Induction of Fibrinogen Biosynthesis and Secretion From Cultured Pulmonary Epithelial Cells

Fibrinogen modulates gene expression in wounded fibroblasts

Fibrinogen (FBG) has long been regarded as serving essentially a hemostatic role by its conversion from a soluble, plasma protein to an insoluble fibrin gel. However, several extrahepatic sites of FBG biosynthesis have been identified. Indeed, we have demonstrated that both lung epithelial cell derived and plasma FBG assemble into the extracellular matrix (ECM) of epithelial cells and fibroblasts. In this report, we determined that FBG assembly into the ECM is a cell dependent step that occurs in the absence of de novo protein synthesis. Using an in vitro model of wound repair, we examined the role of FBG in modulating gene expression. Data collected from cDNA array analysis indicated that FBG downregulates steady state levels of fibronectin mRNA, whereas cyclin D1 mRNA levels were upregulated in fibroblasts. Taken together, these data suggest that FBG may function independently of hemostasis in cellular adhesive interactions to modulate cellular signaling processes during wound repair.

Transcriptional control mechanism of fibrinogen gene expression

Although fibrinogen genes are expressed constitutively in hepatocytes, their transcription can be greatly increased during inflammatory stress. Extensive studies have focused on the cytokine mediated transcriptional regulation of fibrinogen genes. It is clear that interleukin-6 (IL-6) and its family of cytokines are the major inducers of fibrinogen gene expression. Functional analyses of all three fibrinogen promoters for human and rat all demonstrate that the conserved CTGGGAA motifs within the proximal promoter of each fibrinogen gene are the IL-6 responsive elements. Exploration of the rat gamma fibrinogen gene demonstrated that the IL-6 activated transcription factor, STAT3, binds to the CTGGGAA motif and is required for the IL-6 mediated upregulation of this gene. IL-6 mediated fibrinogen production can be significantly elevated by glucocorticoid treatment. The synergistic effect of glucocorticoids and IL-6 relies on the functional interaction between STAT3 and glucocorticoid receptor. In addition to the upregulation signals for fibrinogen gene expression during inflammatory stress, other signaling also downregulates the expression of fibrinogen genes. For example, the proinflammatory cytokine IL-1 beta exerts inhibitory function on IL-6 mediated fibrinogen gene expression. Given the fact that elevated levels of fibrinogen in blood correlate with increased risk for cardiovascular disease, there is strong motivation to explore the molecular mechanisms that control fibrinogen expression, especially those signals that may downmodulate expression and thus provide novel approaches to controlling fibrinogen levels.

Tumors and fibrinogen. The role of fibrinogen as an extracellular matrix protein

The progression of a tumor from benign and localized to invasive and metastatic growth is the major cause of poor clinical outcome in cancer patients. Much like in a healing wound, the deposition of fibrin(ogen), along with other adhesive glycoproteins, into the extracellular matrix (ECM) serves as a scaffold to support binding of growth factors and to promote the cellular responses of adhesion, proliferation, and migration during angiogenesis and tumor cell growth. Inappropriate synthesis and deposition of ECM constituents is linked to altered regulation of cell proliferation, leading to tumor cell growth and malignant transformation. Fibrin deposition occurs within the stroma of a majority of tumor types. In contrast, abundant FBG, not fibrin, is present within the stroma of breast cancers. It is thought to originate from exudation of plasma FBG and subsequent deposition into the tumor stroma and not endogenous synthesis and secretion of FBG by breast tumor cells. However, we show that MCF-7 human breast cancer cells synthesize and secrete FBG polypeptides, suggesting that the origin of FBG in the stroma of breast carcinoma may be due to endogenous synthesis and deposition. Moreover, FBG assembles into ECM as conformationally altered FBG, not as fibrin. Studies in our laboratory demonstrate that FBG alters the ability of breast cancer cells to migrate. Together, the results of studies from our laboratory, as well as the laboratories of others, indicate that the presence of fibrin(ogen) within the tumor stroma likely affects the progression of tumor cell growth and metastasis. This review focuses on FBG within tumors and its relationship with other tumor constituents, ultimately focusing on the role of FBG in breast cancer.

