Compartmentalized expression of RANTES in a murine model of endotoxemia

Systemic exposure to LPS initiates a complex sequence of events culminating in organ-specific leukocyte recruitment and end organ injury. We hypothesized that RANTES, a C-C chemokine with potent M phi (mononuclear phagocyte) chemotactic activity, is expressed in vivo in response to endotoxemia, and that this protein may play an important role in the recruitment of M phi to the lung. CD-1 mice were challenged with LPS (200 micrograms), resulting in a maximal fourfold increase in polymorphonuclear leukocyte (neutrophils) at 6 h post LPS, and a 2.4-fold increase in numbers of M phi within lung minces at 24 h. A time-dependent increase in RANTES mRNA was detected in lung after LPS treatment, whereas minimal quantities of RANTES mRNA were detected in blood buffy coats and liver. Furthermore, treatment with LPS resulted in time-dependent increase in RANTES protein within lung homogenates, with immunolocalization to alveolar epithelial cells. The pretreatment of mice with goat anti-RANTES Ab significantly inhibited the influx of lung M phi, but not polymorphonuclear leukocyte and lymphocytes, at 24 h post-LPS challenge. Lastly, the pretreatment of animals with soluble TNF receptor: Ig construct 2 h before LPS resulted in a 60% reduction in steady state levels of RANTES mRNA within lung homogenates at 4 h post-LPS. Our observations suggest that RANTES represents an important mediator of lung M phi recruitment in the setting of endotoxemia, and that the expression of RANTES in vivo is dependent upon the endogenous production of TNF.

Compartmentalized expression of RANTES in a murine model of endotoxemia

Systemic exposure to LPS initiates a complex sequence of events culminating in organ-specific leukocyte recruitment and end organ injury. We hypothesized that RANTES, a C-C chemokine with potent M phi (mononuclear phagocyte) chemotactic activity, is expressed in vivo in response to endotoxemia, and that this protein may play an important role in the recruitment of M phi to the lung. CD-1 mice were challenged with LPS (200 micrograms), resulting in a maximal fourfold increase in polymorphonuclear leukocyte (neutrophils) at 6 h post LPS, and a 2.4-fold increase in numbers of M phi within lung minces at 24 h. A time-dependent increase in RANTES mRNA was detected in lung after LPS treatment, whereas minimal quantities of RANTES mRNA were detected in blood buffy coats and liver. Furthermore, treatment with LPS resulted in time-dependent increase in RANTES protein within lung homogenates, with immunolocalization to alveolar epithelial cells. The pretreatment of mice with goat anti-RANTES Ab significantly inhibited the influx of lung M phi, but not polymorphonuclear leukocyte and lymphocytes, at 24 h post-LPS challenge. Lastly, the pretreatment of animals with soluble TNF receptor: Ig construct 2 h before LPS resulted in a 60% reduction in steady state levels of RANTES mRNA within lung homogenates at 4 h post-LPS. Our observations suggest that RANTES represents an important mediator of lung M phi recruitment in the setting of endotoxemia, and that the expression of RANTES in vivo is dependent upon the endogenous production of TNF.

Regulation of the immunostimulatory activity of rat pulmonary interstitial dendritic cells by cell-cell interactions and cytokines

