Immunological reactivity of the lung: VII. Effect of corticosteroids and cyclophosphamide on the Fc receptor function of alveolar macrophages

The effects of various in vitro and in vivo regimens of either corticosteroid or cyclophosphamide administration on guinea pig alveolar macrophages were studied. Corticosteroid- and cyclophosphamide-induced immunosuppression was assessed by the effect of drug administration on the capacity of alveolar macrophages to attach to and/or ingest antibody-coated sheep red blood cells (SRBC). In vitro hydrocortisone (up to 20 μg/ml) had no effect on either the binding or ingestion of antibody-coated SRBC. Two separate regimens of in vivo corticosteroids were given: a single dose of iv hydrocortisone (100 mg/kg), which is a short-acting soluble preparation, and sc doses of cortisone acetate (100 mg/kg for 7 days), which is a depot preparation resulting in sustained levels of plasma cortisol of the magnitude of that found for a brief period of time following iv injection of hydrocortisone. Both regimens resulted in similar degrees of peripheral blood lymphocytopenia and monocytopenia 4 and 24 hr, respectively, following injection. The regimen of hydrocortisone has previously been reported to have no effect on alveolar macrophage cytotoxic effector function in antibody-dependent cellular cytotoxicity (ADCC), whereas the cortisone acetate regimen markedly suppressed ADCC. In the present study, hydrocortisone had no effect on either the binding or ingestion of antibody-coated SRBC by alveolar macrophages. In contrast, cortisone acetate caused a marked decrease in both the binding and ingestion of antibody-coated SRBC. This suppressive effect was maximal at suboptimal concentrations of antibody on the SRBC and could be overcome by increasing the concentrations of anti-SRBC antibody. Alveolar macrophages from animals treated with daily cyclophosphamide (a regimen which suppresses ADCC) were capable of binding and ingesting antibody-coated SRBC normally. Thus, prolonged exposure to corticosteroids in vivo causes an alteration in membrane Fc receptor function of alveolar macrophages, which can explain this impaired ability to kill target cells. Since cyclophosphamide therapy did not interfere with the binding and ingestion of antibody-coated target cells, it is concluded that the impairment in killing of target cells by alveolar macrophages is not directly related to an alteration of Fc receptor function but to a defect in the actual killing process.     

Role of antigen-specific B cells in the induction of SRBC-specific T cell proliferation

In this study, we ask whether antigen presentation can be effected by antigen-activated B cells. Antigen-dependent in vitro proliferation of T cells from mice primed with SRBC or HoRBC occurs in the presence of B cells primed to the relevant antigen. B cells prepared from lymph nodes of mice primed with irrelevant antigens are not effective antigen-presenting cells for RBC-specific T cell proliferation over a wide range of SRBC doses. This is true even when both RBC and the antigen to which the B cells are primed are included in the culture. In contrast, B cells specific for a hapten determinant coupled to SRBC are able to support proliferation of T cells specific for SRBC determinants. We conclude from these data that antigen-specific B cells play a role in the induction of T cell proliferative responses to SRBC and HoRBC antigens. Two models are proposed: either B cells, upon antigen interaction with surface antibody, are able to act as accessory cells to induce Ia-dependent proliferation of immune T cells; or B cells augment the T cell proliferative response by secretion of antibody, leading to opsonization of the antigen for macrophage uptake and presentation.     

Establishment and characterization of murine macrophage hybrids

Proteose peptone-induced peritoneal macrophages from CBA/J (H-2k) mice have been fused to a hypoxanthine phosphoribosyltransferase-negative variant of the P388D1 (H-2d) murine macrophage cell line. Six hybrid clones were isolated following HAT selection and further characterized. Five of the six clones express class I antigens of both parental haplotypes by microelisa and by flow cytometric analysis. Class II antigen expression of both haplotypes was apparent following a 72-hr incubation of the hybrids with concanavalin A-stimulated rat spleen cell supernatant. However, I-Ad was expressed in all hybrids to a greater extent than I-Ak. Three clones with the highest level of I-Ak expression, E5, C2, and C4, were capable of antigen presentation to the I-Ak-restricted T-cell line, D10.G4.1. LPS induction of the hybrids resulted in a 2- to 15-fold increase in the amount of IL-1 produced relative to the P388D1 parent. Finally, in distinction to P388D1, all hybrids demonstrated increased Fc-mediated erythrophagocytosis of chromium-labeled antibody-coated erythrocytes. These murine macrophage hybrids appear stable and should serve as useful models in understanding the regulation of macrophage function.     

