Generation of macrophage chemotactic activity in situ in Listeria-immune rats.

Macrophage chemotactic activity (MCA) is generated in situ in peritoneal inflammatory exudates induced by antigens of the intracellular parasite, Listeria monocytogenes. Chemotactic and chemokinetic activity is formed locally in response to an immunologically specific signal. In rats that have been immunized adoptively with thoracic duct lymphocytes (TDL) from specifically immunized donors, the production of MCA depends upon stimulation by LMA of exudate-seeking S-phase lymphocytes of their progeny. The sequential appearance, increase, and subsequent decline of MCA in the peritoneal cavity parallels the influx of lymphocytes and precedes maximal recruitment of labeled monocytes from the blood. The MCA response in peritoneal exudates induced in adoptively immunized rats correlates with the level of macrophage accumulation in the peritoneal cavity and at sites of LMA injection in the pinna of the ear. The results suggest that MCA is released locally by antigen-activated lymphocytes and imply that the factor(s) concerned has a purposeful role in the host's defense by promoting the rapid deployment and/or retention of monocyte-derived macrophages in centers of infection.     

The mediator of cellular immunity. VIII. Effect of mitomycin C on specifically sensitized lymphocytes.

The antimitotic agent, mitomycin C, was used to probe cellular events underlying the expression of acquired resistance to L. monocytogenes in the rat. It was found that thoracic duct lymphocytes from donors primarily immunized with this organism can protect normal recipients against a Listeria challenge and that their ability to do so is inhibited by treatment of the lymphocytes with mitomycin C. Concentrations of the drug which are effective in this regard also inhibit lymphocyte proliferation, but have little if any effect upon RNA or protein synthesis in cells tested at the time of transfer. Yet mitomycin C probably has irreversible effects on lymphocytes in addition to its capacity to block cell replication, for inhibitor-treated immunoblasts fail to localize in peritoneal exudates induced in recipient rats. The inability of mitomycin-treated immunoblasts to extravasate in inflammatory foci is associated with a diminished capacity of specificially sensitized lymphocytes to promote cell division in peritoneal exudates induced by L. monocytogenes. The results illustrate the importance of lymphocyte-macrophage interactions in cellular resistance to infection and give credence to the view that these interactions occur locally at sites of microbial invasion.     

Leishmania enriettii: Immune induction of macrophage activation in an experimental model of immunoprophylaxis in the mouse

This study describes some of the parameters of the cellular immune response elicited in mice by inoculation of the nonpathogenic protozoan parasite, Leishmania enriettii. Incubation in vitro of leishmania-infected mouse peritoneal macrophages with spleen cells from syngeneic leishmania-immune animals resulted in activation of the phagocytes, leading to intracellular parasite destruction. Activation required interaction of sensitized lymphocytes with parasite antigen released or displayed by infected macrophages. The effect was dependent both on the dose of parasites used for in vivo priming and on the number of spleen cells cocultivated with parasitized macrophages. The activating capacity of lymphocytes was abrogated by anti-Thy-1 antiserum treatment and was retained in the effluent cells after nylon-wool separation. Activation was followed by lysis of part of the macrophage monolayer. Destruction of the phagocytes did not appear to result from the activation process per se and may represent a cytotoxic activity of sensitized lymphocytes for macrophages bearing parasite antigen on their surface.     

The mediator of cellular immunity: XI. Origin and development of MIF producing lymphocytes