Pulmonary dendritic cells (DC) are potent antigen-presenting cells that are thought to play a critical role in the initiation of immune responses within the lung. Because the lung is both a site of entry into the body for microbial pathogens and the organ of gas exchange, pulmonary immune responses must be meticulously regulated to achieve a balance between host defense and respiration. The initial interaction of DC with T cells in the lung is an excellent point at which to control local immune responses. Studies of the regulation of DC accessory cell function have been greatly hampered by difficulties in obtaining pure populations of pulmonary DC that have not been subjected to prolonged incubations during which the DC may undergo functional alteration. We now describe a method for isolating pulmonary DC from the rat that yields 1 x 10(5) cells/rat with > 90% purity. These cells are potent accessory cells, inducing T cell proliferation in a mixed leukocyte reaction (MLR) at a stimulator-to-responder ratio of 1:1,000. This method, which involves flow cytometric separation of nonphagocytic cells that stain brightly for class II MHC (OX6) from a population of low-density pulmonary interstitial cells, avoids extended incubations at 37 degrees C and thus allows study of a relatively pure population of cells that have functional capacities resembling those of naive cells from the normal lung. With these cells, we demonstrate that the functional capacity of pulmonary DC as stimulator cells in an MLR is significantly increased by exposure to the cytokines interleukin-1 or granulocyte/macrophage colony-stimulating factor (GM-CSF) and by culture with interstitial, but not alveolar, macrophages. Furthermore, DC are heterogeneous with respect to the cell surface expression of receptor for GM-CSF, and this expression is subject to modulation in cell culture. From these studies, we conclude that the immunostimulatory capacity of pulmonary DC is a function of local interactions with cytokines and other parenchymal cells. This suggests that DC function may be an important regulatory point for the local control of pulmonary immune responses.

Localization of 5-lipoxygenase to the nucleus of unstimulated rat basophilic leukemia cells

Arachidonate metabolism by 5-lipoxygenase (5-LO) coincides with the translocation of the enzyme from a soluble to a pelletable fraction in thoroughly disrupted granulocytic cells. While immunoelectron microscopy has identified the nuclear membrane as the site at which 5-LO, as well as 5-LO activating protein (FLAP), are localized in activated cells, the locale of soluble 5-LO in unstimulated cells could not be established by this technique. We asked whether the nucleus might also be the site for soluble 5-LO in unstimulated cells, and utilized rat basophilic leukemia (RBL) cells as model granulocytic cells to address this question. Using three different techniques to disrupt cells while leaving nuclei intact (mild nitrogen cavitation, Dounce homogenization, and detergent lysis), immunoblot analysis indicated abundant 5-LO in isolated nuclei. Within purified nuclei, 5-LO existed in two pools: a soluble pool that was readily released upon nuclear disruption and a bound pool that was not removed by 300 mM NaCl treatment. In all cases, 5-LO was also found in cytosolic and non-nuclear membrane fractions. Indirect immunofluorescent microscopy confirmed the presence of abundant 5-LO within the nucleus with minimal extranuclear signal in most cells. However, a minority of cells, characterized by condensed chromatin, showed no nuclear-associated staining with increased cytoplasmic staining for 5-LO. This suggested that some of the cytosolic 5-LO found by cell fractionation resulted from these dividing cells. When the contribution from dividing cells was minimized, either by overnight serum deprivation or by isolating cytoplasts of nucleus-containing cells, 5-LO was prominent in the nuclear fraction but negligible in the cytosolic fraction. In contrast to this distribution in RBL cells, 5-LO in unstimulated human neutrophils was predominantly cytosolic, by both immunoblot and immunofluorescence analyses. In both RBL cells and human neutrophils, FLAP was localized at the nuclear membrane and the endoplasmic reticulum. These data provide the first evidence for the localization of 5-LO in unstimulated granulocytic cells. The finding that a substantial proportion of enzyme is localized within the nucleus of unstimulated RBL cells suggests potentially novel roles for 5-LO or its products within the nucleus.

CD8 cells play a critical role in delayed type hypersensitivity to intact Cryptococcus neoformans

