inflammatory myocarditis in anti-Id-pretreated mice challenged with CVB3. Anti-Id88 was able to stimulate specific cell-mediated immunity against anti-Id88, as well as CVB3, and exerted a suppressive effect on the proliferation of mixed spleen cell populations from virus-exposed mice. Anti-Id stimulated an anti-anti-Id antibody 3 population able to bind antibody 2 F(ab')2 fragments or virus antigen in an indirect enzyme-linked immunosorbent assay. Western blot (immunoblot) analysis of anti-Id88 exhibited binding of syngeneic anti-Id antibody to idiotypes present on immunoglobulin G molecules from virus-immunized mice.

Protective modulation of class II MHC gene expression in tubular epithelium by target antigen-specific antibodies. Cell-surface directed down-regulation of transcription can influence susceptibility to murine tubulointerstitial nephritis.

We have been studying the factors which permit autoimmune injury to the kidney leading to interstitial nephritis. Nonsusceptible mice develop L3T4+ effector T cells which do not recognize their 3M-1 target Ag, nor produce interstitial lesions in the kidney unless proximal tubular class II MHC Ag expression is increased, for example, by rIFN-gamma. Anti-tubular basement membrane/alpha 3M-1-Ab, normally present in such mice after immunization with 3M-1, produce an opposite result by diminishing class II transcription and expression. This unique antibody-ligand interaction on the surface of proximal tubular epithelium secreting 3M-1 serves as a novel protective regulatory response in interstitial parenchyma. The in vitro studies conveyed in this current report suggest that alpha 3M-1-Ab mediate this protective effect by reducing the transcription of mRNA encoding class II gene products. These findings, within the overall complexity of a nephritogenic immune response, demonstrate the important role certain elements may play in maintaining functional nonsusceptibility to autoimmune injury.

Macrophage activation by granulocyte/macrophage colony-stimulating factor. Priming for enhanced release of tumor necrosis factor-alpha and prostaglandin E2.

The macrophage-activating properties of murine recombinant granulocyte-macrophage (GM)-CSF were studied in murine peritoneal macrophages with respect to metabolism, endocytosis, PGE2 and TNF-alpha release, and tumor cytotoxicity. GM-CSF was found to be a potent stimulus for RNA and protein synthesis, glucose consumption, pinocytosis, and FcR-independent phagocytosis. Macrophages were activated by GM-CSF to kill TNF-alpha-insensitive Eb lymphoma cells but failed to generate cytotoxicity against TNF-alpha-sensitive L929 cells. Although GM-CSF alone was incapable of stimulating TNF-alpha release, it primed macrophages for elevated TNF-alpha production in response to IFN-gamma plus LPS. The priming effect of GM-CSF disappeared upon longer incubation (greater than 12 h) and was followed by a strongly reduced responsiveness to stimuli that release TNF-alpha. Late-stage suppression could be reverted by treatment with the cyclooxygenase blocker indomethacin, and GM-CSF-induced priming for enhanced TNF-alpha release was entirely restored. The responsible arachidonic acid product mediating suppression was found to be PGE2, because 1) GM-CSF-primed macrophages released enhanced amounts of PGE2 and 2) indomethacin-restored macrophages were again suppressed when exogenous PGE2 was added back in amounts produced by GM-CSF-primed macrophages. Although GM-CSF potently induced TNF-alpha gene transcription by 20 h of treatment, PGE2 interfered with translation into the secreted TNF-alpha protein. These data show that GM-CSF is capable of priming for the enhanced release of two factors, initially for TNF-alpha and subsequently for PGE2. The temporally delayed generation of these two mediators suggests an autoregulatory circuit in which the later produced PGE2 limits GM-CSF-induced macrophage activation.

The effect of anti-intercellular adhesion molecule-1 on phorbol-ester-induced rabbit lung inflammation.

