Plasminogen Activator Inhibitor-1 Is an Inhibitor of Factor VII-activating Protease in Patients with Acute Respiratory Distress Syndrome

doi:10.1074/jbc.M610748200

Plasminogen Activator Inhibitor-1 Is an Inhibitor of Factor VII-activating Protease in Patients with Acute Respiratory Distress Syndrome^*

Malgorzata Wygrecka¹, Rory E. Morty, Philipp Markart, Sandip M. Kanse, Peter A. Andreasen^¶, Troels Wind^¶, Andreas Guenther, and Klaus T. Preissner

From the Departments of Biochemistry and Internal Medicine, Faculty of Medicine, Justus-Liebig-University Giessen, 35392 Giessen, Germany and the ^¶Department of Molecular and Structural Biology, University of Aarhus, 8000C Aarhus, Denmark

Received for publication, November 20, 2006 , and in revised form, May 22, 2007.

ABSTRACT

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Factor VII-activating protease (FSAP) is a novel plasma-derivedserine protease structurally homologous to tissue-type and urokinase-typeplasminogen activators. We demonstrate that plasminogen activatorinhibitor-1 (PAI-1), the predominant inhibitor of tissue-typeand urokinase-type plasminogen activators in plasma and tissues,is an inhibitor of FSAP as well. We detected PAI-1·FSAPcomplexes in addition to high levels of extracellular RNA, animportant FSAP cofactor, in bronchoalveolar lavage fluids frompatients with acute respiratory distress syndrome. Hydrolyticactivity of FSAP was inhibited by PAI-1 with a second-orderinhibition rate constant (K_a) of 3.38 ± 1.12 x 10⁵ M^–1·s^–1.Residue Arg³⁴⁶ was a critical recognition element on PAI-1 forinteraction with FSAP. RNA, but not DNA, fragments (>400nucleotides in length) dramatically enhanced the reactivityof PAI-1 with FSAP, and 4 µg·ml^–1 RNA increasedthe K_a to 1.61 ± 0.94 x 10⁶ M^–1·s^–1.RNA also stabilized the active conformation of PAI-1, increasingthe half-life for spontaneous conversion of active to latentPAI-1 from 48.4 ± 8 min to 114.6 ± 5 min. In contrast,little effect of DNA on PAI-1 stability was apparent. ResiduesArg⁷⁶ and Lys⁸⁰ in PAI-1 were key elements mediating bindingof nucleic acids to PAI-1. FSAP-driven inhibition of vascularsmooth muscle cell proliferation was antagonized by PAI-1, suggestingfunctional consequences for the FSAP-PAI-1 interaction. Thesedata indicate that extracellular RNA and PAI-1 can regulateFSAP activity, thereby playing a potentially important rolein hemostasis and cell functions under various pathophysiologicalconditions, such as acute respiratory distress syndrome.

INTRODUCTION

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Factor VII-activating protease (FSAP),² also known as plasmahyaluronan-binding protein or plasma hyaluronan-binding serineprotease, is a recently described plasma serine protease (1–3),expressed primarily in the liver and found in endothelial andepithelial cells of the lung, kidney, placenta, and pancreas(1, 4). The enzyme circulates as a 64-kDa single-chain zymogen(scFSAP) in plasma, which is autoactivated to an enzymaticallyactive two-chain form (tcFSAP). Two-chain FSAP consists of a46-kDa heavy chain connected by a disulfide bridge to a 29-kDalight chain containing the catalytic domain (5–7). Autoactivationof scFSAP to tcFSAP is promoted in the presence of negativelycharged substances, such as heparin, dextran sulfate, phosphatidylethanolamine,or extracellular RNA (5–8).