Changes in plasma, tissue, and urinary nitrogen metabolites due to an inflammatory challenge

Studies were undertaken to define the changes in protein metabolism that result from stimulation of the immune system by noninfectious inflammatory agents. Chicks were injected with inflammatory agents and metabolite concentrations were determined between 4 and 48 hr postchallenge. Inflammatory agents resulted in a generalized decrease in the concentration of plasma nitrogen metabolites, including ammonia, uric acid, urea, and several amino acids. Escherichia coli and sheep red blood cell (SRBC) injections induced changes in the concentrations of tissue-free amino acids at 16 hr postchallenge. After E. coli injections, free amino acid concentrations were increased by 175% in muscle and decreased by approximately 25% in liver, spleen, and bursa. A SRBC challenge resulted in similar decreases in free amino acid concentrations in the spleen and bursa as did E. coli; however, muscle and liver free amino acid concentrations were mostly unchanged. Urinary ammonia was increased, urinary uric acid was decreased, and urinary amino acids were not affected by E. coli injection. These findings indicate that stimulation of the immune system by noninfectious inflammatory agents induces tissue-specific changes in nitrogen metabolism. Changes in amino acid pool sizes in various tissues suggest alterations in rates of protein synthesis or degradation.     

Influence of changes in composition of the cerebrospinal fluid on the secretory activity of the subcommissural organ in Rana esculenta

Summary Normally the lymphatic sinuses of the lymph node are loosely packed with lymphocytes and free macrophages as well as with macrophages adhering to the fibrocellular trabeculae. After immunization with SRBC cluster formation occurs in the medullary sinuses of rats between a central macrophage and peripherally located lymphocytes. These rosette-like clusters are nearly identical with the clusters found during primary and secondary immune response against SRBC in vitro and seem to be the in vivo equivalent for the same immune response.     

Gallium arsenide exposure impairs processing of particulate antigen by macrophages: modification of the antigen reverses the functional defect

Gallium arsenide (GaAs), a semiconductor used in the electronics industry, causes systemic immunosuppression in animals. The chemical's impact on macrophages to process the particulate antigen, sheep red blood cells (SRBC), for a T cell response in culture was examined after in vivo exposure of mice. GaAs-exposed splenic macrophages were defective in activating SRBC-primed lymph node T cells that could not be attributed to impaired phagocytosis. Modified forms of SRBC were generated to examine the compromised function of GaAs-exposed macrophages. SRBC were fixed to maintain their particulate nature and subsequently delipidated with detergent. Delipidation of intact SRBC was insufficient to restore normal antigen processing in GaAs-exposed macrophages. However, chemically exposed cells efficiently processed soluble sheep proteins. These findings suggest that the problem may lie in the release of sequestered sheep protein antigens, which then could be effectively cleaved to peptides. Furthermore, opsonization of SRBC with IgG compensated for the macrophage processing defect. The influence of signal transduction and phagocytosis via Fcgamma receptors on improved antigen processing could be dissociated. Immobilized anti-Fcgamma receptor antibody activated macrophages to secrete a chemokine, but did not enhance processing of unmodified SRBC by GaAs-exposed macrophages. Restoration of normal processing of particulate SRBC by chemically exposed macrophages involved phagocytosis through Fcgamma receptors. Hence, initial immune responses may be very sensitive to GaAs exposure, and the chemical's immunosuppression may be averted by opsonized particulate antigens.     