Integrin alphavbeta3-mediated endocytosis of immobilized fibrinogen by A549 lung alveolar epithelial cells

Fibrinogen (FBG), together with its polymerized form fibrin, modulates cellular responses during wound repair and tissue remodeling. Thus, we sought to determine whether A549 lung epithelial type II-like cells would endocytose insoluble, surface-bound FBG as a potential mechanism of alveolar matrix remodeling. Surface-bound FBG was endocytosed into either lysosomes or late endosomes by A549 cells through arg-gly-asp-dependent binding to alphavbeta3 but not alpha5beta1 integrin receptors. Soluble FBG added to confluent monolayers of A549 cells was not endocytosed. Unlike the uptake of the extracellular matrix glycoproteins vitronectin and thrombospondin by other cell types, endocytosis of FBG by A549 cells was neither inhibited by heparin nor dependent on binding to cell-surface heparan sulfate proteoglycans. FBG did not colocalize with endocytosed transferrin, whereas dextran showed partial colocalization with FBG in endocytic vesicles, suggesting nonclathrin-mediated endocytosis. Inhibition of actin filament polymerization blocked endocytosis of both dextran and FBG but not transferrin, providing further support that FBG is endocytosed via a nonclathrin pathway. Disruption of actin polymerization inhibited integrin-mediated cell spreading, which contributed to an overall reduction in FBG clearance that was most likely due to reduced cell migration and associated pericellular proteolysis. Trasylol inhibition of extracellular plasmin activity did not inhibit endocytosis of FBG. The endocytosed FBG was degraded to trichloroacetic acid-soluble fragments that showed an electrophoretic pattern distinctly different from plasmin-degraded FBG. Together, these results suggest that endocytosis of matrix-associated FBG by alveolar epithelial cells may be involved in the processes of alveolar tissue repair and matrix remodeling.

Production of the acute-phase protein lipopolysaccharide-binding protein by respiratory type II epithelial cells: implications for local defense to bacterial endotoxins

This study demonstrates for the first time that respiratory epithelial cells are able to produce the acute phase protein lipopolysaccharide (LPS)-binding protein (LBP), which is known to play a central role in the defense to bacterial endotoxins (or LPS). Indications for local presence of LBP in human lung was obtained via reverse transcriptase/polymerase chain reaction that showed LBP messenger RNA (mRNA) expression. Therefore, LBP production by the human lung epithelial cell line A549, a human adenocarcinoma with features of type II pneumocytes, was studied. These cells produced LBP in response to interleukin (IL)-1beta, IL-6, and tumor necrosis factor- alpha, a response that was strongly enhanced by dexamethasone. In addition, LBP mRNA was detected in A549 cells, in increasing amounts as a result of stimulation. The pattern of cytokine-induced LBP production in A549 cells was similar to the pattern in the human liver epithelial cell line HuH-7. Moreover, the molecular weight of A549-derived LBP was approximately 60 kD, which is similar to HuH-7-derived LBP. Biologic activity of LBP produced by A549 cells was evaluated on the basis of its ability to interact with LPS. Further indications that type II alveolar epithelial cells are able to produce LBP were obtained from the observations that the murine lung type II epithelial cell line C10 produced murine LBP, and that isolated human primary type II pneumocytes expressed LBP mRNA, which was enhanced after stimulation of cells. The local production of this endotoxin binding protein by lung epithelial cells might contribute to a highly specific response at the site of exposure to bacteria and bacterial endotoxins.