Although cell-mediated immunity is critical for optimal host defense to C. neoformans, the role of T lymphocyte subsets is complex and poorly understood. CD8 cells are important both for optimal host defense against C. neoformans, and for expression of delayed type hypersensitivity (DTH). Because host defense correlates with the ability to mount a DTH response to C. neoformans, the current studies were performed to determine the mechanism by which CD8 cells participate in DTH. Mice were immunized by the intratracheal route with live C. neoformans, or by the subcutaneous route with heat-killed C. neoformans. Mice were depleted of CD8 cells in vivo by administration of mAb. After challenge with soluble cryptococcal Ag, the DTH response was quantified as footpad swelling. We found that mice depleted of CD8 cells before immunization were unable to express DTH. Mice depleted of CD8 cells after immunization but before challenge also were unable to express DTH. Splenocytes of mice depleted of CD8 cells in vivo, before immunization, failed to transfer DTH to naive, undepleted mice. Immune splenocytes depleted of CD8 cells in vitro also failed to transfer DTH to naive, undepleted mice. These data indicate that CD8 cells were necessary during the challenge and immunizing phases of DTH, and were necessary for expression of DTH. However, CD8 cell depletion did not abrogate DTH in mice immunized with either soluble cryptococcal Ag in complete Freund's adjuvant, or sheep red blood cells, which are mediated by CD4 cells. These data suggest that CD8 cells play a critical role in the cell-mediated immune response to C. neoformans. Based on this information, it may be possible to protect hosts with deficiencies of CD4 cells, such as in AIDS, by designing immunizing strategies for stimulating CD8 cells.

CD8 cells play a critical role in delayed type hypersensitivity to intact Cryptococcus neoformans

Although cell-mediated immunity is critical for optimal host defense to C. neoformans, the role of T lymphocyte subsets is complex and poorly understood. CD8 cells are important both for optimal host defense against C. neoformans, and for expression of delayed type hypersensitivity (DTH). Because host defense correlates with the ability to mount a DTH response to C. neoformans, the current studies were performed to determine the mechanism by which CD8 cells participate in DTH. Mice were immunized by the intratracheal route with live C. neoformans, or by the subcutaneous route with heat-killed C. neoformans. Mice were depleted of CD8 cells in vivo by administration of mAb. After challenge with soluble cryptococcal Ag, the DTH response was quantified as footpad swelling. We found that mice depleted of CD8 cells before immunization were unable to express DTH. Mice depleted of CD8 cells after immunization but before challenge also were unable to express DTH. Splenocytes of mice depleted of CD8 cells in vivo, before immunization, failed to transfer DTH to naive, undepleted mice. Immune splenocytes depleted of CD8 cells in vitro also failed to transfer DTH to naive, undepleted mice. These data indicate that CD8 cells were necessary during the challenge and immunizing phases of DTH, and were necessary for expression of DTH. However, CD8 cell depletion did not abrogate DTH in mice immunized with either soluble cryptococcal Ag in complete Freund's adjuvant, or sheep red blood cells, which are mediated by CD4 cells. These data suggest that CD8 cells play a critical role in the cell-mediated immune response to C. neoformans. Based on this information, it may be possible to protect hosts with deficiencies of CD4 cells, such as in AIDS, by designing immunizing strategies for stimulating CD8 cells.

Regulation of alveolar epithelial cell ICAM-1 expression by cell shape and cell-cell interactions

In normal lung, intercellular adhesion molecule 1 (ICAM-1) is expressed at high levels on thin type I alveolar epithelial cells, but is minimally expressed on cuboidal type II cells. ICAM-1 is induced in primary culture on tissue culture-treated plastic as type II cells undergo transition toward a type I cell-like phenotype. We hypothesized that alveolar epithelial cell expression of ICAM-1 might be regulated in part by signals that influence the state of differentiation of these cells. We found that rat type II cells that were cultured as aggregates of cuboidal cells on a hydrated basement membrane gel (Matrigel) or on floating type I collagen gels, expressed markedly less ICAM-1 protein and mRNA compared with cells that had spread on plastic. In contrast, type II cells that had spread as monolayers on dishes coated with basement membrane proteins in planar configuration demonstrated ICAM-1 expression comparable to that of cells on plastic alone. Thus regulation of alveolar epithelial cell expression of this immunologically important adhesion molecule involves complex spatial interactions of the cells with the basement membrane and other epithelial cells.