Influenza virus-induced immune complexes suppress alveolar macrophage phagocytosis

Immune complexes in the lungs are capable of inducing adverse responses. Herein we have detailed the formation of immune complexes in the lungs of influenza virus-infected mice and examined their effect on alveolar macrophage defenses. On days 3, 7, 10, 15, and 30 after aerosol infection with influenza A/PR8/34 virus, the acellular pulmonary lavage fluid was tested for viral antigen, specific viral antibody, and immune complexes by immunoassays. Whereas peak viral antigen (day 3) diminished to undetectable levels by day 10, specific viral antibody remained at a low concentration until day 10, after which it rapidly increased. Immune complex concentrations increased through day 7, peaked at day 10, and gradually returned to the control level by day 30. These data demonstrate that immune complexes of detectable size are induced by influenza virus infection during the interface between antigen excess and antibody excess conditions. Since alveolar macrophages are the pivotal phagocytic defense cells in the lung, the ability of normal alveolar macrophages to ingest opsonized erythrocytes was quantitated in the presence of immune complexes from lavage fluid. Immune complexes from day 10 virus-infected lungs caused a dose-dependent suppression of antibody-mediated phagocytosis to 30% of control values. In contrast, although these immune complexes also markedly decreased the phagocytosis of antibody-coated yeast cells, they did not significantly impair the antibody-independent ingestion of unopsonized yeast cells by macrophages. the suppressive effects of immune complexes on alveolar macrophages may, in part, explain the phagocytic dysfunction that occurs 7 to 10 days after influenza virus pneumonia.     

Antigen-reactive cell opsonization: a mechanism of antibody-mediated immune suppression.

Antisera against sheep red blood cells (SRBC) specifically suppressed the direct anti-SRBC plaque-forming cell (PFC) response in mice when passively administered with the antigen. The suppressive activity of mouse and rabbit anti-SRBC sera was found to correlate with anti-SRBC opsonic activity but not with hemagglutination or hemolysin titers. Macrophage depletion of mice, using carrageenan treatment, inhibited antibody-mediated immune suppression. When mice immunized with SRBC were given ¹²⁵I-labeled Udr, radiolabeled spleen lymphocytes were obtained which specifically formed rosettes with SRBC. These radiolabeled antigen-reactive cells (1ARC) were specifically opsonized in mice treated with antigen-antibody complexes but not in mice treated with antigen or antibody alone. These results suggest that antibody-mediated immune suppression may be due to specific opsonization (and subsequent destruction) of ARC in the presence of antigen-antibody complexes.     

Suppression and augmentation of the primary in vitro immune response by different classes of antibodies

The capacity of purified γG₁ and γG₂ anti-sheep red blood cell (SRBC) antibodies to exert antigen-specific feedback regulations on the primary in vitro immune response to SRBC was studied. Antibodies were administered to the culture in the native form, as sheep erythrocyte-antibody complexes or as pepsin-derived F(ab′)₂ antibody fragments. Marked differences in the feedback regulatory effects of γG₁ and γG₂ antibodies were found. Antibodies of the γG₁ class suppressed the immune response to SRBC, whereas γG₂ antibodies isolated from the same serum exerted an augmenting effect on antibody synthesis. These opposing feedback effects on in vitro antibody synthesis were immunologically specific, relatively insensitive to changes in antigen concentrations, and could be elicited by either adding antibodies and antigen separately to the culture or as preformed antigen-antibody complexes. Experiments comparing the activities of the F(ab′)₂ antibody fragments with the parent γG₁ and γG₂ antibodies suggested that the Fc fragments may be involved in these regulatory effects on the immune response. It is concluded that the antigen-specific suppressive and augmenting effects on antibody synthesis shown here are determined by the antibody class. In addition, we suggest that these opposing antibody-mediated feedback effects may represent one of the important elements of the immune response.     

Genetic restrictions of transfer of delayed-type hypersensitivity to sheep erythrocytes: local versus systemic transfer.

