Intravascular granuloma induced by intravenous inoculation ofCryptococcus neoformans

In rodents an intravenous administration of viableCryptococcus (C.) neoformans cells frequently resulted in attachment of intravascular cryptococcal granulomas to inner walls of the large to medium-sized veins of various organs, including the lungs, liver and spleen. In order to elucidate the pathogenesis of granulomatous changes, the cells composing the intravascular granulomas were observed by electron microscopic peroxidase (PO) cytochemistry. The granuloma composing cells could be divided into the following four types according to the pattern of endogenous peroxidase activity: exudate macrophage (Mφ, type I), PO-negative Mφ (type II), resident Mφ (type III) and other inflammatory cells (type IV). In the intravenous granulomas of the lung, the percentages of composed cells were 39.0% for type I, 57.9% for type II, 0% for type III and 3.1% for type IV. By contrast, in the interstitial granulomas in the lung, type III Mφs, possibly derived from alveolar Mφs, played a significant role in granuloma formation. This may indicate that the intravascular granuloma is almost composed of macrophages derived from monocytes rather than alveolar macrophages. The expression of ICAM-1 on endothelia of the pulmonary veins was examined by immunoelectron microscopy. An immunogold labeling index was significantly augmented on the surface of endothelia in response to intravenous challenge ofC. neoformans. The intravascular granuloma demonstrates that the monocytes develop into the granuloma-composing macrophages and suppress the cryptococcal activities even hi the peripheral blood resulting in an assistance of endothelial functions.     

Lung macrophages serve as obligatory intermediate between blood monocytes and alveolar macrophages

Alveolar macrophages are a unique type of mononuclear phagocytes that populate the external surface of the lung cavity. Early studies have suggested that alveolar macrophages originate from tissue-resident, local precursors, whereas others reported their derivation from blood-borne cells. However, the role of circulating monocytes as precursors of alveolar macrophages was never directly tested. In this study, we show through the combined use of conditional cell ablation and adoptive cell transfer that alveolar macrophages originate in vivo from blood monocytes. Interestingly, this process requires an obligate intermediate stage, the differentiation of blood monocytes into parenchymal lung macrophages, which subsequently migrate into the alveolar space. We also provide direct evidence for the ability of both lung and alveolar macrophages to proliferate.     

Characterization of mononuclear phagocyte subpopulations in the human lung by using monoclonal antibodies: changes in alveolar macrophage phenotype associated with pulmonary sarcoidosis

Current concepts of pulmonary sarcoidosis suggest that the alveolar macrophage plays a central role in the pathogenesis of the disease. To help define the population of alveolar macrophages in sarcoidosis, we compared the surface phenotype of alveolar macrophages from patients with sarcoidosis and from normal individuals by using monoclonal antibodies (63D3, OKM1, M phi P-9, M phi S-1, 61D3, and M phi S-39) that detect surface antigens on cells of monocyte/macrophage lineage. Although almost all blood monocytes expressed surface antigens detected by each of these antibodies, only a minority of normal alveolar macrophages expressed the same surface antigens (p less than 0.05, each comparison). However, in sarcoidosis, the percentage of alveolar macrophages expressing these surface antigens was increased (p less than 0.05, each comparison with normal alveolar macrophages). Several findings supported the conclusion that the increased expression of these monocyte-lineage surface antigens on sarcoid alveolar macrophages resulted from increased recruitment of monocytes to the lung in sarcoidosis and not from abnormal "activation" of alveolar macrophages. First, alveolar macrophages expressing these antigens had an immature morphology. Second, in vitro cultivation of blood monocytes and alveolar macrophages in the presence of immune and inflammatory mediators, including mediators known to be present in the lung in sarcoidosis, did not prevent the loss of expression of monocyte-lineage surface antigens from monocytes or induce reexpression of monocyte-lineage surface antigens on alveolar macrophages. Third, the expression of monocyte-lineage surface antigens was only increased on sarcoid macrophages from patients whose lower respiratory tract contained an increased number of T lymphocytes, cells known to release monocyte chemotactic factor in sarcoidosis. Consistent with the knowledge that corticosteroids usually suppress the alveolitis of active sarcoidosis, when the expression of alveolar macrophage surface antigens was evaluated before and during therapy, the percentage of alveolar macrophages expressing monocyte-lineage surface antigens returned to normal after 1 to 3 mo of therapy.(ABSTRACT TRUNCATED AT 400 WORDS)     

