The alveolar macrophage: Its capacity to act as an accessory cell in mitogen-stimulated proliferation of guinea pig lymphocytes

The capacity of the alveolar macrophage to act as an accessory cell in PHA-induced lymphocyte proliferation was investigated and compared with that of the peritoneal and peritoneal exudate macrophages in guinea pigs. When lymph node cells were co-cultured with autologous lung cells recovered by airway lavage, the proliferative response to PHA was greatly enhanced over that of lymph node cells alone. In the presence of peritoneal cells or peritoneal exudate (glycogen-induced) cells, the PHA response was intermediate between that of lymph node cells alone and lymph node cells cultured with lung cells. Experiments using purified macrophages (≥98%) as accessory cells demonstrated that the difference observed between lung and peritoneal accessory cells was due to differences in macrophage function. Furthermore, when lymph node cells were cultured in the upper chamber of a double-chambered Marbrook apparatus, PHA-induced proliferation was enhanced only when lung and not peritoneal macrophages were present in the lower chamber. Additional experiments showed that this difference (1) was not an artifact of the thymidine incorporation assay to measure proliferation; (2) was not affected by changing the macrophage-lymphocyte ratio; and (3) was not simply a trephocytic or growth promoting effect of macrophages which could be replaced by 2-mercaptoethanol.These findings show that macrophages from different sources differ in their abilities to act as accessory cells in PHA-induced lymphocyte proliferation. Alveolar macrophages appear to have an enhanced capacity compared to unstimulated and stimulated peritoneal macrophages in this function. At least part of this difference may be due to a difference in the elaboration of soluble factor (s) by macrophages.     

Macrophages in resistance to rickettsial infection: susceptibility to lethal effects of Rickettsia akari infection in mouse strains with defective macrophage function

We have confirmed the requirement of macrophages in the antigen-induced T-lymphocyte proliferative response and in the generation of migration inhibition factor (MIF) by immune lymphocytes. Extending these observations, we have found that autologous and non-syngeneic, oil-induced peritoneal exudate macrophages were equally effective in restoring the proliferative response and MIF production by column-purified lymph node T cells. MIF activity was optimally restored when T cells were reconstituted with 1 to 40% exudate-derived macrophages whereas 10 to 30% macrophages were needed to optimally restore the T-cell proliferative response. Normal resident macrophages from the peritoneal cavity were also capable of restoring T-cell reactivity as were normal or BCG-activated pulmonary alveolar macrophages. It was also found that the addition of as few as 1.0% glycogen-elicited peritoneal exudate cells restored the production of MIF by T cells. Quantitative considerations demonstrated that the responsible cells in these preparations were polymorphonuclear cells rather than macrophages. In contrast, neither MIF production nor the proliferative response by T cells were restored by the addition of red blood cells. In these studies we were able to demonstrate that freeze-thawed macrophages could restore antigen-induced MIF production, but not antigen-induced cellular proliferation. The ability of freeze-thawed macrophages to stimulate T cells to produce MIF was apparently associated with the macrophage membranes and not with a soluble factor in the macrophage extracts. These results demonstrate that multiple sources of phagocytic cells may interact cooperatively with lymphocytes in reactions of cell-mediated immunity. Further, at least in the case of MIF production, this interaction involves a membrane-bound determinant that is effective even in the absence of viable macrophages.     

Possible role of macrophage glycolipids as receptors for migration inhibitory factor (MIF).

Guinea pig peritoneal exudate cells incubated with water soluble glycolipids obtained from macrophages show an enhanced response to migration inhibitory factor. Incorporation of these glycolipids into liposomes greatly facilitates their interaction with indicator cells. Enhancement of peritoneal exudate cell responsiveness to migration inhibitory factor was specific for glycolipids from guinea pig macrophages. Glycolipids extracted from guinea pig brain and polymorphonuclear leukocytes as well as several bovine and porcine glycolipids had no effect. Specificity of enhancement was not due merely to a preferential association of macrophage glycolipids with indicator cells. The possible role of macrophage glycolipids as receptors for MIF is discussed.     

The role of the macrophage as the stimulator cell in contact sensitivity.

