Bleomycin-induced pulmonary fibrosis in fibrinogen-null mice.

Mice deleted for the plasminogen activator inhibitor-1 (PAI-1) gene are relatively protected from developing pulmonary fibrosis induced by bleomycin. We hypothesized that PAI-1 deficiency reduces fibrosis by promoting plasminogen activation and accelerating the clearance of fibrin matrices that accumulate within the damaged lung. In support of this hypothesis, we found that the lungs of PAI-1(-/-) mice accumulated less fibrin after injury than wild-type mice, due in part to enhanced fibrinolytic activity. To further substantiate the importance of fibrin removal as the mechanism by which PAI-1 deficiency limited bleomycin-induced fibrosis, bleomycin was administered to mice deficient in the gene for the Aalpha-chain of fibrinogen (fib). Contrary to our expectation, fib(-/-) mice developed pulmonary fibrosis to a degree similar to fib(+/-) littermate controls, which have a plasma fibrinogen level that is 70% of that of wild-type mice. Although elimination of fibrin from the lung was not in itself protective, the beneficial effect of PAI-1 deficiency was still associated with proteolytic activity of the plasminogen activation system. In particular, inhibition of plasmin activation and/or activity by tranexamic acid reversed both the accelerated fibrin clearance and the protective effect of PAI-1 deficiency. We conclude that protection from fibrosis by PAI-1 deficiency is dependent upon increased proteolytic activity of the plasminogen activation system; however, complete removal of fibrin is not sufficient to protect the lung.

Treatment of bleomycin-induced pulmonary fibrosis by transfer of urokinase-type plasminogen activator genes.

During acute and chronic inflammatory lung diseases, the normal fibrinolytic activity in the alveolar space is inhibited by increased levels of plasminogen activator inhibitor 1 (PAI-1). Transgenic mice having increased fibrinolytic activity due to genetic deficiency of PAI-1 develop less fibrosis after bleomycin-induced lung inflammation. These observations led us to hypothesize that pulmonary fibrosis could be limited through enhancement of alveolar fibrinolytic activity by adenovirus-mediated transfer of the urokinase-type plasminogen activator (uPA) gene to the lung. To investigate this hypothesis, 0.075 U of bleomycin was introduced intratracheally into mice. Twenty-one days later, the mice were treated intratracheally with phosphate-buffered saline (PBS), a control adenovirus, or adenoviruses containing murine or human uPA cDNAs. On day 28, the mice were sacrificed, and lung fibrosis was quantitated by measuring hydroxyproline content. As expected, bleomycin caused a doubling in lung hydroxyproline to 345.6+/-28.2 microg/lung (SEM) compared with mice receiving PBS (170.2+/-4.0 microg/lung). Treatment of the bleomycin-injured mice with the control adenovirus on day 21 had no impact on lung fibrosis (338.4+/-17.2 microg/lung). Importantly, the human uPA adenovirus significantly reduced (p<0.05) lung hydroxyproline (281.2+/-22.8 microg/lung), thus attenuating by 38% the bleomycin-induced increase in lung collagen. The improvement in bleomycin-induced lung fibrosis resulting from treatment with the human uPA adenovirus further supports the importance of the fibrinolytic system during inflammatory lung injury and repair.

Upregulation of fibrinolysis by adenovirus-mediated transfer of urokinase-type plasminogen activator genes to lung cells in vitro and in vivo.

Impaired fibrinolytic activity within the lungs is a common manifestation of acute and chronic inflammatory lung diseases. Our previous work using transgenic mice showed that upregulation of fibrinolysis reduced pulmonary fibrosis following bleomycin-induced inflammatory lung injury. As a strategy to accelerate fibrinolysis, we generated recombinant adenoviruses containing human and mouse urokinase-type plasminogen activator (uPA) cDNAs. Both vectors induced the expression of functional uPA in human lung-derived epithelial A549 cells. A single intratracheal instillation of these uPA-containing adenoviruses into mouse lungs resulted in increased plasminogen activator activity in bronchoalveolar lavage fluid for at least 2 weeks. Plasma-derived fibrin-rich matrices overlaid on A549 cells infected with these uPA vectors were lysed efficiently in a dose-dependent fashion. Similarly, fibrin matrices formed within intact lungs that had been infected with these uPA-containing adenoviruses were also lysed more rapidly compared with noninfected and control virus-infected lungs. These results indicate that adenovirus-mediated transduction of uPA successfully upregulates fibrinolysis in vitro and in vivo. These uPA vectors can be readily used for testing the role of the fibrinolytic system in animal models of lung fibrosis, with particular attention to their therapeutic potential.