The role of FSAP in different physiological and pathophysiologicalconditions is not fully understood. A dual role for FSAP invitro in hemostasis has been suggested (3, 9). FSAP is a potentactivator of coagulation factor VII, thus contributing to theinitiation of blood coagulation via the extrinsic pathway (3).Furthermore, FSAP also activates prourokinase-type plasminogenactivator (uPA) and thus contributes to plasminogen activationas well (9). Additional links between FSAP and the plasminogenactivation system exist; FSAP is highly homologous to uPA andtissue-type plasminogen activator (tPA), and uPA is a potentialphysiological activator of FSAP (5). Additionally, recent invitro studies have revealed that hemostatic serine proteaseinhibitors (serpins), such as C1 inhibitor and ${alpha}$ ₂-antiplasmin,are inhibitors of FSAP proteolytic activity (7, 9). These observationsprompted us to explore the role of PAI-1, the primary memberof this inhibitor family in plasma and tissues (10, 11), asa potential regulator of FSAP. It is known that PAI-1 inhibitsuPA and tPA by forming SDS-resistant, catalytically inactivecomplexes with proteases (12, 13). In this reaction, the reactivecenter residues P₁-P₁' (Arg³⁴⁶-Met³⁴⁷) in PAI-1 function asan exposed "bait" for the protease by mimicking a putative cleavagesite (14–17). In addition to inhibiting serine proteases,PAI-1 also interacts with different components of the extracellularmatrix, including heparin (18, 19) and vitronectin (20–22).In the presence of heparin, the selectivity of PAI-1 for theinhibition of tPA and uPA is compromised, resulting in a 2-foldincreased rate of association between PAI-1 and thrombin (18).This leads to neutralization of PAI-1 due to the formation ofinactive SDS-stable PAI-1-thrombin complexes and subsequentcleavage of PAI-1 by thrombin (18). Similarly, binding of PAI-1to vitronectin broadens the specificity of the inhibitor, convertingit into a potent inhibitor of activated protein C (23) and thrombin(21). Moreover, vitronectin stabilizes PAI-1 in its active conformationalstate and mediates the binding of the inhibitor to fibrin clots(24). In complexes with vitronectin, PAI-1 serves as an antiadhesivefactor independent of its protease-inhibitory capacity (25).

In the present study, we identified PAI-1·FSAP complexesin bronchoalveolar lavage (BAL) fluids of patients with theacute respiratory distress syndrome (ARDS). Furthermore, formationof a 1:1 stoichiometric complex between PAI-1 and FSAP and dose-dependentbinding of PAI-1 to FSAP in vitro was observed. The kineticsof FSAP inhibition by PAI-1 were investigated in the absenceand presence of different cofactors (RNA, DNA, vitronectin,and heparin). The presence of extracellular RNA, but not DNA,dramatically enhanced the reactivity of PAI-1 against FSAP.RNA served as a novel stabilizer of the active conformationof PAI-1. These data are particularly relevant, since we alsodescribe elevated levels of extracellular RNA in the BAL fluidsof ARDS patients. We also demonstrate that heparin and RNA sharethe same binding sites on PAI-1. Using site-directed mutagenesis,the critical importance of Arg³⁴⁶ in PAI-1 as a mediator ofFSAP inhibition was demonstrated. Additionally, the FSAP-mediatedinhibition of vascular smooth muscle cell proliferation wassignificantly attenuated in the presence of PAI-1. These resultssuggest that PAI-1-mediated inhibition of FSAP might play animportant role in the regulation of hemostasis and vascularcell functions under a variety of physiological and pathologicalconditions, such as ARDS.