Cell type-specific regulation of fibrinogen expression in lung epithelial cells by dexamethasone and interleukin-1beta

Our recent studies demonstrating the expression of fibrinogen (FBG) by an alveolar type II cell line stimulated with proinflammatory mediators and also in the inflamed pulmonary epithelium of animals with Pneumocystis carinii pneumonia suggest that extrahepatic FBG participates in the local acute phase response (APR) to infection and subsequent wound repair. However, the mechanisms that regulate extrahepatic FBG expression are poorly understood. This study compares the regulation of hepatic and pulmonary FBG expression by mediators of the APR, interleukin (IL)-6, IL-1beta, and dexamethasone (DEX), a synthetic glucocorticoid. Northern blotting and metabolic labeling studies revealed that IL-6 with or without DEX upregulates gammaFBG messenger RNA and protein, whereas IL-1beta inhibits gammaFBG expression in human lung (A549) and liver (HepG2) epithelial cells. In contrast, the addition of DEX relieved the IL-1beta-mediated inhibition of FBG expression in lung epithelial cells only; this response is termed "DEX rescue." Studies with cycloheximide indicate that only DEX rescue required de novo protein synthesis. Nuclear run-on analysis revealed no increase in gammaFBG transcription by DEX treatment. Although DEX treatment alone increased the stability of gammaFBG transcripts in lung cells, this effect was not observed in the presence of IL-1beta. Together, these results suggest that pre-existing transcription factors mediate the effects of IL-6 with or without DEX, DEX, and IL-1beta on gammaFBG gene expression in lung and liver cells. Also, the data suggest that DEX induces new protein synthesis of an inhibitor of IL-1beta signal transduction to effectively "rescue" FBG production in lung but not liver epithelial cells. This cell type-specific stimulation of FBG production by glucocorticoids to overcome IL-1beta inhibition may promote pulmonary wound repair mechanisms.

Human bronchoalveolar lavage fluid: two-dimensional gel electrophoresis, amino acid microsequencing and identification of major proteins

Although bronchoalveolar lavage has been used as a research and clinical tools for more than two decades to investigate the cellular and soluble components of the lower respiratory tract, its exact protein composition has never been established. In this context, proteins of human bronchoalveolar lavage fluids (BALF), obtained by washing the epithelial lining fluid of the lungs with phosphate-buffered saline, were analyzed by two-dimensional electrophoresis (2-DE) under denaturing and reducing conditions. To characterize the widest amount of proteins, an analytical map of human bronchoalveolar lavage fluid proteins has been created from a pool of BALF from various patients. The resulting map comprises 211 silver-stained spots in the range of pI 3.5-10 and molecular mass 5-100 kDa. We identified 182 spots by microsequence analysis and by matching with human blood plasma and the Macrophage Like Cell line reference 2-DE maps available from the SWISS-2DPAGE database. The human bronchoalveolar lavage fluid was found to contain 61 different proteins or isoforms thereof. Most of the proteins had low molecular masses (< 35 kDa) and rather acidic isoelectric points (pI; 4 < pI < 7). The proteins in the lavage either are produced locally or originate from plasma. Two unknown proteins were identified and are currently under investigation.

Induction of fibrinogen expression in the lung epithelium during Pneumocystis carinii pneumonia

Pneumocystis carinii is an important pulmonary pathogen responsible for morbidity and mortality in patients with AIDS. The acute-phase response (APR), the primary mechanism used by the body to restore homeostasis following infection, is characterized by increased levels of circulating fibrinogen (FBG). Although the liver is the primary site of increased FBG synthesis during the APR, we unexpectedly discovered that FBG is synthesized and secreted by lung alveolar epithelial cells in vitro during an inflammatory stimulus. Therefore, we sought to determine whether lung epithelial cells produce FBG in vivo using animal models of P. carinii pneumonia (PCP). Inflammation was noted by an influx of macrophages to P. carinii-infected alveoli. Northern hybridization revealed that gamma-FBG mRNA increased two- to fivefold in P. carinii-infected lung tissue, while RNA in situ hybridization demonstrated increased levels of gamma-FBG mRNA in the lung epithelium. Immunoelectron microscopy detected lung epithelial cell-specific production of FBG, suggesting induction of a localized inflammatory response resembling the APR. A systemic APR was confirmed by a two- to fivefold upregulation of the levels of hepatic gamma-FBG mRNA in animals with PCP, resulting in a corresponding increase in levels of FBG in plasma. Furthermore, immunoelectron microscopy revealed the presence of FBG at the junction of cell membranes of trophic forms of P. carinii organisms aggregated along the alveolar epithelium. These results implicate FBG in the pathogenesis of PCP in a manner similar to that of the adhesive glycoproteins fibronectin and vitronectin, which are known to participate in intra-alveolar aggregation of organisms and adherence of P. carinii to the lung epithelium.