Induction of HO-1 in tissue macrophages and monocytes in fatal falciparum malaria and sepsis

BACKGROUND: As well as being inducible by haem, haemoxygenase -1 (HO-1) is also induced by interleukin-10 and an anti-inflammatory prostaglandin, 15d PGJ2, the carbon monoxide thus produced mediating the anti-inflammatory effects of these molecules. The cellular distribution of HO-1, by immunohistochemistry, in brain, lung and liver in fatal falciparum malaria, and in sepsis, is reported. METHODS: Wax sections were stained, at a 1:1000 dilution of primary antibody, for HO-1 in tissues collected during paediatric autopsies in Blantyre, Malawi. These comprised 37 acutely ill comatose patients, 32 of whom were diagnosed clinically as cerebral malaria and the other 5 as bacterial diseases with coma. Another 3 died unexpectedly from an alert state. Other control tissues were from Australian adults. RESULTS: Apart from its presence in splenic red pulp macrophages and microhaemorrhages, staining for HO-1 was confined to intravascular monocytes and certain tissue macrophages. Of the 32 clinically diagnosed cerebral malaria cases, 11 (category A) cases had negligible histological change in the brain and absence of or scanty intravascular sequestration of parasitized erythrocytes. Of these 11 cases, eight proved at autopsy to have other pathological changes as well, and none of these eight showed HO-1 staining within the brain apart from isolated moderate staining in one case. Two of the three without another pathological diagnosis showed moderate staining of scattered monocytes in brain vessels. Six of these 11 (category A) cases exhibited strong lung staining, and the Kupffer cells of nine of them were intensely stained. Of the seven (category B) cases with no histological changes in the brain, but appreciable sequestered parasitised erythrocytes present, one was without staining, and the other six showed strongly staining, rare or scattered monocytes in cerebral vessels. All six lung sections not obscured by neutrophils showed strong staining of monocytes and alveolar macrophages, and all six available liver sections showed moderate or strong staining of Kupffer cells. Of the 14 (category C) cases, in which brains showed micro-haemorrhages and intravascular mononuclear cell accumulations, plus sequestered parasitised erythrocytes, all exhibited strong monocyte HO-1 staining in cells forming accumulations and scattered singly within cerebral blood vessels. Eleven of the available and readable 13 lung sections showed strongly staining monocytes and alveolar macrophages, and one stained moderately. All of the 14 livers had strongly stained Kupffer cells. Of five cases of comatose culture-defined bacterial infection, three showed a scattering of stained monocytes in vessels within the brain parenchyma, three had stained cells in lung sections, and all five demonstrated moderately or strongly staining Kupffer cells. Brain sections from all three African controls, lung sections from two of them, and liver from one, showed no staining for HO-1, and other control lung and liver sections showed few, palely stained cells only. Australian-origin adult brains exhibited no staining, whether the patients had died from coronary artery disease or from non-infectious, non-cerebral conditions CONCLUSIONS: Clinically diagnosed 'cerebral malaria' in children includes some cases in whom malaria is not the only diagnosis with the hindsight afforded by autopsy. In these patients there is widespread systemic inflammation, judged by HO-1 induction, at the time of death, but minimal intracerebral inflammation. In other cases with no pathological diagnosis except malaria, there is evidence of widespread inflammatory responses both in the brain and in other major organs. The relative contributions of intracerebral and systemic host inflammatory responses in the pathogenesis of coma and death in malaria deserve further investigation.     