Regulation of the transfer of delayed-type hypersensitivity (DTH) reactions to SRBC was studied using two assays. In the systemic transfer, SRBC immune cells were transferred intravenously and the recipient challenged by injecting antigen into the footpad. In the local transfer assay, SRBC immune cells were mixed with antigen before transfer into the footpad of the recipient. These studies utilized B10.D2 and B10.BR mice which are congenic strains differing only at H-2 region. DTH reactions can be transferred across H-2 barriers using a local transfer assay. When the immune cells were transferred intravenously or depleted of adherent cells prior to local transfer, DTH reactions cannot be transferred to an H-2 congenic recipient. Spleen cells from naive mice syngeneic to the intravenously transferred cells supply the necessary accessory cell when mixed with the antigen prior to injection into the footpad. This accessory cell may be a macrophage.     

An endotoxin induced serum factor that causes enhancement of antibody response to heterologous erythrocytes.

The sera obtained from blood of the mice, which had been intravenously injected with LPS several hours in advance, contained some active substance capable of enhancing anti-sheep red blood cell (SRBC) antibody responses in mice. Activity of the sera was still retained after passage through a rabbit anti-LPS antibody-coated Sepharose 4B column, but greatly reduced by passage through a rabbit anti-mouse thymocyte antibody-coated Sepharose 4B column. The active substance in the sera was eluted through a Sephadex G-200 column at the same position as the serum albumin. The addition of this substance to B cell rich spleen cell cultures in vitro in the presence of SRBC generated tremendous numbers of antibody forming cells 4 days after the incubation, suggesting that this substance was able to take over the helper function of T cells in thymus dependent antibody responses. However, this substance was not capable of stimulating 3H-thymidine-uptake into cultured spleen cells. The possible role of this substance in the adjuvant effect of LPS is discussed.     

Effects of antigen-feeding on intestinal and systemic immune responses. III. Antigen-specific serum-mediated suppression of humoral antibody responses after antigen feeding.

Feeding mice sheep erythrocytes (SRBC) caused a significant decrease in splenic IgM antibody responses to SRBC given ip. Reduced IgM responses were due to a suppressor factor in the serum of fed mice rather than due to a lack of IgM antibody-forming cell precursors or to the presence of suppressor T cells. Although feeding initially primed mice to produce greater IgA and IgG anti-SRBC responses after SRBC challenge, the initial primed state was transitory. Mice fed SRBC for longer than 8 weeks had significantly reduced splenic IgG and IgA responses after SRBC challenge.Suppression of IgM responses by serum from fed mice was antigen-specific and not H-2 restricted. Serum from fed mice inhibited the induction of IgM anti-SRBC responses but did not block the expression of already established responses. The size of the suppressor factor and the ability to remove suppressor activity from serum by anti-mouse immunoglobulin suggested that suppression was mediated by antibody. However, the determinants against which the antibody was directed appeared to differ among batches of suppressor sera. Suppressor activity did not appear to be mediated by immune complexes, or soluble antigen. Oral feeding of antigen can have a marked influence on host systemic immune responses when the antigen used for feeding is subsequently administered parenterally. Thus, oral antigen administration may provide a way for specifically manipulating systemic immune responses in vivo. In addition, antigen-feeding may provide a means for producing transferable factors that suppress humoral antibody responses.     

The enhancement of humoral and cellular immune responses by dimethyldioctadecylammonium bromide