The role of the CD18 complex of leukocyte glycoproteins in adhesion-dependent functions of human leukocytes in vitro has been well documented. A ligand, intercellular adhesion molecule-1 (ICAM-1), for at least one member of the CD18 complex has been identified. This molecule is inducible on many cell types including vascular endothelium and keratinocytes by inflammatory mediators such as IL-1, TNF, and IFN-gamma. ICAM-1 has been shown to mediate, in part, the in vitro adhesion of lymphocytes and neutrophils to endothelial cells expressing ICAM-1. In the present study we have shown that mAb's to the human CD18 complex and to human ICAM-1 cross react with rabbit cells and that both anti-CD18 and anti-CD11b but neither anti-CD11a nor anti-ICAM-1 mAb's inhibit neutrophil migration, an adhesion-dependent function, in vitro. Pretreatment of rabbits with anti-CD18 and anti-ICAM-1 but not anti-CD11a mAb inhibited by greater than 60% neutrophil migration into PMA-induced inflamed rabbit lungs. This effect of anti-ICAM-1 mAb on pulmonary neutrophil influx after PMA injection has important implications. Specifically, that ICAM-1 can function as a ligand for CD18 and can mediate, at least in part, the migration of neutrophils to inflammatory sites.

Dextran sulfate and heparin interact with CD4 molecules to inhibit the binding of coat protein (gp120) of HIV.

Dextran sulfate, heparin, and certain other sulfated polysaccharides potently inhibit the adsorption of HIV to CD4+ cells. The mechanism of this inhibition is unclear and, specifically, it is unknown if these agents act at the level of CD4-gp120 binding. For example, previous reports have demonstrated that dextran sulfate does not inhibit the cell surface binding of anti-CD4 mAb known to be directed at the gp120 binding site. In order to confirm and extend these observations, in the present study, it was shown that dextran sulfate does not inhibit the binding of OKT4A, OKT4C, Leu3a, or B66.6 to CD4+ cells as measured by cytofluorography. Next, recombinant forms of CD4 (rT4) and gp120 (rgp120) were utilized to directly study their molecular interaction in the absence of other viral or cellular structures. Reciprocal solid phase ELISA assays were developed to study directly the effects of sulfated polysaccharides on the binding of rT4 to immobilized rgp120 and vice versa. Dextran sulfate, heparin, and fucoidan, but not chondroitin sulfate, inhibited the binding of rgp120 to rT4. Importantly, dextran sulfate and heparin pre-treatment of immobilized rT4, but not immobilized rgp120, inhibited rT4-rgp120 binding. Taken together, these data suggest that while both sulfated polysaccharides and anti-CD4 mAb inhibit gp120 binding, the sulfated polysaccharides interact with sites on CD4 that are distinct from those with which the antibodies bind.

Murine natural suppressor cells in the newborn, in bone marrow, and after cyclophosphamide. Genetic variations and dependence on IFN-gamma.

Natural suppressor (NS) cells are potent, Ag nonspecific, MHC-unrestricted inhibitors of immune responses. Murine NS activity is found in several situations, including adult bone marrow (BM) and neonatal/newborn spleen, and spleen following total lymphoid irradiation, after BM transplantation and after cyclophosphamide (CY) treatment. Using three of these situations (adult BM, newborn spleen, and spleen after CY treatment), the strain distribution of NS cell activity was assessed. A wide variation in potency is seen in both naturally occurring (adult BM and newborn spleen) and induced (after CY treatment) NS cell activity. Up to 10-fold differences in NS activity are seen between high and low NS strains. This reflects an intrinsic genetic variation between mouse strains in both naturally occurring and CY-induced NS cell activity. Thus, a strain with high NS activity at birth, has high NS activity in its BM as an adult and in its spleen after CY treatment. Of the strains tested, B10.D2 has the highest NS cell activity while BALB/c has the lowest, and the F1 between these two strains is intermediate in NS activity. Finally, the NS cell activity from all strains tested required IFN-gamma for expression of its inhibitory activity.

Monocyte suppressor factor is plasminogen activator inhibitor inhibition of membrane bound but not soluble IL-1.

Human monocytes cultured in monolayer for 6 days were found to secrete a factor that suppressed the T cell proliferative response to soluble Ag and to alloantigens. The elaboration of this monocyte suppressor factor (MSF) was not inhibited by indomethacin. It has an apparent Mr of 50 to 60 kDa. It does not inhibit soluble IL-1 in the murine thymocyte costimulator assay but does inhibit the activity of membrane bound IL-1, which we observed to be almost exclusively IL-1 alpha. MSF contains elevated amounts of plasminogen activator inhibitor (PAI) when measured either as bioactivity or in an ELISA. Its immunosuppressive properties are inhibited by anti-PAI antibody. Furthermore, the eluate but not the effluent of an anti-PAI immunoabsorbent column contains all of the immunosuppressive activity. Based on these data we suggest that MSF is, in fact, PAI and postulate that the mechanism of action is inhibition of the plasmin cascade, thereby preventing the release of membrane bound IL-1. This suggests that monocytes possess an autoregulatory circuit that may have implications for the kinetics of the inflammatory response.