Fibrinogen Activates NF-κB Transcription Factors in Mononuclear Phagocytes

Adhesion to extracellular matrices is known to modulate leukocyte activation, although the mechanisms are not fully understood. Mononuclear phagocytes are exposed to fibrinous provisional matrix throughout migration into inflammatory foci, so this study was undertaken to determine whether fibrinogen triggers activation of NF-κB transcription factors. U937 cells differentiated with PMA in nonadherent culture were shown to express two fibrinogen-binding integrins, predominately CD11b/CD18, and to a lesser extent, CD11c/CD18. Cells stimulated with fibrinogen (10–100 μg/ml)/Mn2+ (50 μM) for 2 h were examined by electrophoretic mobility shift assay. NF-κB activation, minimal in unstimulated cells, was substantially up-regulated by fibrinogen. Fibrinogen also caused activation of AP-1, but not SP1 or cAMP response element-binding protein (CREB) factors. Blocking mAbs against CD18 and CD11b abrogated fibrinogen-induced NF-κB activation. To determine the effects on transcriptional regulation, U937 cells were transfected with a plasmid containing the HIV-1 enhancer (bearing two NF-κB sites) coupled to a chloramphenicol acetyltransferase (CAT) reporter. Cells were subsequently stimulated with 1) PMA for 24 h, inducing CAT activity by 2.6-fold, 2) fibrinogen/Mn2+ for 2 h, inducing CAT activity by 3.2-fold, or 3) costimulation with fibrinogen and PMA, inducing 5.7-fold the CAT activity induced by PMA alone. We conclude that contact with fibrinogen-derived proteins may contribute to mononuclear phagocyte activation by signaling through CD11b/CD18, resulting in selective activation of transcriptional regulatory factors, including NF-κB.

Thrombin Cleavage-Independent Deposition of Fibrinogen in Extracellular Matrices

Lung epithelial cells (A549) synthesize and secrete fibrinogen (FBG) in vitro when stimulated with interleukin-6 and dexamethasone. This FBG secretion is polarized in the basolateral direction, suggesting that FBG is a component of the extracellular matrix (ECM). Immunofluorescent staining of A549 cells showed a fibrillar pattern of FBG, similar to the staining detected using antibodies against the matrix constituents, collagen type IV and fibronectin (FN). The same pattern of staining was detected using antibodies against fibrinopeptides A and B, as well as with the T2G1 monoclonal antibody against the fibrin-specific epitope, β15-21. Matrix staining was unaltered in the presence of the thrombin inhibitor, hirudin, or the plasmin inhibitor, aprotinin, consistent with the interpretation that matrix deposition of FBG does not require such enzymatic action. Metabolic labeling studies confirmed that FBG secreted from A549 cells or deposited into the ECM showed no evidence of thrombin or plasmin proteolytic processing or of transglutaminase-mediated covalent cross-linking (γ-γ dimers or α-polymers). Incubation of either A549 cell-derived or purified plasma FBG with cultures of human foreskin fibroblasts resulted in FBG deposition in the ECM that colocalized with matrix fibrils containing endogenously produced FN and laminin (LN). Binding of FBG to this exogenously produced matrix was unaltered by inhibition of thrombin and plasmin action, yet also exhibited exposure of the fibrin-specific epitope, β15-21. The majority (∼70%) of newly synthesized and secreted FBG is bound to the cell surface as determined by its trypsin-sensitivity. Cell surface-bound FBG is initially deoxycholate-soluble, which, over time, becomes incorporated in the deoxycholate-insoluble ECM in a similar fashion to FN. These data suggest that matrix incorporation requires the binding of secreted FBG to cell-associated matrix assembly sites. However, unlike FN, FBG in the ECM is composed of the dimeric protamer (Aα/Bβ/γγ) and not high molecular weight polymers indicative of fibrin. This study provides evidence that deposition of FBG in both endogenous and exogenously produced matrices results in conformational changes that occur independently of thrombin cleavage. This matrix-bound FBG, on which unique cell-reactive domains are likely exposed, could augment cellular response mechanisms evoked during injury and inflammation.