Thoracic duct lymphocytes obtained from rats infected with Listeria monocytogenes were characterized with respect to size, turnover and their capacity to release macrophage migration inhibitory factor (MIF). Cells responsive to Listerial antigens (LMA) in the MIF assay were identified in lymph during the first week of an immunizing infection. These were immunoblasts or large lymphocytes, as evidenced by their sedimentation with S phase lymphocytes at unit gravity. When labeled cells from the lymph of Listeria-infected donors were infused into similarly infected recipients, donor S phase lymphocytes localized rapidly, and in substantial numbers, in peritoneal exudates induced by the unrelated organism, F. tularensis. Within this immigrant population were cells which conferred immunity against L. monocytogenes and released MIF in cultures containing LMA. Exudates harvested 36 hr or 61 hr after stimulation contained labeled lymphocytes that were smaller than the S phase cells recovered during the early post-induction period. The observed shift of radioactivity from large to smaller lymphocytes was parallelled by a shift MIF production to exudate fractions containing smaller cells. The MIF producing cells in exudates of advancing age also exhibited increasing resistance to inhibition by vinblastine. These findings suggest that MIF is released by a family of lymphocytes—large, medium and small. LMA-responsive lymphocytes are delivered to the thoracic duct soon after their formation, at a stage in development when they can be stimulated to release only low levels of MIF. These mediator producing cells circulate briefly in the blood and differentiate fully only after they extravasate into inflammatory foci.     

The mediator of cellular immunity. IV. Cooperation between lymphocytes and mononuclear phagocytes

Acquired resistance to an intravenous infection with Listeria monocytogenes involves the interaction of two cell types: specifically committed lymphocytes and monocyte-derived macrophages. This interaction was revealed in experiments using the polyfunctional alkylating agent, cyclophosphamide. Cyclophosphamide is toxic for both lymphocytes and blood monocyte antecedents. Rats treated with cyclophosphamide were immunized adoptively with cells obtained from the thoracic duct lymph of Listeria-immune donors. But such animals benefited from a lymphocyte injection only while they could assemble monocyte-derived macrophages in an inflammatory exudate. The results imply that blood monocytes provide an essential element to the host's defense mechanism against intracellular bacterial parasites, and that monocyte-derived macrophages are the instruments through which cellular resistance to infection is expressed.     

Enhancement of macrophage bactericidal capacity by antigenically stimulated immune lymphocytes

The ability of antigenically stimulated immune lymphocytes to influence the bactericidal capacity of normal macrophages was studied in vitro. Purified lymphocytes were obtained from the lymph nodes and peritoneal exudates of guinea pigs immunized with bovine gamma globulin (BGG) and from control animals. Immune and control lymphocytes were added to normal macrophages and incubated overnight in the presence or absence of BGG. After washing, the macrophage monolayers were infected with Listeria monocytogenes; 4 hr later, the cells were lysed and the surviving intracellular bacteria quantitated. The macrophages which had been incubated with BGG-immune lymphocytes in the presence of BGG displayed a markedly enhanced listericidal capacity. In parallel experiments, these same antigen-stimulated lymphocytes were shown to inhibit the migration of normal macrophages. Lymphocytes derived from peritoneal exudates were more active than lymph node lymphocytes in both assays.     

Mitogenic factor from inbred guinea pigs. II. Properties of the factor

Thymectomized adult rats which have been heavily irradiated and reconstituted with syngeneic bone marrow cells rapidly regain the ability to defend themselves against a primary infection with the intracellular bacterial parasite, Listeria monocytogenes. They do so by a cell-mediated immunological mechanism as evidenced by the protective immunity transferred adoptively by thoracic duct lymphocytes or peritoneal exudate cells from donors infected with this organism. But peritoneal exudate cells from thymus-derived donors convey only a fraction of the immunity transmitted by exudate cells from similarly infected intact rats. Since thymectomized irradiated animals can mobilize their cellular defenses more effectively when they are injected with a modest number of thoracic duct lymphocytes, an effect that cannot be duplicated with a massive infusion of bone marrow, it is argued that thymusdependent lymphocytes or T cells have an influential role in the development of cellular resistance to infection.     

Dissociation of macrophage accumulation and local chemotactic activity in delayed inflammatory sites.