Role of alveolar macrophages in endotoxin-induced neutrophilic alveolitis in rats

Although bacterial endotoxins have potent effects on blood monocytes and tissue macrophages, the role of alveolar macrophages in regulating intrapulmonary neutrophil traffic following endotoxemia has not been studied previously. We have previously reported that a single intraperitoneal injection of endotoxin from Escherichia coli serotype 055B5 causes acute lung inflammation by neutrophils (PMN) in rats. The factors which influence the migration of PMN in the lung in this model are unknown. To determine whether macrophage-derived products could play a role in directing migration, we enumerated neutrophils in histologic sections and employed electron microscopy to document the location of neutrophils in the lung in vivo following endotoxin. We also cultured the alveolar macrophages recovered by lung lavage to measure the effect of their culture supernatants on neutrophil migration in vitro. In the first 6 hr following endotoxin, and also 24 hr later, there was an increase in the number of PMN enumerated in the lung parenchyma by light microscopy. Electron microscopy showed the location of the neutrophils to be exclusively intravascular at 6 hr. By contrast, neutrophils were observed in both interstitial and bronchoalveolar spaces at 24 hr, confirming that transvascular migration was active at that time. The pulmonary macrophages which were recovered by lung lavage from groups of rats sacrificed at 4 and at 15 hr following the administration of endotoxin were assayed for the release into culture media of migration-stimulatory activity for neutrophils. Macrophages from animals sacrificed 4 hr following endotoxin released less migration-stimulating activity into media than macrophages from controls. These macrophages could be stimulated to release migration-stimulating activity into culture media at levels comparable to macrophages from controls by the addition of opsonized Zymosan to the culture media. By contrast, macrophages from animals sacrificed 15 hr after endotoxin spontaneously released more migration-stimulating activity for neutrophils than did macrophages from controls. Thus, in this model, a specific increase in the synthesis or release by alveolar macrophages of factors which stimulate the migration of neutrophils in vitro coincided with a transition from intravascular to extravascular alveolar inflammation by neutrophils in vivo. These observations are consistent with the hypothesis that pulmonary alveolar macrophages may contribute to the regulation of alveolar inflammation following endotoxemia by releasing factors which influence the migration of neutrophils.     

Perfluoro compounds as artificial erythrocytes.

Some liquid perfluoro compounds dissolve relatively large amounts of oxygen and can be used in dispersed form as substitutes for erythrocytes. The commonly used perfluoro compounds contain about the same amount of oxygen as do equal volumes of erythrocytes when equilibrated with 100% oxygen. However, when equilibrated with alveolar air, the perfluoro compounds contain much less oxygen than erythrocytes. The dispersed fluorochemicals are adequate substitutes for perfusion of isolated preparations of mammalian brain, heart kidney, lung and liver. However, when put into the circulation of the intact animal, the dispersed fluorochemicals tends to produce lesions of the lungs, dilation of the right heart, and ultimately fatal hypoxia. It is suggested that the course of events following intravenous injection of dispersed fluorochemical is initiated by an interaction of the perfluoro particles with blood platelets or blood clotting factors. The ensuing intravascular clotting could then cause the changes in the lungs which lead to a marked increase in pulmonary artery pressure and dilation of the right heart. These events would terminate in fatal hypoxia due to pulmonary pathology and heart failure.     

Monoclonal antibody OKM5 inhibits the in vitro binding of Plasmodium falciparum-infected erythrocytes to monocytes, endothelial, and C32 melanoma cells

Plasmodium falciparum-infected erythrocytes bind in vitro to human endothelial cells, monocytes, and a certain melanoma cell line. Evidence suggests that this interaction is mediated by similar mechanisms which lead to the sequestration of parasitized erythrocytes in vivo through their attachment to endothelial cells of small blood vessels. We show here that monoclonal antibody OKM5, previously shown to react with the membranes of endothelial cells, monocytes, and platelets, also reacts with the C32 melanoma cell line which also binds P. falciparum-infected erythrocytes. At relatively low concentrations, OKM5 inhibits and reverses the in vitro adherence of infected erythrocytes to target cells. As with monocytes, OKM5 antibody recognizes an 125I-labeled protein of approximately 88 Kd on the surface of C32 melanoma cells. It seems likely, therefore, that the 88 Kd polypeptide plays a role in cytoadherence, possibly as the receptor or part of a receptor for a ligand on the surface of infected erythrocytes.     