In this study we examined the requirement for the type of stimulator cell for thymus-derived (T) lymphocyte activation to simple chemical haptens. T cells from picryl chloride-immune guinea pigs were challenged in vitro with various trinitrophenyl (TNP)-conjugated syngeneic stimulator cells and the extent of activation was determined by an increase in DNA synthesis. Hapten-specific T cell activation occurred with TNP-conjugated peritoneal exudate cells (PEC) and purified macrophages but not with TNP-conjugated erythrocytes, thymocytes, or nonadherent lymph node cells or PEC. In addition, T cell activation also occurred with TNP-conjugated guinea pig leukemia cells, but only in the presence of macrophages. Furthermore, it was shown that macrophages were required to process and/or present TNP-conjugated leukemia cell antigens rather than simply providing a growth-promoting function. These results suggest that a macrophage-like stimulator cell is required for hapten-specific T cell activation and that this particular stimulator cell may be important in contact sensitivity.     

Macrophage activation of allogeneic lymphocyte proliferation in the guinea pig mixed leukocyte culture.

The role of the macrophage in the guinea pig mixed leukocyte culture was investigated. Macrophages obtained from oil-induced peritoneal exudates, peritoneal wash-out cells, spleen, and alveolar washings were found to be effective stimulators of allogeneic lymph node and splenic lymphocyte DNA synthesis. The stimulatory properties of macrophages proved radioresistant but viability dependent. Unfractionated lymph node cells or adherence column purified lymph node lymphocytes and thymocytes were only minimally active as stimulators, even in the presence of macrophages syngeneic to the responder lymphocytes. Allogeneic fibroblasts, polymorphonuclear leukocytes, L2C leukemia cells, and xenogeneic (murine) macrophages failed to simulate. These data provide evidence that the macrophage is the predominant stimulator of the mixed leukocyte culture in the guinea pig.     

Eosinophils and immune mechanisms. III. Production of the lymphokine eosinophil stimulation promoter by mouse T lymphocytes.

The lymphoid cell population responsible for production of eosinophil stimulation promoter (ESP), a lymphokine which increases migration of eosinophils, was investigated in murine Schistosoma mansoni infection. Con A challenge induced ESP production, whereas LPS did not. Prior treatment with anti-thetaC3H alloantiserum plus complement in vitro eliminated ESP production; in vivo treatment with rabbit anti-mouse thymocyte serum consistently reduced ESP production by splenic lymphoid cells, but affected lymph node cell ESP production only after exceptionally large doses. Thymocytes did not produce significant amounts of ESP; nor did lymphoid cells from congenitally athymic mice. Depletion of B lymphocytes and macrophages by nylon fiber adherence eliminated antigen-induced ESP production; this was partially restored by addition of non-immune, 72-hr peritoneal exudate cells. Con A-induced ESP production was not affected by nylon fiber treatment. These results demonstrate that ESP is produced by an ATS-sensitive, peripheralized T lymphocyte population, and suggest a macrophage requirement for antigen-induced production of this lymphokine.     

Reversal of macrophage-augmented MLR reactivity by tumor-induced splenic suppressor T cells and their soluble factor(s)

Augmenting concentrations of macrophages or their supernatants failed to reverse T-cell hyporeactivity in tumor-bearing mice (TBM). Serial passaging over nylon wool columns depleted TBM spleen cells of a mildly adherent tumor-induced suppressor cell and restored mixed lymphocyte reaction (MLR) reactivity to the purified TBM T-cell population. The tumor-induced suppressor cell was extensively plated to remove macrophages and characterized as a T cell by its anti-Thy 1 serum sensitivity. This suppressor T cell, when added to normal T cells, abrogated all enhancing effects caused by addition of macrophages. Suppressor T-cell inhibition was non-contact dependent, since suppressor T-cell supernatants inhibited MLR activity in T cells treated with enhancing concentrations of macrophage supernatants. Thus it appears that tumor-induced T-cell debilitation is a reversible phenomenon, mediated not by macrophages but by soluble factor(s) from a nonphagocytic, mildly adherent, suppressor T cell.     

The activation of guinea pig T lymphocytes by anti-beta 2-microglobulin serum.

In order to study further the role of beta 2-m in the regulation of the immune response, we have examined the effects of a goat anti-guinea pig beta 2-m serum on a number of T lymphocyte functions in vitro. Anti-beta 2-m serum produced a marked inhibition of the response of peritoneal exudate T cells to antigen and mitogen stimulation. Surprisingly, a marked activation of lymph node T lymphocyte proliferation was observed in the absence of antigen or mitogen stimulation. This stimulatory effect of anti-beta 2-m serum was shown to be specific for beta 2-m and required the presence of macrophages. The T cell proliferative response induced by anti-beta 2-m could not be blocked by antisera to the antigens of the guinea pig MHC. These studies suggest that beta2-m may play some critical role in the immune response at the level of T cell activation.     