A dissociation between the in situ generation of lymphocyte-dependent macrophage chemotactic activity (MCA) and the accumulation of macrophages in peritoneal inflammatory exudates was demonstrated in rats stimulated intraperitoneally with a saline suspension of killed Listeria monocytogenes (LM). Treatment of specifically immunized animals with cobra venom factor (CoVF) erased the hemolytic activity of serum complement (C) and the generation of peritoneal MCA. Such C-deficient rats nonetheless marshaled a substantial number of monocyte-derived macrophages into LM-induced exudates. The results suggest that MCA does not have an obligatory role in the attraction of macrophages into lesions in which there is a delayed inflammatory component. CoVF not only abrogated lymphocyte-dependent MCA in antigen-induced exudates but also decreased MCA of fresh and of heated normal rat serum. The serum of venom-treated animals could not be rendered chemotactic by C activation. It remains to be determined whether lymphocyte-dependent MCA is a product of antigen-stimulated T cells or is generated extracellularly by the interaction of T-cell factors with a humoral precursor. In any event, lymphocyte-dependent MCA differs from C-dependent MCA insofar as it is inactivated by heating (30 min at 56 °C).     

Allogeneic restriction of the delayed inflammatory reaction in the rat.

Delayed-type hypersensitivity (DTH) to Listeria monocytogenes was measured in rats that were recipients of syngeneic, semisyngeneic, and allogeneic immune thoracic duct lymphocytes (TDL). DTH could be transferred only to recipients that shared at least one haplotype with the TDL donors. The restriction was expressed in an inability of sensitized lymphoblasts to localize efficiently at antigen injection sites in the pinna of the ear and peritoneal cavity. Failure of allogeneic lymphoblasts to extravasate in more than trace numbers into Listeria-antigen-induced exudates was reflected in an absence of other lymphocyte-mediated expressions of DTH. Thus, lymphocyte-dependent MCA was not detected in Listeria-antigen-induced peritoneal exudates borne by recipients of allogeneic immune TDL and blood monocytes were not recruited in increased numbers into such exudates as they were in exudates borne by syngeneic rats. But allogeneic restriction of the delayed inflammatory response to Listeria antigen was overcome, at least in part, when antigen-presenting macrophages of the same MHC type as the immune TDL donors were implanted in the peritoneal cavity. The results encourage the belief that the observed failure of immune TDL to transfer DTH to allogeneic recipients is related to the inability of sensitized donor T cells to recognize antigen displayed by allogeneic macrophages.     

Nonrecirculating memory T lymphocytes in cellular resistance to infection

Acquired resistance of rats to intracellular infection with Listeria monocytogenes rests on the cooperation between sensitized mediator lymphocytes and effector macrophages. Large numbers of specific T lymphoblasts, capable of transferring resistance to recipients, appear in central lymph shortly (3–6 days) after subcutaneous infection of rats. In contrast, late-phase immunity is poorly transferrable with thoracic duct lymphocytes (TDL) despite high levels of specific resistance observed in spleen, liver, and testes of actively immunized animals. That late-phase immunity is mediated partly by resident, nonrecirculating T cells is attested to by the ineffective transfer of resistance from preinfected to normal partners of parabiotic rats. Transfer studies with thoracic duct cells and peritoneal cells from the stimulated and unstimulated peritoneal cavity seem to suggest that resident T cells mediating late-phase resistance are the progeny of lymphoblasts that extravasated during early phase. Assays measuring the proliferative response upon antigen stimulation in vitro support the concept of a gradual redistribution within the animal of memory T cells.     

Nucleolin, a shuttle protein promoting infection of human monocytes by Francisella tularensis

Background

Francisella tularensis is a highly virulent facultative intracellular bacterium, disseminating in vivo mainly within host mononuclear phagocytes. After entry into macrophages, F. tularensis initially resides in a phagosomal compartment, whose maturation is then arrested. Bacteria escape rapidly into the cytoplasm, where they replicate freely. We recently demonstrated that nucleolin, an eukaryotic protein able to traffic from the nucleus to the cell surface, acted as a surface receptor for F. tularensis LVS on human monocyte-like THP-1 cells.