Adenosine regulates the respiratory burst of cytokine-triggered human neutrophils adherent to biologic surfaces.

The effect of adenosine on the respiratory burst was investigated using human neutrophils adherent to serum-coated surfaces. Adenosine caused complete suppression of the respiratory burst elicited by TNF-alpha, FMLP, or CSF for granulocytes; partial suppression of the response to CSF for granulocytes/macrophages, Staphylococcus aureus, Escherichia coli, Listeria monocytogenes, or uncoated polystyrene surfaces; and no suppression of the response to PMA. In most experiments, 4.7 x 10(-7) M and 2.5 x 10(-8) M adenosine caused 50% suppression of H2O2 release in response to TNF-alpha and FMLP, respectively, and 10 microM caused 100% suppression. Preexposure of neutrophils to ADP blocked the inhibitory effect of adenosine. With adherent neutrophils, there is a prolonged lag period in the onset of the respiratory burst in response to cytokines. Adenosine was fully suppressive if its addition was delayed past the first third of this lag period, or if it was removed during the last third of the lag period. A 10-min pulse with adenosine was most inhibitory when delivered in the middle third of the lag period. Dihydrocytochalasin B abolished the suppressive effect of adenosine on H2O2 release in response to FMLP. Thus adenosine, at concentrations found in human plasma, is a potent but selective inhibitor of the respiratory burst of adherent human neutrophils in response to physiologic, soluble stimuli, and ADP is a potentially physiologic counter-suppressant. Adenosine appears to exert most of its effect during a discrete interval within the lag period before onset of the respiratory burst, and may affect the coupling of agonist receptors to the cytoskeleton.

Inhibition of endotoxin-induced activation of human monocytes by human lipoproteins.

Toxicity of lipopolysaccharide (LPS) (endotoxin) is, to a large extent, mediated by the activation of monocytes/macrophages and subsequent release of monokines, such as interleukin-1 (IL-1) and tumor necrosis factor alpha (TNF-alpha). It is known that LPS binds readily to serum lipoproteins and that LPS-lipoprotein complexes are less toxic than unbound LPS. Here we present data analyzing the impact of the LPS-serum interaction at the cellular level. By measuring IL-1 TNF-alpha, and IL-6, the interaction of different LPSs or lipid A with human serum could be shown to prevent the activation of human monocytes. The amounts of LPS inactivated by normal human serum did not exceed 10 ng/ml. The LPS-inactivating capacity of serum was shown to be a function of the lipoproteins. Other serum components, such as naturally occurring anti-LPS immunoglobulin G, complement, or nutritive lipids, had no significant influence in our system. Our experiments suggest that serum lipoproteins control endotoxin-induced monocyte activation and monokine release.

Role of CD4 in thymocyte selection and maturation.

We examined the possible role of CD4 molecules during in vivo and in vitro fetal thymic development. Our results show that fetal thymi treated with intact anti-CD4 mAbs fail to generate CD4 single-positive T cells, while the generation of the other phenotypes remains unchanged. Most importantly, the use of F(ab')2 and Fab anti-CD4 mAb gave identical results, i.e., failure to generate CD4+/CD8- T cells, with no effect on the generation of CD4+/CD8+ T cells. Since F(ab')2 and Fab anti-CD4 fail to deplete CD4+/CD8- in adult mice, these results strongly argue that the absence of CD4+/CD8- T cells is not due to depletion, but rather, is caused by a lack of positive selection, attributable to an obstructed CD4-MHC class II interaction. Furthermore, we also observed an increase in TCR/CD3 expression after anti-CD4 (divalent or monovalent) mAb treatment. The TCR/CD3 upregulation occurs in the double-positive population, and may result from CD4 signaling after mAb engagement, or may be a consequence of the blocked CD4-class II interactions. One proposed model argues that the CD3 upregulation occurs in an effort to compensate for the reduction in avidity or signaling that is normally provided by the interaction of the CD4 accessory molecule and its ligand. As a whole, our findings advocate that CD4 molecules play a decisive role in the differentiation of thymocytes.