Dimethyldioctadecylammonium bromide (DDA) produced marked enhancement of both cellular and humoral immune responses to SRBC when administered to mice intraperitoneally, or of cellular immunity when given subcutaneously. Stimulated cellular responses were seen as increased footpad swelling as a measure of delayed hypersensitivity and increased antigen-induced blastogenesis. Elevation of humoral response was reflected in increased numbers of splenic plaque-forming cells (PFC) and in circulating anti-SRBC antibody. Adjuvancy did not depend on addition of the lipid of DDA to antigen, as both humoral and cellular responses were enhanced whether DDA and SRBC were admixed or injected separately 4 hr apart intraperitoneally. DDA also enhanced the PFC response to the T-cell independent antigen TNP-LPS. The DDA effects are accompanied by macrophage activation, which may mediate at least in part the observed responses. DDA-activated macrophages exhibit fast spreading, are highly phagocytic, and elaborate significantly greater amounts of thymocyte mitogenic factor(s) than do normal resident peritoneal macrophages. This activation may effect the stimulation of antigen-specific primary lymphocyte responses by adjuvant and expansion of memory-cell populations which lead to the observed enhancement of secondary responses.     

Studies of mouse immunoglobulin allotypes by reverse plaque assay: Detection of spleen cells secreting immunoglobulins with specific allotype in C57BL/6J mice

A reverse hemolytic plaque assay for the detection and enumeration of mouse spleen cells secreting immunoglobulins bearing a particular allotypic specificity is described. Sheep red blood cells (SRBC) coated with protein A or anti-mouse gamma globulin antibody were employed as indicator cells and an anti-allotype antibody was used as developer. A comparison of the efficiency of protein A, goat anti-mouse or rabbit anti-mouse gamma globulin antibody-coated SRBC as indicator cells in the plaque assay indicated that the rabbit anti-mouse gamma globulin-coated SRBC gave the best results in terms of number and morphology of the plaques. The number of indicator cells in the assay mixture also significantly affected the quality of the plaques formed. When the mouse spleen cells were assayed with the indicator cells and an anti-allotypic antibody as developer in presence of complement in a liquid medium, only those cells secreting the immunoglobulin of the given allotypic specificity formed hemolytic plaques.     

Complement Receptors 1 and 2 in Murine Antibody Responses to IgM-Complexed and Uncomplexed Sheep Erythrocytes

Early complement components are important for normal antibody responses. In this process, complement receptors 1 and 2 (CR1/2), expressed on B cells and follicular dendritic cells (FDCs) in mice, play a central role. Complement-activating IgM administered with the antigen it is specific for, enhances the antibody response to this antigen. Here, bone marrow chimeras between Cr2(-/-) and wildtype mice were used to analyze whether FDCs or B cells must express CR1/2 for antibody responses to sheep erythrocytes (SRBC), either administered alone or together with specific IgM. For robust IgG anti-SRBC responses, CR1/2 must be expressed on FDCs. Occasionally, weak antibody responses were seen when only B cells expressed CR1/2, probably reflecting extrafollicular antibody production enabled by co-crosslinking of CR2/CD19/CD81 and the BCR. When SRBC alone was administered to mice with CR1/2(+) FDCs, B cells from wildtype and Cr2(-/-) mice produced equal amounts of antibodies. Most likely antigen is then deposited on FDCs in a way that optimizes engagement of the B cell receptor, making CR2-facilitated signaling to the B cell superfluous. SRBC bound to IgM will have more C3 fragments, the ligands for CR1/2, on their surface than SRBC administered alone. Specific IgM, forming a complex with SRBC, enhances antibody responses in two ways when FDCs express CR1/2. One is dependent on CR1/2(+) B cells and probably acts via increased transport of IgM-SRBC-complement complexes bound to CR1/2 on marginal zone B cells. The other is independent on CR1/2(+) B cells and the likely mechanism is that IgM-SRBC-complement complexes bind better to FDCs than SRBC administered alone. These observations suggest that the immune system uses three different CR1/2-mediated effector functions to generate optimal antibody responses: capture by FDCs (playing a dominant role), transport by marginal zone B cells and enhanced B cell signaling.     