Methodology/Principal Findings

Here, we followed the fate of nucleolin once F. tularensis has been endocytosed. We first confirmed by siRNA silencing experiments that expression of nucleolin protein was essential for binding of LVS on human macrophage-type THP-1 cells. We then showed that nucleolin co-localized with intracellular bacteria in the phagosomal compartment. Strikingly, in that compartment, nucleolin also co-localized with LAMP-1, a late endosomal marker. Co-immunoprecipation assays further demonstrated an interaction of nucleolin with LAMP-1. Co-localization of nucleolin with LVS was no longer detectable at 24 h when bacteria were multiplying in the cytoplasm. In contrast, with an iglC mutant of LVS, which remains trapped into the phagosomal compartment, or with inert particles, nucleolin/bacteria co-localization remained almost constant.

Conclusions/Significance

We herein confirm the importance of nucleolin expression for LVS binding and its specificity as nucleolin is not involved in binding of another intracellular pathogen as L. monocytogenes or an inert particle. Association of nucleolin with F. tularensis during infection continues intracellularly after endocytosis of the bacteria. The present work therefore unravels for the first time the presence of nucleolin in the phagosomal compartment of macrophages.     

Binding and degradation of soluble immunoglobulin aggregates by mouse mononuclear phagocytes—Stimulation by colony-stimulating factor

The binding and degradation of soluble guinea pig IgG₂ aggregates by murine mononuclear phagocytes were studied. Bone marrow mononuclear phagocytes cultured in the presence of an embryonic fibroblast-conditioned medium (CM) degraded the aggregates to a much greater degree than did resident peritoneal macrophages. Binding and degradation by resident peritoneal macrophages were enhanced by culture in the presence of CM.Freshly harvested thioglycollate-induced peritoneal macrophages bound and degraded the aggregates to the same degree as the cultured bone marrow mononuclear phagocytes did. However, the thioglycollate-induced macrophages lost most of these capacities when cultured in vitro without CM. When CM was added to these cultures, the capacity to bind and degrade was restored in a dose-dependent fashion. To obtain the maximum effect, exposure to CM must be maintained for more than 2 days. The effect of CM could be reproduced with purified CSF-1. Taken together the results of this study indicate that Fc receptor expression is modulated by CSF-1.     

Effect of mononuclear phagocytes on the differentiation of syngeneic, allogeneic and xenogeneic hematopoietic stem cells

The colony formation in spleen of lethally irradiated syngeneic or hybrid recipients was studied after transplantation of bone marrow cells, with or without macrophages from lymph nodules or from peritoneal cavity of mice, cells of macrophage-like cell line J-774, and monocytes from peripheral blood of healthy donors. The direction of stem cell differentiations in the presence of all the types of mononuclear phagocytes was seen to change from mainly erythroid to mainly myeloid one. The ratio of erythroid to myeloid colonies became equal to 0.5-0.9 instead of 2.0, when bone marrow cells were injected with equivalent quantity of mononuclear phagocytes. This new regulatory function of mononuclear phagocytes is discussed.     

Enhancing and suppressive effects of macrophages on T-lymphocyte stimulation in vitro.

The immunoregulatory effect of peritoneal and splenic macrophages on Con A-stimulated mouse splenic T lymphocytes was investigated in vitro using [¹²⁵I]UdR incorporation as a measure of lymphocyte proliferation. [¹²⁵I]UdR incorporation was enhanced by the addition of increasing numbers of splenic or low doses of peritoneal adherent cells to macrophagedepleted splenic lymphocytes. The addition of increasing numbers of peritoneal macrophages beyond 5–10%, however, proportionally suppressed T-cell proliferation. Activated splenic macrophages obtained from mice 6 days after infection with Listeria monocytogenes were suppressive, whereas macrophages obtained from immune donors 9–10 days after infection were not, so that a chronological association appeared to exist between macrophage activation and immunosuppression. The addition of 2-mercaptoethanol to the cell cultures increased [¹²⁵I]UdR incorporation without affecting the stimulatory and suppressive effects of splenic and peritoneal macrophages, respectively. Heat-killed and freeze-thawed macrophages lost their capacity to enhance or inhibit lymphocyte transformation. Macrophages treated with mitomycin C to inhibit DNA synthesis retained their regulatory functions. These studies suggest differential regulatory roles for spleen versus peritoneal macrophages on T-lymphocyte responses to Con A stimulation in vitro.     