Effect of injection of adult mouse peritoneal macrophages on suppressor cell activity in neonatal mice

Injection of adult mouse peritoneal exudate cells into newborn mice results in a premature decrease of splenic suppressor cell activity in the neonates. The effect becomes apparent 4–5 days after ip injection of 10–15 × 10⁶ thioglycollate-induced peritoneal exudate cells into mice on the day of birth. The macrophage in the peritoneal exudate is the responsible cell type. The effect is not H-2 restricted or strain limited. Heat-killed peritoneal exudate cells or peritoneal cells from unstimulated donors can also decrease neonatal suppressor cell activity prematurely. Adult spleen cells, injected into neonatal mice, do not affect suppressor cell activity. The data are discussed in light of the hypothesis that macrophages control suppressor activity in neonatal mice and that an increase in the number and/or function of macrophages shortly after birth results in a decrease in the number and/or function of suppressor cells, allowing for immunological competence to emerge.     

Guinea pig T-cell in vitro proliferative responses to tyrosine-azobenzenearsonate-pulsed and azobenzenearsonate-coupled macrophages have different specificities

The cell interactions involved in azobenzenearsonate-N-acetyl-tyrosine (ABA-tyr)-induced delayed hypersensitivity in the guinea pig were studied by in vitro blastogenesis. The ABA-sensitive lymphocyte was demonstrated to be a T lymphocyte and its presence in peritoneal exudate cells was shown to be much higher than spleen or lymph node populations. The secondary response of ABA-sensitized lymphocytes to ABA-tyr in culture is dependent on the presence of an accessory cell, with both splenic and peritoneal macrophages being equally effective. ABA coupled directly to macrophages as an immunogen induced strong responses to itself and not to ABA-tyr-pulsed macrophages or ABA-tyr in solution. The reverse was true in animals, immunized with ABA-tyr. ABA conjugated to thymocytes, L₂C leukemia cells, and guinea pig erythrocytes however, did not elicit significant responses. The results obtained in animals immunized with ABA- or ABA-tyr-modified cells was similar whether or not CFA was used. The difference in specificity shown between ABA-coupled and ABA-tyr-pulsed macrophages favors a single receptor hypothesis for T-cell recognition.     

Stimulation of guinea pig macrophage pinocytosis by lipopolysaccharides (LPS): Evidence that LPS acts directly on the macrophage

Bacterial lipopolysaccharide can enhance the pinocytosis of horseradish peroxidase in guinea pig macrophages. This increased uptake can be seen as early as 6 hr after incubation in a spinner suspension culture. An equivalent amount of enhanced pinocytosis can be seen if plated, washed peritoneal exudate macrophages are used. Plated guinea pigs PECs, washed five times, were examined for the presence of B cells, and none were found. Thus, LPS appears to stimulate the macrophage directly and does not require a lymphocyte intermediary. The active stimulatory moiety appears to be lipid A, which can be blocked by preincubation of LPS with polymyxin B.     

Effect of capsular polysaccharide of Klebsiella pneumoniae on the differentiation and functional capacity of macrophages cultured in vitro.

The effect of the capsular polysaccharide of Klebsiella pneumoniae (CPS-K) on the differentiation and functional capacity of macrophages cultured in vitro from various lymphoid tissues was investigated. In cultures of peritoneal cells, the number of macrophages did not change throughout incubation periods of from 1 hr to 3 days, and the addition of CPS-K had no affect. It appears therefore that CPS-K does not exhibit cytotoxic effects on macrophages. In cultures of spleen cells, only a small number of macrophages appeared within 1 hr, but the number of macrophages increased during further incubation. The addition of CPS-K to cultures of spleen cells at the start of incubation suppressed markedly the increase in the numbers of macrophage. This finding indicates that CPS-K blocks the process of the generation of macrophages, probably from their precursor cells in cultures of spleen cells. Only a small number of macrophages appeared in cultures of thymocytes or lymph node cells either with or without CPS-K. The phagocytic capacity of either peritoneal macrophages or macrophages generated in cultures of spleen cells was activated during incubation in vitro. Macrophages cultured in the presence of CPS-K for 24 hr or longer appeared to have an enhanced phagocytic activity, although the enhancement of their phagocytic activity by the addition of CPS-K was less marked in cultures of spleen cells than in those of peritoneal macrophages. Morphologically, macrophages in both cultures of peritoneal cells and spleen cells incubated in the presence of CPS-K for 4 days possessed much longer cytoplasmic processes than those incubated in the absence of CPS-K. From the present study, it appears that CPS-K exhibits dual effects on macrophage precursor cells and macrophages, a blocking effect on the differentiation from the former to the latter and an enhancing effect on the functional capacity of the latter.     