Granuloma formation by artificial microparticles in vitro. Macrophages and monokines play a critical role in granuloma formation.

To investigate the basic mechanisms of granuloma formation, in vitro granulomas were induced by culturing murine spleen cells in the presence of artificial microparticles. Large granulomas developed around dextran beads. The lesions were inducible by spleen cells from either normal mice or athymic nude mice. Minimal inflammation was produced around latex beads. The histologic features and time kinetics of granulomas in vitro. Culture supernatants of dextran induced granulomas contained high levels of interleukin-1 (IL-1) activity but not interleukin-2 (IL-2) or interleukin-4 (IL-4) activity. IL-1 activity was correlated with granuloma size. Additionally, granulomas were produced by culturing spleen cells in the presence of agarose beads coupled to recombinant IL-1 or recombinant tumor necrosis factor-alpha (TNF-alpha). Granulomatous lesions also were induced by macrophage-enriched populations in the presence of monokine-coupled beads. Adherent macrophages, but not nonadherent cells, were required for induction of granulomas in vitro. In contrast, very small lesions were seen when spleen cells or adherent cells were cultured in the presence of beads coupled to recombinant IL-2 or recombinant interferon-gamma (IFN-gamma). These results suggest that macrophages and monokines such as IL-1 and TNF-alpha play an essential role in granuloma formation in vitro.

IL-4 down-regulates IL-1 and TNF gene expression in human monocytes.

The effects of IL-4 on IL-1 and TNF gene expression in human peripheral monocytes (PBM) were examined. Highly purified PBM cultured for 24 to 96 h in the presence of IL-4 produce neither IL-1 nor TNF protein. RNA hybridization studies demonstrated that IL-4 does not induce transcription of IL-1 or TNF. Preincubation of PBM with IL-4 did, however, inhibit LPS-induced IL-1 and TNF production in a dose- and time-related fashion. Maximal inhibition occurred after 96 h of incubation with 200 U/ml IL-4. RNA hybridization studies demonstrated that IL-4 suppressed the expression of IL-1 alpha, IL-1 beta, and TNF mRNA. These results suggest IL-4 modulates monocyte production of TNF and IL-1 by down-regulation of gene expression. This unique property of IL-4 may be important in the regulation of the immune response.

Stimulation of mouse lymphocytes by a mitogen derived from Mycoplasma arthritidis. VII. Responsiveness is associated with expression of a product(s) of the V beta 8 gene family present on the T cell receptor alpha/beta for antigen.

Mycoplasma arthritidis produces a potent soluble T lymphocyte mitogen (MAM) which is dependent upon accessory cells bearing the alpha-chain of the I-E molecule (E alpha). Lymphocytes from the RIIIS mouse strain which possess E alpha yet whose T cells fail to recognize the MAM-E alpha complex were shown not to express V beta 8.1, 8.2 or 8.3 gene products present on the TCR-alpha/beta by virtue of their lack of reactivity with the F23.1 mAb. Because lymphocytes from the congenic B10.RIII mouse strain reacted positively with F23.1, we examined the progeny from (RIIIS x B10.RIII)F1 x RIIIS backcross mice for cosegregation of lymphocytes expressing F23.1-reactive sites and ability to proliferate in response to MAM. Whereas lymphocytes of all mice responded to Con A, only lymphocytes from progeny expressing F23.1-reactive cells responded to MAM. Similar studies were conducted on progeny from the F23.1- SWR mouse which was backcrossed to (SWR x B10.RIII)F1 mice. Of the E alpha-bearing progeny, there was a direct correlation between lymphocyte expression of F23.1 determinants and ability to respond to MAM. These results established that MAM reactivity was dependent upon a product(s) of the V beta locus of the TCR-alpha/beta. Nodal and thymic lymphocytes cultured for 3 days in vitro with MAM exhibited clonal expansion of F23.1 and F23.2-reactive cells as compared with cultures treated with Con A. We also demonstrated that F23.1 and F23.2 mAb inhibited the ability of lymphocytes to proliferate in response to MAM but had little effect on responses to Con A. The combined data suggest that the MAM-E alpha complex can utilize a V beta 8 gene product(s) on the TCR-alpha/beta.