Thrombin Cleavage-Independent Deposition of Fibrinogen in Extracellular Matrices

Lung epithelial cells (A549) synthesize and secrete fibrinogen (FBG) in vitro when stimulated with interleukin-6 and dexamethasone. This FBG secretion is polarized in the basolateral direction, suggesting that FBG is a component of the extracellular matrix (ECM). Immunofluorescent staining of A549 cells showed a fibrillar pattern of FBG, similar to the staining detected using antibodies against the matrix constituents, collagen type IV and fibronectin (FN). The same pattern of staining was detected using antibodies against fibrinopeptides A and B, as well as with the T2G1 monoclonal antibody against the fibrin-specific epitope, β15-21. Matrix staining was unaltered in the presence of the thrombin inhibitor, hirudin, or the plasmin inhibitor, aprotinin, consistent with the interpretation that matrix deposition of FBG does not require such enzymatic action. Metabolic labeling studies confirmed that FBG secreted from A549 cells or deposited into the ECM showed no evidence of thrombin or plasmin proteolytic processing or of transglutaminase-mediated covalent cross-linking (γ-γ dimers or α-polymers). Incubation of either A549 cell-derived or purified plasma FBG with cultures of human foreskin fibroblasts resulted in FBG deposition in the ECM that colocalized with matrix fibrils containing endogenously produced FN and laminin (LN). Binding of FBG to this exogenously produced matrix was unaltered by inhibition of thrombin and plasmin action, yet also exhibited exposure of the fibrin-specific epitope, β15-21. The majority (∼70%) of newly synthesized and secreted FBG is bound to the cell surface as determined by its trypsin-sensitivity. Cell surface-bound FBG is initially deoxycholate-soluble, which, over time, becomes incorporated in the deoxycholate-insoluble ECM in a similar fashion to FN. These data suggest that matrix incorporation requires the binding of secreted FBG to cell-associated matrix assembly sites. However, unlike FN, FBG in the ECM is composed of the dimeric protamer (Aα/Bβ/γγ) and not high molecular weight polymers indicative of fibrin. This study provides evidence that deposition of FBG in both endogenous and exogenously produced matrices results in conformational changes that occur independently of thrombin cleavage. This matrix-bound FBG, on which unique cell-reactive domains are likely exposed, could augment cellular response mechanisms evoked during injury and inflammation.

Polarized secretion of fibrinogen by lung epithelial cells

The lung epithelium has recently been identified as a novel site of fibrinogen (FBG) biosynthesis. A coordinated upregulation of A alpha, B beta, and gamma chain FBG gene transcription occurs upon stimulation of A549 lung epithelial cells with dexamethasone (DEX) and the proinflammatory mediator interleukin-6 (IL-6). Subsequently, the cells synthesize and secrete fully assembled FBG. This study addresses the polarity of such FBG secretion by A549 cells cultured on polycarbonate membrane filters. After induction with IL-6 and DEX, cells were metabolically labeled, and FBG was immunopurified from the apical and basolateral chambers. Analysis by gel electrophoresis revealed that A549 cells secreted newly synthesized FBG in a polarized manner, with the majority (80%) of FBG secreted basolaterally. Consistent with this observation, immunoelectron microscopy using Protein A-gold labeling showed FBG within secretory vesicles in close proximity to the basolateral aspect of the A549 cell membrane. Polarized secretion was microtubule-dependent since depolymerization using colchicine significantly reduced the basolateral component of secretion, causing intracellular retention of FBG. These data provide evidence that FBG is secreted by lung alveolar epithelial cells vectorially toward the basement membrane, which may reflect in vivo processes associated with local injury, inflammation, and repair mechanisms.