Expression of the transferrin receptor gene during the process of mononuclear phagocyte maturation

The expression of transferrin receptors by blood monocytes, human alveolar macrophages, and in vitro matured macrophages was evaluated by immunofluorescence, radioligand binding, and Northern analysis, using the monoclonal anti-human transferrin receptor antibody OKT9, [125I]-labeled human transferrin and a [32P]-labeled human transferrin receptor cDNA probe, respectively. By immunofluorescence, the majority of alveolar macrophages expressed transferrin receptors (86 +/- 3%). The radioligand binding assay demonstrated the affinity constant (Ka) of the alveolar macrophage transferrin receptor was 4.4 +/- 0.7 X 10(8) M-1, and the number of receptors per cell was 4.4 +/- 1.2 X 10(4). In marked contrast, transferrin receptors were not present on the surface or in the cytoplasm of blood monocytes, the precursors of the alveolar macrophages. However, when monocytes were cultured in vitro and allowed to mature, greater than 80% expressed transferrin receptors by day 6, and the receptors could be detected by day 3. Consistent with these observations, a transferrin receptor mRNA with a molecular size of 4.9 kb was demonstrated in alveolar macrophages and in vitro matured macrophages but not in blood monocytes. Thus, although blood monocytes do not express the transferrin receptor gene, it is expressed by mature macrophages, an event that probably occurs relatively early in the process of monocyte differentiation to macrophages.     

Studies on intravascular phagocytosis in the lung

In this paper we have shown for the first time endocytosis by intravascular lung phagocytes. Glutaraldehyde-treated erythrocytes (discocytes) homed rapidly to the rat lung as measured by scintigraphic procedures. Transmission and scanning electron microscopy showed that the discocytes are phagocytosed by macrophages, blood monocytes and granulocytes as whole cells. This process could not be inhibited by silica treatment.     

Cell separation in the buffy coat

One of the most rapid methods to determine cell counts in whole blood is by way of layer thickness measurements of the buffy coat. The purpose of this study was to determine the separation and purity of blood cells in the different layers of the buffy coat. Blood samples were centrifuged at 10,000 g in microhematocrit tubes with an inserted float to expand the buffy coat region. Whole blood from normal laboratory individuals separates by density into four regions: platelets, a layer of lymphocyte and monocytes, granulocytes and erythrocytes. A thin band of highly swollen red cells was discovered between the buffy coat layers of many normal volunteers and patients. Stereological analysis of electron micrographs showed that mixing of formed elements within the layers is less than 2% with the exception of some erythrocytes, which can make up a higher volume fraction in the lymphocyte/monocyte and granulocyte layers. The red cell column contains about 95.7% erythrocytes and is depleted of platelets and leukocytes. In approximately 5% of hospital blood samples, the granulocyte-erythrocyte interface was feathered and undetectable, and a significantly higher volume fraction of red cells was found among the granulocytes. Cell mass density determinations indicate that the erythrocytes in these abnormal granulocyte layers have a lowered mass density, overlapping with that of the granulocytes.     

Immunolocalization of 67 kDa elastin-binding protein in perinatal rat lungs

Summary 67 kDa elastin-binding protein (RL-67EBP) has been isolated from neonatal rat lungs by the use of an elastin-coupled affinity column, followed by elution with either lactose or synthetic elastin hexapeptide (VGVAPG), and immunohistochemistry has been used on perinatal rat lungs to determine the tissue localization of this protein. No immunoreactive structures occur in fetal lungs, or in the lungs of day-1 and-4 neonates. On day-7 after birth, immunoreactive cells appear in the subepithelial connective tissue of the intrapulmonary airways, from day-10 on, these cells become evenly distributed in the alveolar parenchyma. Occasionally, some cells occur in the alveolar air space, being free from the surface of the alveolar septum. Unpermeabilized cells obtained by bronchoalveolar lavage, show cell surface immunoreactivity, indicating that RL-67EBP is expressed on the surface membrane of the cells. From these findings, it is suggested that the immunoreactive cells are blood-borne monocytes, and that RL-67EBP may function as an elastin peptide receptor by which monocytes mobilize through interstitial connective tissue during their migration from blood to alveolar air space, where they eventually differentiate into alveolar macrophages.     