Defective isotype-specific regulation of IgA anti-erythrocyte autoantibody-forming cells in NZB mice.

B cell hyperactivity characterizes many autoimmune diseases. In NZB mice this is manifested by a variety of immunologic aberrations, including increased B cell proliferation and hyper IgM and IgA secretion in vitro. Recent studies have shown that IgA secretion can be suppressed or enhanced in an isotype-specific manner by a soluble factor(s), called IgA-binding factor (IgABF), produced by IgA FcR-bearing T cells. We now show that T cells from young NZB mice, cultured with high concentrations of IgA, produce an IgABF that has aberrant biologic activity when compared to IgABF produced from IgA FcR+ T cells of BALB/c mice. Although BALB/c IgABF normally suppresses proliferation and secretion by IgA-producing B cells, neither proliferation nor IgA secretion from normal murine IgA-B cells is suppressed by NZB IgABF. In fact, IgA secretion is significantly enhanced by NZB IgABF. We also present the first evidence of IgA anti-mouse erythrocyte (anti-MRBC) autoantibody-forming cells present in the spleens of NZB mice. Whereas BALB/c IgABF suppresses the in vitro generation of IgA anti-MRBC autoantibody-forming cells by NZB spleen cells, NZB IgABF enhances this response. Of particular interest is the development of IgA anti-MRBC autoantibody-forming cells in cultures of spleen cells from nonautoimmune BALB/c mice in the presence of NZB IgABF. These studies suggest that isotype-specific T cells factors might play an important role in the development of autoantibody-forming cells.

Modulation of tumor necrosis factor-alpha gene expression. Desensitization of prostaglandin E2-induced suppression.

PGE2, an immune mediator, is an inhibitor of LPS-stimulated TNF production and gene transcription. In the present study we determined whether pretreatment with PGE2 could desensitize the suppressive function of PGE2 for the production of macrophage (MO)-derived TNF. CFA-elicited MO were incubated with PGE2 or medium only, washed, and then challenged with graded doses of LPS (0.001 to 1000 ng/ml) in the presence or absence of new PGE2. The concomitant addition of PGE2 with LPS shifted the LPS concentration-effect curve 16-fold to the right with a 52% decrease in the maximum LPS response, while MO pretreated with PGE2, washed, and incubated with LPS plus new PGE2 were desensitized to TNF regulation. These latter conditions resulted in a complete loss of the ability of PGE2 to inhibit MO TNF production as demonstrated by no significant change in the EC50 of LPS. In addition, the PGE2 concentration effect curve was shifted to the right after pretreatment of MO, suggesting a desensitized PGE2 receptor system. At the transcriptional level, pretreatment of MO with PGE2 attenuated the ability of new PGE2 to inhibit LPS-dependent TNF mRNA expression. Further studies demonstrated that, although the concomitant addition of the cyclooxygenase inhibitor indomethacin plus LPS could increase TNF production, MO pretreated with indomethacin, washed, and then challenged with LPS demonstrated an inhibition of TNF expression. MO pretreated with indomethacin also demonstrated an increased sensitivity for exogenous PGE2-induced suppression of TNF mRNA and bioactivity. These investigations further support the role of PGE2 as an immunomodulating compound that may effectively regulate the local concentration of specific monokines needed to maintain an inflammatory lesion.

Depression of polymorphonuclear leukocyte functions by purified influenza virus hemagglutinin and sialic acid-binding lectins.