Specific immunosuppression by passive antibody. V. Participation of macrophages in reversal of suppression by peritoneal exudate cells from immune animals

Thioglycollate-stimulated peritoneal exudate cells (PEC), harvested from mice immunized against sheep erythrocytes (SRBC) and transferred to normal syngeneic recipients, reverse the immunosuppression caused by passively administered anti-SRBC antibody. Macrophages purified from PEC on BSA gradients did not reverse immunosuppression; neither did suspensions of cells from mesenteric lymph nodes of immune mice. Mixtures of the purified macrophages and lymph node cells were fully capable of reversing immunosuppression. Thus, two types of cell, one a macrophage and one a lymphocyte, are required. Both must be compatible with the recipient mice at the H-2 complex. However, only the macrophages must necessarily be obtained from an immune donor. When “immune” macrophages were preincubated in vitro with “normal” lymph node cells before transfer to antibody-treated syngeneic recipients, a significant reversal of the immunosuppressive effect occurred. The ability of whole PEC or spleen cells to reverse the immunosuppressive effect of passive antibody is acquired rapidly after injection of a single low dose of antigen. Development of this ability precedes the appearance, in the circulation, of immunosuppressive antibody.     

Changes in lymphocyte subsets and macrophage functions from high, short-term dietary ethanol in C57/BL6 mice

Chronic administration of a diet containing 7% ethanol (36% of total calories) for 8 days to male C57/BL6 mice resulted in significant changes in functioning of macrophages. Peritoneal exudate macrophages from the ethanol-fed mice released more tumor cell cytotoxic materials upon culturing in vitro than cells from controls. However, peritoneal exudate cells continued to respond to exogenous beta carotene in vitro to produce additional cytotoxic materials. Phagocytosis of sheep red blood cells in vitro was suppressed in cells from ethanol treated mice. The number of splenic lymphocytes of various subsets was significantly changed by the ethanol exposure. Total T cells and T suppressor cells were lower, with a significant decrease in B cells containing IgM on their surface. The percentage of spleen cells showing markers for macrophage functions and their activation were significantly reduced. It is concluded that short-term chronic consumption of dietary ethanol, which was sufficient to produce physical dependence, results in significant alterations in lymphocyte subtypes and suppression of some macrophage functions.     

Site of action of a soluble immune response suppressor (SIRS) produced by concanavalin A-activated spleen cells.

The cellular site of action of SIRS, a soluble immune response suppressor released by Con A-activated spleen cells which suppresses antibody responses to heterologous erythrocytes by murine spleen cells in vitro, was investigated. Exposure of spleen cells to SIRS for 2 hr at 37 degrees C or 1 hr at 4 degrees C was sufficient to suppress 5-day antibody responses in vitro. Similar exposure of splenic or peritoneal exudate macrophages to SIRS also suppressed antibody responses by untreated splenic lymphoid cells; exposure of splenic lymphoid cells to SIRS was without effect. SIRS did not act via T cells which might have contaminated the macrophage preparations. SIRS-mediated suppression could be partially overcome by an excess of normal peritoneal exudate macrophages, but not by an excess of T or B cells. These data indicate that the target cell of SIRS activity is the macrophage. The results are discussed in the context of macrophage functions that could be affected by SIRS.     

Participation of lymphocyte activating factor (Interleukin 1) in the induction of cytotoxic T cell responses

The initiation of murine alloantigen-specific cytotoxic T cell responses is macrophage dependent. The requirement for macrophages can be replaced in macrophage-depleted cytotoxic T lymphocyte assay by a soluble factor released from phorbol myristic acetate-stimulated mouse peritoneal adherent cells or P388D1 macrophage tumor cells. On the basis of the cell of origin, m.w. (15,000), and elution profiles on DEAE cellulose and polyacrylamide gels, this macrophage-replacing factor for T cell-mediated cytotoxicity was identical to lymphocyte activating factor (LAF). The stimulatory effect of LAF was totally dependent on the presence of the priming alloantigen. The results presented in this report support the hypothesis that macrophage-mediated antigen-induced T cell activation is dependent on two signals, antigen and LAF.     

Absolute macrophage dependency of T lymphocyte activation by mitogens.

