Venus A. Wong

Rapid fluorescence-based measurement of neutrophil migration in vitro

We have standardized a new chemotaxis chamber that uses fluorescence as the cellular marker for the measurement of leukocyte migration in vitro in disposable 96-well microplates. This new fluorescence-based assay is a robust assay because filter pore size, cell density, filter composition, and filter thickness do not affect PMN migration towards interleukin-8 or the complement fragment, C5a. When compared to two separate chemotaxis assays in which the migrated cells are counted visually, the fluorescence-based assay was more rapid, less labor intensive, and more sensitive. This new assay is a significant advance in the measurement of leukocyte migration in vitro.

Duffy Antigen Facilitates Movement of Chemokine Across the Endothelium In Vitro and Promotes Neutrophil Transmigration In Vitro and In Vivo

The Duffy Ag expressed on RBCs, capillaries, and postcapillary venular endothelial cells binds selective CXC and CC chemokines with high affinity. Cells transfected with the Duffy Ag internalize but do not degrade chemokine ligand. It has been proposed that Duffy Ag transports chemokines across the endothelium. We hypothesized that Duffy Ag participates in the movement of chemokines across the endothelium and, by doing so, modifies neutrophil transmigration. We found that the Duffy Ag transfected into human endothelial cells facilitates movement of the radiolabeled CXC chemokine, growth related oncogene-α/CXC chemokine ligand 1 (GRO-α/CXCL1), across an endothelial monolayer. In addition, neutrophil migration toward GRO-α/CXCL1 and IL-8 (IL-8/CXCL8) was enhanced across an endothelial monolayer expressing the Duffy Ag. Furthermore, GRO-α/CXCL1 stimulation of endothelial cells expressing the Duffy Ag did not affect gene expression by oligonucleotide microarray analysis. These in vitro observations are supported by the finding that IL-8/CXCL8-driven neutrophil recruitment into the lungs was markedly attenuated in transgenic mice lacking the Duffy Ag. We conclude that Duffy Ag has a role in enhancing leukocyte recruitment to sites of inflammation by facilitating movement of chemokines across the endothelium.

A new method for studying gradient-induced neutrophil desensitization based on an open microfluidic chamber

During inflammation neutrophils rapidly migrate to the site of tissue damage or infection by following complex gradients of bacterial peptides and host-derived chemokines. The efficiency and speed of neutrophil migration is critically dependent upon the ability of neutrophils to sense new gradients and utilize only those that provide the most direct path to the damaged or infected site. Receptor desensitization plays an important role in migration efficiency and is most commonly studied using bath application of chemotactic factor solutions instead of presenting cells with gradients analogous to those they would experience in vivo. Here we describe a new method for examining gradient-induced neutrophil desensitization using a previously-developed open-chamber microfluidic gradient generator.

Fas-Mediated Acute Lung Injury Requires Fas Expression on Nonmyeloid Cells of the Lung

Fas (CD95) is a membrane surface receptor, which, in the lungs, is expressed in macrophages, neutrophils, and epithelial cells. In mice, Fas activation leads to a form of lung injury characterized by increased alveolar permeability. We investigated whether Fas-mediated lung injury occurs primarily as a result of Fas activation in myeloid cells (such as macrophages) or in nonmyeloid cells (such as epithelial cells). Chimeric mice lacking Fas in either myeloid or nonmyeloid cells were generated by transplanting marrow cells from lpr mice (which lack Fas) into lethally irradiated C57BL/6 mice (MyFas− group) or vice versa (MyFas+ group). Additional mice transplanted with marrow cells from their same strain served as controls (Fas+ ctr and Fas− ctr groups). Sixty days after transplantation, the mice received intratracheal instillations of the Fas-activating mAb Jo2 (n = 10/group), or an isotype control Ab (n = 10/group), and were euthanized 24-h later. Only animals expressing Fas in nonmyeloid cells (Fas+ ctr and MyFas−) showed significant increases in lung neutrophil content and in alveolar permeability. These same mice showed tissue evidence of lung injury and caspase-3 activation in cells of the alveolar walls. Despite differences in the neutrophilic response and lung injury, there was no statistical difference in the lung cytokine concentrations (KC and MIP-2) among groups. We conclude that Fas-mediated lung injury requires expression of Fas on nonmyeloid cells of the lungs. These findings suggest that the alveolar epithelium is the primary target of Fas-mediated acute lung injury, and demonstrate that apoptotic processes may be associated with neutrophilic inflammation.