Differences in the receptor apparatus of resident and meat-peptone broth-stimulated macrophage populations detectable under the action of salmozan

The degree of expression of lectin-like receptors in resident (RPM) and peptone-elicited peritoneal macrophages (PE-PM) using salmozan as polysaccharide was investigated. Obtained results allow to suppose that salmozan screens lectin-like receptors in macrophages and SRBC. The salmozan screening of lectin-like receptors in macrophages and SRBC resulted in decrease of SRBC uptake level in RPM-subpopulation but did not alter it in PE-PM-subpopulation. The same effect was occurred with the intensified erythrocyte loading of this macrophage subpopulations. It is suggested that one of the functional differences of studied macrophage subpopulation consists in the largest expression of lectin-like receptors in RPM-subpopulation.     

Effects of carrageenan on immune responses. Studies on the macrophage dependency of various antigens after treatment with carrageenan.

Carrageenan, a sulfated polygalactose having macrophage toxic properties, elicited a marked suppression of IgM response to T cell-dependent antigens such as sheep red blood cells (SRBC), dinitrophenylated bovine serum gamma-globulin (DNP-BGG), and trinitrophenylated concanavalin A (TNP-Con A). In contrast, carrageenan did not inhibit antibody responses to such T cell-independent antigens as trinitrophenylated DEAE-dextran (TNP-DEAE-dextran), trinitrophenylated polyvinyl pyrrolidone(TNP-PVP), and trinitrophenylated Ficoll (TNP-Ficoll). Compared to total spleen cells, spleen cells from which macrophages had been removed by adhesion to plastic Petri dishes had less effect on the production of antibody against T cell-dependent antigens, but no change or a rather stimulated effect was observed in in vitro antibiody synthesis against T cell-independent antigens. These results strongly suggest that macrophages are involved in antibody responses to T cell-dependent antigens but not in those to T cell-independent antigens. However, the antibody response to trinitrophenylated lipopolysaccharide (TNP-LPS), a T cell-independent antigen, was inhibited by carrageenan treatment, suggesting that the response is macrophage dependent. Moreover, antibody response to higher doses of dinitrophenylated phytohemagglutinin (DNP-PHA), a T cell-dependent antigen, was shown to be macrophage independent by carrageenan treatment, although the antibody response to low doses of the antigen was macrophage dependent. Considering all these results, carrageenan treatment seems to be a very useful method to determine whether immune response to various antigens are macrophage dependent or not.     

Immunoregulation in the rat: cellular and molecular requirements for B cell responses to types 1, 2, and T-dependent antigens

The requirements for primary in vitro plaque-forming cell (PFC) development in cultures of purified rat splenic B cells have been examined. Rat B cells were directly responsive to the type 1 antigen trinitrophenyl-Brucella abortus (TNP-BA), but both T cells and adherent accessory cells were required for B cell responses to the type 2 antigen TNP-Ficoll and the T cell-dependent (TD) antigen sheep erythrocytes (SRBC). However, the cellfree supernatants from concanavalin A-induced spleen cells of rat or mouse origin replaced the requirement for T cells and macrophages, and resulted in PFC development in response to TNP-Ficoll and SRBC and augmented PFC numbers in response to TNP-BA. Culture supernatants from induced murine T cell and macrophage cell lines were used to partially deduce the molecular requirements for the support of PFC development by rat B cells to these three antigens. Supernatants from the EL-4 (EL-4 sup) and B151 K12 (B15 sup) T cell lines augmented TNP-BA responses, suggesting that B cell growth factor II (BCGF-II) mediated this effect. An admixture of purified interleukin 2 (IL 2) and B15 sup supported PFC development to SRBC; indicating that IL 2, BCGF-II, and the T cell-replacing factor in B15 sup (B15-TRF) were sufficient to support this response. In addition, the IL 2 plus B15 sup-supported anti-SRBC PFC response was increased by the addition of an interleukin 1-containing fraction from the supernatant of the macrophage line P388D1. PFC development in response to TNP-Ficoll had the most stringent requirements and only occurred in the presence of EL-4 sup and B15 sup (IL 2, BCGF-I, BCGF-II, EL-TRF, B15-TRF). These data indicate that different cellular and molecular requirements exist for PFC development in response to types 1, 2, and TD antigens by rat B cells.