MCP-1 expression by rat type II alveolar epithelial cells in primary culture

Recruitment and activation of mononuclear phagocytes are potentially critical regulatory events for control of pulmonary inflammation. Located at the boundary between the alveolar airspace and the interstitium, alveolar epithelial cells are ideally situated to regulate the recruitment and activation of mononuclear phagocytes through the production of cytokines in response to inflammatory stimulation from the alveolar space. To test this hypothesis, we investigated the production of monocyte chemotactic polypeptide-1 (MCP-1), a protein that is chemotactic for and that activates monocytes, by rat type II alveolar epithelial cells in primary culture. Immunocytochemical staining using anti-murine JE, an antibody recognizing rat MCP-1, demonstrated cell-associated MCP-1 Ag throughout the monolayer. The intensity of staining was increased in response to IL-1 beta. When type II epithelial cells formed a tight monolayer on a filter support, there was polar secretion of MCP-1 Ag into the apical compartment by both control and IL-1-stimulated cells as measured by specific MCP-1 ELISA. Northern blot analysis revealed that IL-1 and TNF-alpha stimulated MCP-1 mRNA expression in a dose-dependent manner, whereas dexamethasone blocked MCP-1 expression by cells stimulated with IL-1. In contrast to previous results using transformed epithelial cell lines, MCP-1 mRNA was induced in these primary cultures directly by stimulation with LPS. These data suggest that alveolar epithelial cells may have an important and previously unrecognized role in the initiation and maintenance of inflammatory processes in the lung by recruiting and activating circulating monocytes through the production of MCP-1.

MCP-1 expression by rat type II alveolar epithelial cells in primary culture

Recruitment and activation of mononuclear phagocytes are potentially critical regulatory events for control of pulmonary inflammation. Located at the boundary between the alveolar airspace and the interstitium, alveolar epithelial cells are ideally situated to regulate the recruitment and activation of mononuclear phagocytes through the production of cytokines in response to inflammatory stimulation from the alveolar space. To test this hypothesis, we investigated the production of monocyte chemotactic polypeptide-1 (MCP-1), a protein that is chemotactic for and that activates monocytes, by rat type II alveolar epithelial cells in primary culture. Immunocytochemical staining using anti-murine JE, an antibody recognizing rat MCP-1, demonstrated cell-associated MCP-1 Ag throughout the monolayer. The intensity of staining was increased in response to IL-1 beta. When type II epithelial cells formed a tight monolayer on a filter support, there was polar secretion of MCP-1 Ag into the apical compartment by both control and IL-1-stimulated cells as measured by specific MCP-1 ELISA. Northern blot analysis revealed that IL-1 and TNF-alpha stimulated MCP-1 mRNA expression in a dose-dependent manner, whereas dexamethasone blocked MCP-1 expression by cells stimulated with IL-1. In contrast to previous results using transformed epithelial cell lines, MCP-1 mRNA was induced in these primary cultures directly by stimulation with LPS. These data suggest that alveolar epithelial cells may have an important and previously unrecognized role in the initiation and maintenance of inflammatory processes in the lung by recruiting and activating circulating monocytes through the production of MCP-1.

Legionella pneumophila replicates within rat alveolar epithelial cells

Legionella pneumophila replicates in the distal pulmonary airspace, causing legionnaires' pneumonia. Legionella organisms replicate within alveolar macrophages and recruited blood monocytes; however, when these cells are activated, they become potent inhibitors of L. pneumophila proliferation. L. pneumophila may replicate in other cells and thereby avoid the host defenses of macrophages. Experiments demonstrated that L. pneumophila replicate within primary cultures of rat pulmonary alveolar epithelial cells. Double-label immunofluorescent and electron microscopy demonstrated L. pneumophila within epithelial cells. Replication of L. pneumophila required similar numbers of alveolar epithelial cells or alveolar macrophages, required viable epithelial cells, and took place intracellularly. While replication of L. pneumophila occurred in both serum-free and serum-containing media, it was enhanced in the presence of serum. Pulmonary alveolar epithelial cells may represent an alternative site for replication of Legionella species in the terminal airspace and thus clarify some previously unexplained aspects of the pathogenesis of legionnaires' disease.