Alveolar macrophages: functional heterogeneity within macrophage populations from rat lung

Alveolar macrophages were obtained from the unstimulated lungs of rats by repeated endobronchial lavage and an interstitial macrophage population prepared by mincing the lungs subsequent to the lavage process. Considerable heterogeneity was observed within these macrophage populations with respect to cell size, surface morphology and cytochemistry. Functional studies, involving assessment of IgG-Fc receptor density/avidity and the expression of cytostatic activity in cultures of mitogen-stimulated lymphocytes, revealed comparable heterogeneity, and further indicated a considerably higher degree of apparent stimulation in the alveolar versus the interstitial macrophage population. Parallel assessment of the functional activity of blood monocytes, the immediate precursors of these latter macrophages, indicated a lower state of activation again. This suggests that the lung interstitium normally provides an intermediate environment between the blood and the alveolar spaces, wherein blood monocytes may undergo maturational changes before their efflux into the alveoli.     

Evidence that exogenous substances can be phagocytized by alveolar epithelial cells and transported into blood capillaries

Since the ability of alveolar epithelial cells to ingest inhaled fine particles has not been characterized in detail, the present study seeks to evaluate this physiological activity. We used a 0.2% suspension of intact or lecithin-coated polystyrene latex beads (240 nm in diameter). A 5-ml suspension of intact or lecithin-coated latex beads was intratracheally administered to rats using a compressor nebulizer. Thereafter, the lungs were perfused intratracheally with glutaraldehyde solution and cut into small pieces. The samples were postfixed with osmium tetroxide, embedded in epoxy resin and examined under an electron microscope. Both lecithin-coated and uncoated beads were incorporated into alveolar macrophages. Some of the ingested beads in the alveolar macrophages were sequestered within lysosomes. Types I and II alveolar epithelial cells selectively incorporated only lecithin-coated beads, which were also observed within the cytoplasm of monocytes in the capillary lumen. These findings suggest that alveolar epithelial cells can incorporate exogenous particles, which are then transferred from the alveoli to intravascular spaces by transcytosis.     

In vitro binding of Trypanosoma congolense to erythrocytes.

Trypanosoma congolense Broden, an intravascular parasite, binds to vessel walls and erythrocytes of infected hosts. In an attempt to characterize T. congolense adhesion to host cells, an in vitro assay was devised. It was shown in the in vitro experiments that T. congolense binds to bovine, sheep, and goat erythrocytes, but not always to erythrocytes of rats, mice, rabbits, horses or humans. Only the anterior part of live trypanosomes adheres to erythrocytes, and the attachment site on the trypanosomes is destroyed by trypsin and chymotrypsin-trypanosomes did not adhere to bovine erythrocytes that had been incubated with neuraminidase, sodium periodate and poly-L-lysine. The foregoing experiments suggest that the surface of T. congolense contains a protein-associated site which binds to sialic acid of some host cells. This surface site is most likely responsible for attachment to blood vessels in vivo.     

Alveolar macrophages have greater amounts of the enzyme 5-lipoxygenase than do monocytes.