EXPERIMENTAL PROCEDURES

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Materials—The purification of FSAP from human plasma byaffinity chromatography, together with the conversion of scFSAPto tcFSAP, was performed as described previously (5, 26). Urokinase-typeplasminogen activator and ${alpha}$ ₁-proteinase inhibitor were from ZLB-Behring(Marburg, Germany). Aprotinin was from Bayer (Leverkusen, Germany).Recombinant human wild-type (WT) PAI-1 and PAI-1 variant R346Awere expressed in Escherichia coli as described previously (27).The PAI-1 WT as well as PAI-1 variants K65A, K69A, R76A, K80A,and K88A, expressed in E. coli, were a gift from Dr. H. Pannekoek(19) (University of Amsterdam, Academic Medical Center, Amsterdam,The Netherlands). Tissue-type plasminogen activator, C1 inhibitor,antithrombin, and ${alpha}$ ₂-antiplasmin were obtained from AmericanDiagnostica (Pfungstadt, Germany). Vitronectin was preparedfrom human plasma as described previously (20). Heparin waspurchased from Ratiopharm (Ulm, Germany). The extraction ofRNA from HepG2 cells was performed using QIAzol^TM lysis reagent(Qiagen, Hilden, Germany) according to the manufacturer's instructions.Genomic DNA was isolated from HepG2 cells using Genomic DNAKit (Qiagen) following the manufacturer's instructions. Forvisual detection, isolated nucleic acids were subjected to electrophoresison a 1% agarose gel followed by ethidium bromide staining. Theconcentrations of nucleic acids were determined using a GeneQuant photometer (Amersham Biosciences, Freiburg, Germany).

Bronchoalveolar Lavage—BAL fluids were obtained by flexiblefiberoptic bronchoscopy from spontaneously breathing healthyvolunteers without any history of cardiac or lung disease andwith normal pulmonary function (n = 8) and from mechanicallyventilated patients with early ARDS (<120 h after onset ofthe disease; n = 8) as recently described (28). Diagnosis ofARDS was made on the basis of the ARDS American-European consensuscriteria (29). Written informed consent was obtained from eitherthe patients or their next-of-kin.

Determination of RNA and DNA Concentration in BAL Fluid—RNAand DNA were extracted from BAL fluid using QIAzol^TM lysis reagentand QIAamp® DNA minikit, respectively (both from Qiagen).The RNA concentration was measured using one-step real timequantitative reverse transcription-PCR for GAPDH. The amplificationprimers were GAPDH-F (5'-CCA CAT CGC TCA GAC ACC AT-3') andGAPDH-R (5'-GGC AAC AAT ATC CAC TTT ACC AGA G-3') and a dual-labeledfluorescent probe was GAPDH-P (5'-AAG GTC GGA GTC AAC GGA TTTGGT CG-3'). The reverse transcription-PCRs were set up withthe GeneAmp EZ rTth RNA PCR kit (PE Applied Biosystems, FosterCity, CA) according to the manufacturer's protocol using 5 µlof extracted RNA. The DNA concentration was assessed using realtime quantitative PCR for $beta$ -globin. The amplification primerswere $beta$ -globin-F (5'-GTG CAC CTG ACT CCT GAG GAG-3') and $beta$ -globin-R(5'-CCT TGA TAC CAA CCT GCC CAG-3'), and a dual-labeled fluorescentprobe was $beta$ -globin-P (5'-AAG GTG AAC GTG GAT GAA GTT GGT GG-3').The PCRs were set up with a Quan-i Tect probe PCR kit (Qiagen)according to the manufacturer's protocol using 5 µl ofextracted DNA. Amplification data were collected and analyzedwith an ABI Prism 7700 Sequence Detector (PE Applied Biosystems).Each sample was analyzed in triplicate, and multiple negativewater blanks were included in each analysis. A calibration curvewas prepared using serial dilutions of a commercially availablehuman control RNA or human control DNA (both from PE AppliedBiosystems).

The presence of nucleic acids in BAL fluids from ARDS patientsand healthy controls was also assessed by a filter-binding assay,where a nylon membrane was soaked with buffer A (10 mM Tris-Cl(pH 7.5), 50 mM NaCl, 1 mM EDTA, and 1x Denhardt's solution(0.02% (m/v) Ficoll, 0.02% (m/v) polyvinylpyrrolidone, and 0.02%(m/v) BSA)) and fixed into a slot-blot apparatus. The RNA andDNA extracted from the BAL fluid from eight ARDS patients andfrom eight healthy volunteers was biotinylated and then appliedto the filter in 100 µl of TBS for 10 min, aspirated throughthe filter, and cross-linked for 10 min by exposure to ultravioletlight (254 nm). After washing with buffer A, the membrane wasincubated with peroxidase-labeled streptavidin (DAKO, Glostrup,Denmark), and detection of RNA and DNA was performed using enhancedchemiluminescence (Pierce). Biotinylation of RNA and DNA wasperformed with EZ-Link^TM Psoralen-PEO-biotin from Pierce accordingto the manufacturer's instructions.