The biological activity of FasL in human and mouse lungs is determined by the structure of its stalk region

Acute lung injury (ALI) is a life-threatening condition in critically ill patients. Injury to the alveolar epithelium is a critical event in ALI, and accumulating evidence suggests that it is linked to proapoptotic Fas/FasL signals. Active soluble FasL (sFasL) is detectable in the bronchoalveolar lavage (BAL) fluid of patients with ALI, but the mechanisms controlling its bioactivity are unclear. We therefore investigated how the structure of sFasL influences cellular activation in human and mouse lungs and the role of oxidants and proteases in modifying sFasL activity. The sFasL in BAL fluid from patients with ALI was bioactive and present in high molecular weight multimers and aggregates. Oxidants generated from neutrophil myeloperoxidase in BAL fluid promoted aggregation of sFasL in vitro and in vivo. Oxidation increased the biological activity of sFasL at low concentrations but degraded sFasL at high concentrations. The amino-terminal extracellular stalk region of human sFasL was required to induce lung injury in mice, and proteolytic cleavage of the stalk region by MMP-7 reduced the bioactivity of sFasL in human cells in vitro. The sFasL recovered from the lungs of patients with ALI contained both oxidized methionine residues and the stalk region. These data provide what we believe to be new insights into the structural determinants of sFasL bioactivity in the lungs of patients with ALI.

Blockade of the Fas/FasL system improves pneumococcal clearance from the lungs without preventing dissemination of bacteria to the spleen

BACKGROUND The Fas/FasL system is both proapoptotic and proinflammatory. FasL is inhibited by decoy receptor-3 (DcR3), a naturally occurring decoy receptor. We determined the effects of systemic blockade of the Fas/FasL system by a DcR3 analog (DcR3-a) in mice with pneumococcal pneumonia. METHODS Streptococcus pneumoniae (7.2 x 105 or 1.9 x 107 cfu/mL) was instilled intratracheally into untreated C57Bl/6 mice, C57Bl/6 mice treated with DcR3-a, or Fas-deficient lpr mice, and the mice were studied 48 h later. RESULTS After instillation of the lower bacterial dose, disruption of the Fas/FasL system by either DcR3-a or the lpr mutation resulted in improved clearance of bacteria in the lungs (mean +/- SE, 4.6+/-2.1 x 10(6) and 3.5 +/- 1.6 x 10(6) cfu/lung, respectively, vs. 21.9+/-9.3 x 10(6) cfu/lung in untreated C57Bl/6 mice; P<.05) and decreased percentage of polymorphonuclear neutrophils in bronchoalveolar lavage fluid (mean +/- SE, 19.3%+/-9.5% and 20.2%+/-7.8%, respectively, vs. 55.0%+/-12.2% in untreated C57Bl/6 mice; P<.05). These changes were associated with decreased lung concentrations of the proinflammatory cytokines tumor necrosis factor- alpha and macrophage inflammatory protein-2 and with a decrease in apoptotic cells in the alveolar walls. CONCLUSION Blockade of the Fas/FasL system by DcR3-a in the lungs improves clearance of bacteria in mice with pneumococcal pneumonia.

Enhanced expression of Duffy antigen in the lungs during suppurative pneumonia.

Duffy antigen is a chemokine binding protein expressed on the surface of erythrocytes and postcapillary venular endothelial cells. It binds selective CXC and CC chemokines with high affinity. Although Duffy antigen is present in the normal pulmonary vascular bed, it is not known whether its expression is altered by innate inflammatory responses in the lungs. We studied Duffy antigen expression by immunohistochemistry in autopsy lung specimens from 16 cases of suppurative pneumonia, 11 cases of acute lung injury, and seven normal lungs. In lungs with suppurative pneumonia, Duffy antigen was expressed in higher numbers of pre- and postcapillary parenchymal vessels compared to normal specimens or specimens with acute lung injury (p<0.03 and p<0.02, respectively). Lungs with suppurative pneumonia also showed Duffy antigen expression on the alveolar septa, whereas this was a rare finding in normal specimens or in acute lung injury (p<0.02). Furthermore, Duffy antigen labeling of the alveolar septa localized to regions with airspace accumulation of neutrophil-rich exudates. In summary, Duffy antigen expression is increased in the vascular beds and alveolar septa of the lung parenchyma during suppurative pneumonia, suggesting that Duffy antigen may have a functional role in the lung parenchyma during inflammation.