Macrophage growth inhibitors derived from the murine peritoneal cavity

Summary The murine peritoneal cavity contains factors that inhibit the in vitro growth and colony formation of macrophages. The inhibition of macrophage growth is not due to cell death. In the presence of inhibitors, the growth of colony-forming macrophages is suppressed, and small clusters are formed as a result of limited proliferation. The more mature mono-nuclear phagocytes (blood monocytes and peritoneal exudate macrophages) are more sensitive to the overall inhibitory effect of the peritoneal inhibitors than the less mature bone marrow mononuclear phagocytes. Furthermore, using dialysis and Amicon ultrafiltration, at least two inhibitors with differential inhibitory effects can be demonstrated. The colony formation of bone marrow mononuclear phagocytes is suppressed mainly by a protease-resistant, small molecular weight (<1,000) dialyzable inhibitor. In contrast, peritoneal exudate macrophages are sensitive to both the small molecular weight inhibitor and a protease-sensitive, large molecular weight (>12,000), nondialyzable inhibitor. The data suggest a possible existence of a dual inhibitor control on the proliferation of mononuclear phagocytes in vivo. In addition, the in vitro cultured peritoneal exudate cells are capable of producing inhibitors that mimic the activity of the in vivo inhibitors. This investigation was supported by Grants CA 09 11(SY) and AI15563(CCS) from the National Institutes of Health, Bethesda, MD     

Acquired cellular resistance following transfer of lymphocytes from mice infected repeatedly with Staphylococcus aureus

Cell-mediated immunity following multiple staphylococcal infections of mice was found to differ from other established experimental models of infection with facultative intracellular microorganisms in that acquired cellular resistance was of extremely short duration. This is perhaps a reflection of the fact that Staphylococcus aureus does not multiply or survive within mononuclear phagocytes and are eliminated from the tissues within a few days. Thus, a sustained antigenic stimulus required for maintenance of cellular immunity does not occur. Spleen cells from immunized mice transferred simultaneously with staphylococcal antigen conferred resistance against Listeria monocytogenes on unimmunized syngeneic mice. Treatment of immune splenic lymphocytes with antilymphocyte serum and complement markedly inhibited or abolished capacity of the lymphocytes to transfer resistance to Listeria. These results support and extend our previous data which suggest that mice infected repeatedly with staphylococci are able to suppress the growth of L. monocytogenes via cellular rather than humoral mechanisms.     

In situ effector pathways of allograft destruction. 3. Plasminogen activator activity in rat renal allografts

The question of which cell components in a rejecting rat renal allograft secrete plasminogen activator (PA) has been analyzed. Although normal renal parenchymal cells also secreted PA, most of the PA in a renal allograft (and to a lesser extent also in an autograft) was produced by the inflammatory leukocytes. Fractionation at 1 g demonstrated that the inflammatory cell population responsible for the PA production in the allograft sedimented together with the large mononuclear phagocytes (macrophages). Fractions purified for small blast cells and large lymphocytes did not contain any PA activity but they were able to induce resting peritoneal macrophages to produce PA when cocultured in vitro. The results demonstrate that the allograft-infiltrating mononuclear phagocytes are "activated" in the sense that they secrete PA and that the activation of mononuclear phagocytes at the site of inflammation may be partially regulated by the inflammatory lymphoid cells.     