Alveolar macrophages release greater amounts of leukotriene B4 (LTB4) and 5-hydroxyeicosatetraenoic acid (5-HETE) after A23187 stimulation than do blood monocytes. The mechanisms for this enhanced 5-lipoxygenase activity in alveolar macrophages are unknown. In these studies, we determined whether alveolar macrophages have greater amounts of the enzyme 5-lipoxygenase than do blood monocytes. We confirmed that alveolar macrophages released greater amounts of LTB4 after A23187 stimulation than did equivalent numbers of blood monocytes. In both the presence and absence of A23187, alveolar macrophages had greater amounts of immunoreactive 5-lipoxygenase, determined by Western analysis, on a per cell and a per protein basis than did blood monocytes. The amounts of 5-lipoxygenase enzyme in the cells roughly correlated with the amounts of LTB4 released by both types of cells. These observations suggest that A23187 stimulates alveolar macrophages to release greater amounts of LTB4 and 5-HETE than blood monocytes, in part, due to the greater amounts of 5-lipoxygenase.     

Preparation and characterization of 'heparinocytes': erythrocytes with covalently bound low molecular weight heparin

In an attempt to create the possibility of stable, long acting, intravascular anticoagulation, low molecular weight heparin was modified by introducing a sulfhydryl group into the molecule (LMWH-SH). Human erythrocytes were covalently grafted with LMWH-SH by the use of a heterobifunctional coupling reagent which reacts with the SH group of LMWH-SH and surface exposed amino groups of erythrocytes now called 'heparinocytes' (HC). HC were morphologically indistinguishable from untreated erythrocytes and displayed identical osmotic resistance. The functionality of HC was analyzed by classical coagulation tests in which they dose dependently inhibited clot formation. HC were also functional in recalcified whole blood inhibiting thrombin formation as assessed by the cleavage of the chromogenic substrate S-2238. The system appears applicable as a potential autologous, long-term anticoagulant treatment or prophylaxis.     

Alveolar macrophages differ from blood monocytes in human IL-1 beta release. Quantitation by enzyme-linked immunoassay

Fresh human alveolar macrophages and blood monocytes were stimulated with LPS and assessed for their ability to produce and release antigenic IL-1 beta. Using a sensitive and specific ELISA for IL-1 beta, monocytes released 13.3 +/- 3.1 ng/10(6) cells compared to 3.5 +/- 0.8 ng/10(6) cells for alveolar macrophages (p less than 0.01). To investigate the reason for this difference in IL-1 beta release, monocytes were compared to alveolar macrophages for total IL-1 beta production (i.e., the amount released plus that detected in the lysates). Monocytes produced a total of 19.0 +/- 3.2 ng/10(6) cells whereas alveolar macrophages produced 24.8 +/- 5.6 ng/10(6) cells (p = 0.37). The relative increase in alveolar macrophage intracellular IL-1 beta was confirmed by Western blot analysis of cell lysates. Thus, the limitation in IL-1 release from alveolar macrophages appears to be due to a decrease in the processing and release of the IL-1 beta precursor. In addition, TNF production studies demonstrated that the limitation in IL-1 release was not a generalized defect. In contrast to the IL-1 beta data, when TNF was measured from monocytes and macrophages, monocytes released only 14.6 +/- 3.4 ng/10(6), whereas macrophages released 101 +/- 30 ng/10(6) (p less than 0.02). In this same context, when fresh monocytes were allowed to mature in vitro they took on monokine production characteristics similar to alveolar macrophages. In vitro matured monocytes had a greater than 20-fold decrease in their ability to release IL-1 beta and a 6- to 8-fold increase in their ability to release TNF. Taken together, these studies suggest that IL-1 beta release is limited in mature mononuclear phagocytes as compared to fresh blood monocytes, and furthermore, that IL-1 beta regulation differs significantly from that of TNF-alpha.     

Cellular penetration of fluorescently labeled superoxide dismutases of various origins.