Western Blotting Analysis of BAL Fluids from ARDS Patients—Bronchoalveolarlavage fluids (25 µl) were combined with nonreducing samplebuffer containing 6 M guanidine hydrochloride, and after SDS-PAGEon 10% gels, proteins were transferred to a polyvinylidene difluoridemembrane. After blocking with 5% (m/v) nonfat milk in Tris-bufferedsaline (25 mM Tris-Cl, 150 mM NaCl, pH 7.5) containing 0.1%(v/v) Tween 20 (TBS-T), the membrane was incubated at 4 °Covernight with a rabbit antibody raised against FSAP (AventisBehring, Marburg, Germany), followed by incubation with horseradishperoxidase-labeled secondary antibody (DAKO). Immune complexeswere detected using enhanced chemiluminescence (Pierce). Fordetection of PAI-1, the membrane was stripped using strippingbuffer (2% (m/v) SDS, 100 mM $beta$ -mercaptoethanol in TBS) and reprobedwith a rabbit anti-PAI-1 antibody (Santa Cruz Biotechnology,Inc., Santa Cruz, CA).

Co-immunoprecipitation Experiments—Prior to co-immunoprecipitation,albumin was removed from BAL fluid samples using a ProteoSeek^TMantibody-based albumin/IgG removal kit from Pierce accordingto the manufacturer's instructions. Bronchoalveolar lavage fluid(100 µl) was incubated at 4 °C overnight with 5 µgof murine monoclonal anti-FSAP antibody or IgG as an isotypecontrol. Samples were transferred to tubes containing 50 µlof protein A-Sepharose^TM CL-4B beads (Amersham Biosciences).After a 2-h incubation at room temperature, the immunoprecipitateswere washed five times (50 mM Tris-Cl, pH 7.5, 150 mM NaCl,1% (v/v) Triton X-100), boiled in 40 µl of SDS samplebuffer, separated by SDS-PAGE (10% gels) under reducing conditions,and transferred to a polyvinylidene difluoride membrane. Themembrane was blocked with 5% (m/v) nonfat dry milk in TBS-Tand then incubated at 4 °C overnight with rabbit antibodiesdirected against FSAP, PAI-1 (Santa Cruz Biotechnology), ${alpha}$ ₁-proteinaseinhibitor (Aventis Behring), C1 inhibitor, ${alpha}$ ₂-antiplasmin, andantithrombin, respectively (all obtained from DAKO). After incubationwith peroxidase-labeled secondary antibody, proteins were detectedby enhanced chemiluminescence.

Inhibition of FSAP by C1 Inhibitor, ${alpha}$ ₁-Proteinase Inhibitor,Antithrombin III, ${alpha}$ ₂-Antiplasmin, and PAI-1—Fourteen nM(by mass) tcFSAP was added to C1 inhibitor (50 nM), ${alpha}$ ₁-proteinaseinhibitor (50 µM), antithrombin (50 µM), ${alpha}$ ₂-antiplasmin(100 nM), and PAI-1 (50 nM) in TBS, pH 7.4, in a total volumeof 100 µl. After a 5-min incubation at 37 °C, 10 µlof 3 mM chromogenic substrate S-2288 (H-D-isoleucyl-L-prolyl-L-arginyl-para-nitroanilidedihydrochloride; Chromogenix, Mölndal, Sweden) was added,and the hydrolysis of S-2288 by FSAP was measured spectrophotometricallyat 405 nm in an EL 808 microtiter plate reader (BioTek Instruments,Highland Park, VT).