Differentiation-related expression of ICAM-1 by rat alveolar epithelial cells

Local regulation of immune and inflammatory responses within the alveolar space is a critical aspect of normal pulmonary host defense. The type I and type II epithelial cells that line the alveolar space are in intimate contact with lymphocytes and macrophages within the alveolar space and are ideally situated to provide regulatory signals to these effector cells. The present studies were undertaken to investigate the expression by rat alveolar epithelial cells in vitro and in vivo of intercellular adhesion molecule-1 (ICAM-1), an adhesion molecule that is involved in migration and activation of T cells and macrophages. An antibody specifically blocking rat ICAM-1 (mAb 1A29) inhibited the adherence of activated T lymphoblasts to monolayers of type II alveolar epithelial cells. The expression of ICAM-1 protein by alveolar epithelial cells in vitro was confirmed both by immunofluorescence microscopy and by Western blot analysis. However, in each instance, ICAM-1 was not detected in type II cells the day of isolation, but appeared at low levels after 1 day and in abundance throughout the monolayer after 2 days, with sustained expression thereafter. This suggested that ICAM-1 expression might be a type I cell feature, which was induced as isolated type II cells underwent transformation towards the type I cell-like phenotype in vitro. Using immunofluorescence microscopy on frozen sections of normal lung, ICAM-1 was found in a linear distribution along the alveolar space, consistent with expression on type I cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Hard metal pneumoconiosis and the association of tumor necrosis factor-alpha

Hard metal pneumoconiosis is a recently recognized occupational lung disease associated with the exposure to cobalt fumes in the workplace. Chronic exposure in susceptible individuals results in interstitial lung disease histopathologically manifested as interstitial fibrosis with an associated mononuclear cell infiltrate and the presence of "cannibalistic" multinucleated giant cells in the alveolar airspaces. The majority of patients present with symptoms of chronic cough and dyspnea. Interestingly, in addition, patients uniformly report significant weight loss out of proportion to their degree of respiratory impairment. In this case report we demonstrate the association of tumor necrosis factor-alpha (TNF) and hard metal (cobalt) pneumoconiosis and suggest that TNF may have a potential role in the etiology of the constitutional symptoms and the pathogenesis of interstitial lung disease.

A factor secreted by a human pulmonary alveolar epithelial-like cell line blocks T-cell proliferation between G1 and S phase

Because the pulmonary alveolar space is both the site of gas exchange for respiration and a portal of entry for foreign antigen, immunologic interactions within that space must be meticulously controlled. Alveolar epithelial cells are ideally situated to play a role in immune regulation within the alveolar space. We have used A549 cells, a cell line that is derived from a human alveolar cell carcinoma and that has been used as a model for alveolar type II epithelial cells, to examine the potential role of alveolar epithelial cells in local pulmonary immune regulation. Medium conditioned by confluent monolayers of A549 cells suppressed proliferation by human peripheral blood mononuclear cells (PBMC) stimulated with lectin, anti-CD3 antibodies, calcium ionophore and phorbol ester, or in a mixed leukocyte reaction. PBMC that had been incubated in and then removed from A549-conditioned medium went on to proliferate normally. Because the suppressive effect was abrogated by heating or acidification and was not blocked by neutralizing antibody to transforming growth factor-beta 1, this effect could not be attributed to transforming growth factor-beta. The factor mediating this effect has an approximate molecular weight of 70,000 D by gel filtration chromatography. Nonalveolar, pulmonary carcinoma cell lines did not exert this immunosuppressive influence nor did the alveolar epithelial cells inhibit proliferation by the transformed, Jurkat, T-cell line. Cell cycle analysis demonstrated that PBMC exposed to A549 cell-conditioned medium failed to enter S phase after mitogen stimulation.(ABSTRACT TRUNCATED AT 250 WORDS)

Alveolar epithelial cells block lymphocyte proliferation in vitro without inhibiting activation