Activity and Properties of Macrophage Migration Inhibitory Factor produced by Mixed Lymphocyte Cultures

THE macrophage migration test is an in vitro demonstration of delayed hypersensitivity. Supernatant fluids of sensitive lymphocytes cultured for 24 h in the presence of specific antigen contain migration inhibitory factor (MIF) that arrests the migration of macrophages of unsensitized animals in vitro¹,². In vivo, it induces delayed skin reactions³. The use of the macrophage migration test, based on differences of transplantation antigens in donor and recipient, to show histocompatibility has been suggested⁴. The test was also recommended as an indicator of immunological reactivity after organ transplantation, to demonstrate impending rejection⁵. It can demonstrate homograft sensitivity, for migration of peritoneal exudate cells (containing lymphocytes and macrophages) of CBA mice previously sensitized by grafts from A/Jax donors was inhibited when they were mixed with peritoneal exudate cells of the donor strain. However, histocompatibility was not demonstrated, for mixtures of peritoneal exudate cells of ungrafted CBA mice and A/Jax mice migrated regularly during the 24 h test⁶.     

Human mononuclear phagocyte-associated antigens: I. Identification and characterization

Rabbit antisera were produced against a lymphokine-activated human macrophage cell line, U937 (αU937), and human peritoneal macrophages (αPEMØ). After absorption with AB erythrocytes, pooled platelets, and B-lymphoblastoid cell lines, both antisera reacted by microcytotoxicity, indirect immunofluorescence (IF), and radioimmunoassay (RIA) with adherence-purified human peripheral blood monocytes, splenic and peritoneal macrophages, and leukemic myelomonoblasts. A panel of normal human T lymphocytes, B lymphocytes, and erythroid-myeloid or lymphoblastoid cell lines failed to react with both αU937 and αPEMØ. Although both heteroantisera reacted against polymorphonuclear leukocytes (PMNs), after absorption with PMNs specific reactivity against mononuclear phagocytes remained. Absorption of αU937 and αPEMØ with myelomonoblastic leukemia cells (AMML) removed IF and RIA activity against both PMNs and monocytes but not against splenic and peritoneal macrophages. In contrast, absorptions of both heteroantisera preparations with splenic macrophages abolished their IF and RIA reactivity not only to splenic and peritoneal macrophages but also to peripheral blood monocytes and leukemic myelomonoblasts. These results are consistent with (1) both antisera defining specific monocyte/macrophage-associated antigens(s) which are distinct from MHC-coded HLA-A,B,C, and DR antigens, and (2) expression of common monocyte/macrophage-associated antigen(s) and uniquely associated antigen(s) selectively expressed on tissue macrophages. These reagents will be useful in delineating human monocyte/macrophage differentiation as well as the immunological functions of mononuclear phagocytes.     

Plasminogen activator-specific inhibitors in mouse macrophages: in vivo and in vitro modulation of their synthesis and secretion

Mouse resident peritoneal macrophages synthesize two plasminogen activator-specific inhibitors (PAI) that are functionally and antigenically related, but differ in their apparent Mr and oligosaccharide content. Most of the Mr 40,000 inhibitor can be recovered from the cell lysate, whereas the Mr 55,000 glycosylated PAI is preferentially secreted. The murine macrophage PAI are functionally similar and immunologically related to PAI synthesized and secreted by human monocytes-macrophages, and to a PAI from human placenta (PAI-2). PAI production by murine mononuclear phagocytes can be modulated both in vivo and in vitro. Bone marrow-derived macrophages do not produce detectable PAI, whereas inflammatory macrophages obtained from thioglycollate-induced peritoneal exudates produce only low levels of PAI. In cultures of resident peritoneal macrophages, phorbol myristate acetate and cholera toxin increase the synthesis of the Mr 55,000 secreted PAI, whereas dexamethasone decreases the synthesis of both PAI; the production of PAI is also enhanced in the presence of macrophage colony-stimulating factor (CSF-1). The overall proteolytic activity of mononuclear phagocytes thus depends in part on the controlled synthesis and secretion of PAI. The balance between the production of plasminogen activators and of their inhibitors could be critical in determining the level of plasminogen-dependent extracellular proteolysis associated with different phases of the inflammatory response.