A T lymphocyte subpopulation that contains only 0.3% macrophages and less than 2% B lymphocytes has been prepared from guinea pig lymph node cells by the use of two different types of adherence columns. This subpopulation does not porliferate in response to the mitogens Con A or PHA unless additional macrophages are added. The means by which macrophages restore T cell responsiveness to PHA has been investigated. Marcophages appear to function via two different distinct mechanisms in this experimental situation. The first mechanism involves the binding of PHA to the macrophage followed by the "presentation" of the mitogen to the T lymphocyte in a manner that induces cell activation. This presentation function requires that the macrophage be viable and metabolically active. The second mechanism by which macrophages function is by the elaboration of a soluble factor or factors. The presence of these factors has been reliably and reproducibly demonstrated by using a double-chambered, Marbrook-type tissue culture vessel. This soluble factor can induce activation of T lympohcytes with surface bound PHA in the apparent absence of any form of macrophage presentation. In contrast, the function of this factor is clearly distinct from that of the reducing agent, 2-mercaptoethanol, (2-ME) since 2-ME does not enable this T cell subpopulation to be activated by mitogens. On the basis of these observations, we propose that two distinct signals are required to activate this T lymphocyte subpopulation. One signal is delivered by the interaction of the mitogen with the T cell surface, and the second signal is delivered by a soluble factor(s) produced by macrophages. Whether all types of T lymphocytes require two signals to be activated, remains to be established.     

A novel guinea pig macrophage-specific polymorphic molecule. I. Biochemistry, genetics, and tissue distribution

In the course of studying Ia molecules from strain 2 and strain 13 guinea pig macrophages, with the intent of comparing them to B cell Ia molecules, it was observed that guinea pig alloserum prepared by cross-immunization of guinea pig lymphocyte Ag non-identical inbred guinea pigs immunoprecipitated not only conventional class I and class II molecules, but also a 98,000-Da molecule, termed gp98. Two different forms of the molecule were detected, indicating it is polymorphic. The genes encoding gp98 were shown not to be linked to the guinea pig lymphocyte Ag complex. The molecule gp98 was found on macrophages within populations of peritoneal exudate cells, resident peritoneal cells, bone marrow cells, and spleen. All gp98-bearing macrophages were also Ia-positive. However, only a subpopulation of macrophages bore gp98. The gp98 was not found on Ly-1 or Ig-bearing cells, indicating that B and T cells do not bear Ia. Thus, gp98 appears to be a highly immunogenic polymorphic macrophage-specific molecule that allows the characterization of guinea pig macrophage subsets.     

Antigen-specific T cell cluster formation on antigen-pulsed macrophage monolayers in mice

We describe the quantitative measurement of antigen-specific clusters formed by antigen-pulsed macrophages and immunized T cells in mice. We have found the peripheral blood T cells show very little non-specific adhesion to macrophages in mice. By using this population of lymphocytes in the peripheral blood as the source of immunized T cells, we could quantitate antigen-specific cluster formation. On OVA-pulsed monolayers of peritoneal exudate macrophages from normal BALB/c mice, syngeneic peripheral blood T cells from donors immunized with the same antigen develop 20-40 clusters per 1,000 macrophages, whereas the same T cells on non-pulsed monolayers develop only 0-5 cluster-like accumulations of cells. On antigen-pulsed monolayers of macrophages from allogeneic (C57BL/6 or A/J) mice, clusters are developed only in the negative range (0-5/1,000 macrophages). Considering the observation by Braendstrup et al, these data seem to suggest that histocompatibility between macrophages and T cells is required to develop antigen-specific T cell clusters on antigen-pulsed macrophage monolayers, and that the genetic restriction of immune responsiveness may be directly expressed in this initial form of cellular interaction between antigen-bearing macrophages and specific T cells.     

Staphylococcal enterotoxin B induced release of macrophage migration inhibition factor from normal lymphocytes

Staphylococcal enterotoxin B (SEB), a potent lymphocyte mitogen, inhibits migration of peritoneal exudate cells from most guinea pigs but does not inhibit migration of purified macrophages. Experiments were designed to test the ability of highly purified SEB to induce normal lymphocytes to release migration inhibition factor (MIF). Supernatants of lymph node lymphocytes cultured with SEB inhibited the migration of purified macrophages, indicating the release of a migration inhibition factor. Mitomycin-C blocked the SEB-induced release of MIF. SEB-induced MIF localized in the albumin fraction on Sephadex G-200 chromatography. Antibody to SEB specifically blocked the inhibitory effect of SEB on migration of normal guinea pig peritoneal exudate cells.