In the face of constant exposure to inhaled antigens, precise local regulation of immune responses in the pulmonary alveolar space is essential to achieve a delicate balance between host defense and excessive immune responses that are incompatible with the primary physiologic function of the lung. We postulated that the cells of the alveolar epithelium may have an immunoregulatory role in the lung. Therefore, we have examined the effects of primary cultures of rat type II alveolar epithelial cells on lymphocyte proliferation and on the expression of a number of markers of T-cell activation. Monolayers of alveolar epithelial cells suppressed proliferation and DNA synthesis by concanavalin A-stimulated rat splenocytes. Suppression of [3H]thymidine incorporation was independent of the dose of mitogen and was also apparent when lymphocytes were stimulated with phorbol esters and calcium ionophore, suggesting that the effect was independent of cell surface binding of the lectin. Suppression was reversed 48 h after lectin-stimulated splenocytes were removed from co-culture with alveolar epithelial cells. Despite inhibition of lymphocyte proliferation, other markers of T-cell activation were induced normally in lymphocytes cultured with alveolar epithelial cells. Culture with alveolar epithelial cells did not inhibit the the production of interleukin-2 by stimulated lymphocytes. Furthermore, by fluorescence-activated cell sorter analysis, equal proportions of stimulated lymphocytes in culture alone or with alveolar epithelial cell monolayers were induced to express receptors for interleukin-2 and for transferrin.(ABSTRACT TRUNCATED AT 250 WORDS)

Signal transduction via CD4, CD8, and CD28 in mature and immature thymocytes. Implications for thymic selection

The positive and negative selection of immature thymocytes that shapes the mature T cell repertoire appears to occur at an intermediate stage of development when the cells express low levels of TCR/CD3. These cells are also CD4+CD8+ and CD28+ (dull), and signals delivered by these three accessory molecules have been implicated in the selection process. We have examined the regulatory function of these accessory molecules on responses of immature thymocytes stimulated through the TCR/CD3 complex. Cross-linking CD4 or CD8 with CD3 strongly enhanced signal transduction via CD3 as assessed by protein tyrosine phosphorylation and calcium mobilization. Subsequent cell proliferation could be induced by soluble anti-CD28 mAb, which was comitogenic for cells stimulated with CD3 x CD4 or CD3 x CD8 cross-linking, but was without effect on cells stimulated with CD3 x CD3 cross-linking. A potential role for CD28 signal transduction in thymic maturation is suggested by the demonstration that the BB-1 molecule, a natural ligand for CD28, is expressed on thymic stromal cells. Taken together, our data suggest a model of thymic development in which CD4 or CD8 may enhance TCR/CD3 signaling upon coligation by an MHC molecule. If the CD28 surface receptor is simultaneously stimulated by a BB-1 expressing stromal cell, this set of interactions could lead to proliferation and positive selection. In the absence of CD28 stimulation the enhanced TCR/CD3 signals might lead to apoptosis and negative selection.

Signal transduction via CD4, CD8, and CD28 in mature and immature thymocytes. Implications for thymic selection

The positive and negative selection of immature thymocytes that shapes the mature T cell repertoire appears to occur at an intermediate stage of development when the cells express low levels of TCR/CD3. These cells are also CD4+CD8+ and CD28+ (dull), and signals delivered by these three accessory molecules have been implicated in the selection process. We have examined the regulatory function of these accessory molecules on responses of immature thymocytes stimulated through the TCR/CD3 complex. Cross-linking CD4 or CD8 with CD3 strongly enhanced signal transduction via CD3 as assessed by protein tyrosine phosphorylation and calcium mobilization. Subsequent cell proliferation could be induced by soluble anti-CD28 mAb, which was comitogenic for cells stimulated with CD3 x CD4 or CD3 x CD8 cross-linking, but was without effect on cells stimulated with CD3 x CD3 cross-linking. A potential role for CD28 signal transduction in thymic maturation is suggested by the demonstration that the BB-1 molecule, a natural ligand for CD28, is expressed on thymic stromal cells. Taken together, our data suggest a model of thymic development in which CD4 or CD8 may enhance TCR/CD3 signaling upon coligation by an MHC molecule. If the CD28 surface receptor is simultaneously stimulated by a BB-1 expressing stromal cell, this set of interactions could lead to proliferation and positive selection. In the absence of CD28 stimulation the enhanced TCR/CD3 signals might lead to apoptosis and negative selection.