Febrile-Range Hyperthermia Augments Lipopolysaccharide-Induced Lung Injury by a Mechanism of Enhanced Alveolar Epithelial Apoptosis

Fever is common in critically ill patients and is associated with worse clinical outcomes, including increased intensive care unit mortality. In animal models, febrile-range hyperthermia (FRH) worsens acute lung injury, but the mechanisms by which this occurs remain uncertain. We hypothesized that FRH augments the response of the alveolar epithelium to TNF-α receptor family signaling. We found that FRH augmented LPS-induced lung injury and increased LPS-induced mortality in mice. At 24 h, animals exposed to hyperthermia and LPS had significant increases in alveolar permeability without changes in inflammatory cells in bronchoalveolar lavage fluid or lung tissue as compared with animals exposed to LPS alone. The increase in alveolar permeability was associated with an increase in alveolar epithelial apoptosis and was attenuated by caspase inhibition with zVAD.fmk. At 48 h, the animals exposed to hyperthermia and LPS had an enhanced lung inflammatory response. In murine lung epithelial cell lines (MLE-15, LA-4) and in primary type II alveolar epithelial cells, FRH enhanced apoptosis in response to TNF-α but not Fas ligand. The increase in apoptosis was caspase-8 dependent and associated with suppression of NF-κB activity. The FRH-associated NF-κB suppression was not associated with persistence of IκB-α, suggesting that FRH-mediated suppression of NF-κB occurs by means other than alteration of IκB-α kinetics. These data show for the first time that FRH promotes lung injury in part by increasing lung epithelial apoptosis. The enhanced apoptotic response might relate to FRH-mediated suppression of NF-κB activity in the alveolar epithelium with a resultant increase in susceptibility to TNF-α–mediated cell death.

Cloning of two rabbit GRO homologues and their expression in alveolar macrophages

We cloned two rabbit GRO homologue cDNAs from a lipopolysaccharide-stimulated rabbit alveolar macrophage (AM) cDNA library. One cDNA contains the complete coding sequence for a new mature GRO protein, RabGRO, which shares 68, 78 and 70% amino-acid identity with human GRO-alpha, -beta and -gamma, respectively. The other cDNA contains previously unreported sequence encoding a second GRO protein, rabbit permeability factor 2. The two Rab GRO proteins share 93% identity. Northern analysis shows that Rab AM GRO expression is rapidly induced by lipopolysaccharide. These findings suggest that GRO chemokines may be important in the pulmonary inflammation that occurs with septic lung injury.

The Fas/FasL pathway impairs the alveolar fluid clearance in mouse lungs.

Alveolar epithelial damage is a critical event that leads to protein-rich edema in acute lung injury (ALI), but the mechanisms leading to epithelial damage are not completely understood. Cell death by necrosis and apoptosis occurs in alveolar epithelial cells in the lungs of patients with ALI. Fas activation induces apoptosis of alveolar epithelial cells, but its role in the formation of lung edema is unclear. The main goal of this study was to determine whether activation of the Fas/Fas ligand pathway in the lungs could alter the function of the lung epithelium, and the mechanisms involved. The results show that Fas activation alters the alveolar barrier integrity and impairs the ability of the lung alveolar epithelium to reabsorb fluid from the air spaces. This result was dependent on the presence of a normal Fas receptor and was not affected by inflammation induced by Fas activation. Alteration of the fluid transport properties of the alveolar epithelium was partially restored by β-adrenergic stimulation. Fas activation also caused apoptosis of alveolar endothelial cells, but this effect was less pronounced than the effect on the alveolar epithelium. Thus, activation of the Fas pathway impairs alveolar epithelial function in mouse lungs by mechanisms involving caspase-dependent apoptosis, suggesting that targeting apoptotic pathways could reduce the formation of lung edema in ALI.