Infection of polymorphonuclear leukocytes (PMNL) with influenza virus causes depression of PMNL metabolic and bactericidal activities. The studies reported here were undertaken to determine whether the hemagglutinin (HA) glycoprotein of influenza virus mediates this depression. PMNL were incubated with purified HA and the oxidative responses to exogenous stimuli were measured. The results indicate that HA, in either liposomes or protein aggregates referred to as rosettes, depressed PMNL oxidative responses. Depression was observed within 2 min of initial interaction of HA with PMNL and lasted more than 2 h. The membrane fusion activity of HA requires proteolytic cleavage of the HA, whereas the receptor binding activity does not. There was no difference in the ability of virions with cleaved or uncleaved HA to depress PMNL responses suggesting that the fusion event is not required for PMNL dysfunction. Inasmuch as the HA glycoprotein binds to sialic acid-containing receptors on the surface of the PMNL, we tested whether other sialic acid-specific binding proteins can mediate the reduction of PMNL responses. Sialic acid-specific lectins from Limulus polyphemus or Limax flavus were incubated with PMNL before measuring their responses to secondary stimulus. Depression was observed upon incubation with the lectins similar to that seen upon incubation with the HA or influenza virus. These results suggest that attachment of influenza virus to sialic acid-containing receptors is responsible at least in part, for suppressing PMNL oxidative responses.

Inhibitory effects of rabbit antisera on mitogenic activity of Actinobacillus actinomycetemcomitans lipopolysaccharide.

Lipopolysaccharides (LPSs) were isolated from Actinobacillus actinomycetemcomitans strains ATCC 29523 (serotype a), Y4 (b), and NCTC 9710 (c) by the hot phenol-water procedure. Y4 lipid A was obtained by the hydrolysis of Y4 LPS in 1% acetic acid. All the LPS preparations and Y4 lipid A were mitogenic for C3H/HeN mouse spleen cells, but not for C3H/HeJ mouse spleen cells. Immunoglobulin preparations partially purified by ammonium sulfate precipitation at 33% saturation from rabbit antisera against Y4 whole cells inhibited the mitogenic response of C3H/HeN mouse spleen cells to LPSs from all the strains of A. actinomycetemcomitans and Y4 lipid A. Anti-Y4 LPS immunoglobulin preparation inhibited the mitogenic activity of Y4 LPS and Y4 lipid A. Furthermore, anti-Y4 whole cell Fab fragments inhibited the mitogenic activity of both Y4 LPS and Y4 lipid A. These results suggest that antibodies against A. actinomycetemcomitans LPS may modify immune responses of lymphocytes to this organism at periodontal sites.

Regulation of lymphokine response during reinfection by influenza virus. Production of a factor that inhibits lymphokine activity.

Mononuclear cells, obtained from the spleens and lungs of influenza virus-seropositive C57BL/6 mice at 2 to 4 days after re-infection with homologous virus (strain A/Bangkok/1/79), produced a low m.w. factor in vitro that prevents the biologic expression, but not production, of the lymphokine, leukocyte migration inhibition factor (LIF). The low m.w. factor inhibited LIF activity without destroying the LIF molecule inasmuch as simple dialysis restored lymphokine activity to culture supernatants. Production of the low m.w. factor was observed from 2 to 4 days after re-infection, at which time the delayed-type hypersensitivity response to viral Ag was suppressed. In contrast, LIF was produced by splenocytes and lung mononuclear cells obtained at all times tested after re-infection (from 2 to 30 days). Production of the low m.w. factor required re-infection of influenza A virus-seropositive mice with type A virus; re-infection with influenza B virus failed to induce production. Ag specificity was also required in vitro for splenocytes to produce the factor; cells from type A virus-re-infected mice required type A Ag stimulation. Cell depletion studies with mAb plus C revealed that macrophages and T cells along with Ag stimulation were required for factor production by spleen cells. However, mononuclear cells obtained within 4 days from the lungs of re-infected mice did not require in vitro Ag stimulation for production of the low m.w. factor, and factor production was dependent upon the presence of CD4+ (L3T4) cells in the culture. Fractionation of culture supernatants over a Sephadex G-50 column indicated that the factor had a molecular mass of 2 to 3 kDa, and by FPLC chromatofocusing over a Mono P column, the factor eluted at a pH of approximately 8.2. Thus, re-exposure of influenza virus-seropositive mice to homologous virus resulted in the production of a low m.w. factor that prevented the biologic expression of LIF, but not its production. Lymphokines are an important component of the delayed-type hypersensitivity response; the presence of mononuclear cells secreting a low m.w. factor and LIF concomitantly at the site of virus replication (lungs) and the capacity of the factor to block the biologic expression of LIF in vitro suggest that the factor may have a role in the regulation of a delayed-type hypersensitivity response in vivo during re-infection.