Intrapulmonary tumor necrosis factor gene therapy increases bacterial clearance and survival in murine gram-negative pneumonia.

Tumor necrosis factor alpha (TNF) has been shown to be an essential cytokine mediator of innate immunity in bacterial pneumonia. To augment the expression of TNF within the lung, a recombinant adenoviral vector containing the murine TNF cDNA (Ad5mTNF) has been developed, and the intratracheal administration of this vector resulted in the dose- and time-dependent expression of TNF in the lung, but not systemically. Administration of Ad5mTNF resulted in significant airspace and peribronchial inflammation, with a predominant neutrophil influx by 2 days, and mononuclear cell infiltrates by 4 to 7 days posttreatment. Importantly, the administration of Ad5mTNF at a dose of 1 x 10(8) PFU significantly improved the survival of animals challenged concomitantly with Klebsiella pneumoniae, which occurred in association with enhanced clearance of bacteria from the lung and decreased dissemination of K. pneumoniae to the bloodstream. However, the delivery of higher doses of Ad5mTNF (5 x 10(8) PFU) was not beneficial and in fact the intratracheal administration of a similar dose of control vector (Ad5LacZ) actually enhanced Klebsiella-induced lethality by impairing clearance of K. pneumoniae from the lung. Our studies suggests that the transient transgenic expression of TNF within the lung dose dependently augments antibacterial host defense in murine Klebsiella pneumonia.

An improved method for immobilizing IgG antibodies on protein A-agarose.

This report describes a modification of a procedure developed by others for crosslinking IgG to protein A which itself is covalently linked to a gel support. Earlier immunoaffinity columns were described as having large antigen-binding capacities and stability under a variety of elution conditions. The present data show that columns constructed with earlier techniques were only partially stable to pH 3.0 buffers, and, as a result, bound less than 20% of the antigen predicted by theory. Modifying parameters of the dimethylpimelimidate crosslinking method led to immunoaffinity columns which did not leak immunoglobulin under low pH elution buffer conditions. The new immunoaffinity absorbants, because of the increased strength of the couple between the antibody and protein A, were capable of binding antigen at over 80% of their theoretical capacity.

The plasminogen activation system in lung disease.

The importance of the plasminogen activator (PA) system in multiple pulmonary disorders has become increasingly apparent as methods to analyze its components have improved. Early investigations discovered that the pulmonary alveolar space is normally a pro-fibrinolytic environment that is diminished in a variety of lung diseases. Interest in these observations was greatly increased when animal experiments revealed that manipulations of the PA system significantly modulated the tissue fibrosis that follows many types of lung injury. In particular, enhancement of PA activity was found to consistently decrease the extent of scarring induced by lung damage. Based upon these early observations, it was hypothesized that fibrin was necessary for the pathogenesis of lung fibrosis, and that an increase in PA activity would reduce collagen accumulation by accelerating the clearance of fibrin from the provisional matrix. However, as is often the case with simple hypotheses, subsequent studies revealed that the actual role of the PA system in pulmonary disease is much more complex. Possible mechanisms beyond fibrinolysis include degradation of other matrix proteins, activation of protease cascades including those involving matrix metalloproteinases, activation and release of growth factors from sites of production and sequestration, and modulation of cell adhesion and motility. In each of these processes, the serpin plasminogen activator inhibitor-1 (PAI-1) plays a central role. For these reasons, it has become apparent that PAI-1 presents an attractive target to influence multiple disease processes within the lung, particularly those that lead to lung fibrosis.

Participation of urokinase-type plasminogen activator receptor in the clearance of fibrin from the lung.

In vitro studies have demonstrated that the binding of urokinase-type plasminogen activator (uPA) to its cell surface receptor (uPAR) greatly accelerates plasminogen activation. However, the role of uPAR in clearing abnormal fibrin deposits from the lung is uncertain. Knowing that uPA binding to uPAR is species specific, we used adenoviral vectors to transfer human or murine uPA genes into human or mouse epithelial cells in vitro and to mouse lungs in vivo. By measuring degradation of fluorescein-labeled fibrin, we found that uPA lysed fibrin matrices more efficiently when expressed in cells of the same species. A monoclonal antibody that blocks the binding of human uPA to human uPAR suppressed fibrin degradation by human cells expressing human uPA but not murine uPA. Importantly, 3 days after intratracheal delivery of the vectors, mice receiving murine uPA transgenes degraded fibrin matrices formed within their air spaces more efficiently than animals transduced with human uPA genes. These results show that uPA bound to uPAR increases the efficiency of fibrinolysis on epithelial cell surfaces in a biologically relevant fashion.