BACKGROUND: Using fluorescently labeled superoxide dismutase (SOD) and flow cytometry, we have shown previously that the enzyme CuZn SOD (EC 1.15.1.1) from bovine erythrocytes binds rapidly to the cell surface with slow uptake into the cell during the following hours. The degree of labeling was most important for monocytes in comparison to other blood cells (erythrocytes, lymphocytes, and neutrophils) and fibroblasts. In agreement with the flow-cytometric findings, the inhibition of superoxide production was more important for SOD-pretreated monocytes than for neutrophils, as demonstrated with the cytochrome c reduction assay. It was thus of interest to confirm the observed differences between monocytes and neutrophils with confocal laser microscopy, study in greater detail the kinetics of binding, penetration, and intracellular localization of the enzyme, and compare the results obtained with bovine CuZn SOD with those from SODs of other origins and carrying different active sites. MATERIALS AND METHODS: Recombinant human (rh), bovine, and equine CuZn SODs, as well as rh and E. coli Mn SODs, were studied before use with respect to specific activity and purity (HPLC, SDS-PAGE electrophoresis). Fluorescein isothiocyanate was covalently conjugated to the various SODs for study with high-resolution confocal scanning laser microscopy. Superoxide production by monocytes and neutrophils was measured with the cytochrome c assay. RESULTS: As expected from our experiments with flow cytometry, only rare neutrophils were labeled with FITC-SOD, even with the longest incubation time of 3 hr and the highest dose of 1500 units/ml. In addition, they showed a localized fluorescence pattern that was quite different from the diffuse punctate fluorescence pattern of monocytes. Lymphocytes were not labeled at all. The rapid binding to the cellular surface of monocytes was confirmed, and even after 5 min of preincubation, FITC-SOD was found on a small percentage of monocytes. This was correlated with a reduction in superoxide release after phorbolmyristate acetate (PMA) stimulation by 40%. An interesting finding was the perinuclear accumulation of the penetrated SOD after the longest pretreatment of 3 hr, suggesting a barrier against further progression. Indeed, through confocal microscopy we were able to exclude any fluorescence at the nuclear level. While the fluorescence labeling patterns and the kinetics of penetration were quite similar for bovine, equine, and rh CuZn SOD, the Mn SODs showed poor labeling, correlated with a weak inhibitory effect on cytochrome c reduction, which was not statistically significant. CONCLUSIONS: The rapid binding of native CuZn SODs on the surface of monocytes, leading to reduced superoxide release by these cells, explains the observation that beneficial effects of injected SOD lasted for months despite rapid clearance of the enzyme from the bloodstream, according to pharmacodynamic studies. The preferential binding to monocytes, in contrast to neutrophils, may play a role in chronic inflammatory diseases in which the monocytes are in an activated state. The differences in binding capacity between CuZn SODs and Mn SODs, correlated with different inhibitory effects of superoxide production by monocytes, may also have therapeutic significance.     

Alveolar epithelial cells direct monocyte transepithelial migration upon influenza virus infection: impact of chemokines and adhesion molecules

Influenza A virus pneumonia is characterized by severe lung injury and high mortality. Early infection elicits a strong recruitment of monocytes from the peripheral blood across the endo-/epithelial barrier into the alveolar air space. However, it is currently unclear which of the infected resident lung cell populations, alveolar epithelial cells or alveolar macrophages, elicit monocyte recruitment during influenza A virus infection. In the current study, we investigated whether influenza A virus infection of primary alveolar epithelial cells and resident alveolar macrophages would elicit a basal-to-apical monocyte transepithelial migration in vitro. We found that infection of alveolar epithelial cells with the mouse-adapted influenza A virus strain PR/8 strongly induced the release of monocyte chemoattractants CCL2 and CCL5 followed by a strong monocyte transepithelial migration, and this monocytic response was strictly dependent on monocyte CCR2 but not CCR5 chemokine receptor expression. Analysis of the adhesion molecule pathways demonstrated a role of ICAM-1, VCAM-1, integrin-associated protein (CD47), and junctional adhesion molecule-c on the epithelial cell surface interacting with monocyte beta(1) and beta(2) integrins and integrin-associated protein in the monocyte transmigration process. Importantly, addition of influenza A virus-infected alveolar macrophages further enhanced monocyte transmigration across virus-infected epithelium in a TNF-alpha-dependent manner. Collectively, the data show an active role for virus-infected alveolar epithelium in the regulation of CCL2/CCR2-dependent monocyte transepithelial migration during influenza infection that is essentially dependent on both classical beta(1) and beta(2) integrins but also junctional adhesion molecule pathways.