Complex Formation between FSAP and C1 Inhibitor, ${alpha}$ ₁-ProteinaseInhibitor, Antithrombin III, ${alpha}$ ₂-Antiplasmin, and PAI-1—Two-chainFSAP (1 µg) was combined with C1 inhibitor (2 µg), ${alpha}$ ₁-proteinase inhibitor (3 µg), antithrombin (2 µg), ${alpha}$ ₂-antiplasmin (2 µg), or PAI-1 (4 µg) in TBS, pH7.4, in a total volume of 100 µl and incubated at roomtemperature for 30 min. Subsequently, nonreducing sample bufferwas added, and the samples were subjected to 10% SDS-PAGE. Theproteins were stained with Coomassie Brilliant Blue R-250.

Titration of Wild-type PAI-1 and PAI-1 R346A—Increasingamounts of wild-type PAI-1 and PAI-1 R346A were incubated at37 °C for 30 min in a total volume of 100 µl with3 nM tPA (active concentration) in TBS buffer. Chromogenic substrate(10 µl of a 3 mM S-2288 solution) was added, and residualtPA activity was determined from a linear plot of the increaseof absorbance at 405 nm over time.

Analysis of PAI-1 Binding to FSAP—A microtiter plate wascoated with 50 µl of 140 nM tcFSAP or scFSAP in 50 mMNaHCO₃, pH 9.6, at 4 °C overnight. The plate was washedthree times with TBS-T buffer, and nonspecific binding siteswere blocked with 3% (m/v) BSA in TBS-T at room temperaturefor 1 h. Increasing concentrations (0–20 nM) of PAI-1in TBS-T containing 0.3% (m/v) BSA alone or in the presenceof 2 µg·ml^–1 rabbit antibody against FSAPwere added to the wells, and PAI-1 was allowed to bind to FSAPat room temperature for 2 h. After extensive washing with TBS-T,bound PAI-1 was detected using a rabbit polyclonal antibodyagainst PAI-1 followed by peroxidase-labeled secondary antibody.Final detection was performed using 3,3',5,5'-tetramethylbenzidine(TMB), with a TMB substrate kit (Pierce) according to the manufacturer'sinstructions. Binding of PAI-1 to BSA-coated wells was employedas a background control, against which values were normalized.The uPA-PAI-1 complexes were generated by incubation of equimolarquantities of two-chain uPA and active PAI-1 at room temperaturefor 30 min and subsequently purified by Superdex 200 gel filtrationchromatography (Amersham Biosciences).

Complex Formation between FSAP and PAI-1—Twenty ng oftcFSAP or scFSAP were incubated with increasing amounts of PAI-1(0–80 ng) at room temperature for 30 min. Samples weremixed with either nonreducing or reducing sample buffer, andafter SDS-polyacrylamide gel electrophoresis on 10% polyacrylamidegels, proteins were transferred to a polyvinylidene difluoridemembrane. Detection of proteins was performed with a rabbitpolyclonal antibody directed against FSAP or with murine monoclonalantibodies directed against heavy and light chain FSAP, respectively.Subsequently, the membranes were stripped and reprobed witha rabbit anti-PAI-1 antibody.

NH₂-terminal Sequencing—The amino-terminal sequence ofpeptides contained in the PAI-1·FSAP complex was determinedby automated Edman degradation using an Applied Biosystems 492pulsed liquid phase sequencer equipped with an on-line 785Aphenylthiohydantoin derivative analyzer. Ten cycles of Edmandegradation were performed, and the amino acids detected ateach cycle were aligned with the FSAP sequence (GenBank®accession number NP_004123 [GenBank] ).

Enzymatic Analysis of FSAP Inhibition by PAI-1—Reactionsamples contained 14 nM (by mass) tcFSAP, increasing concentrationsof PAI-1 (0–24 nM; by active site titration against tPA)and 0.3 mM of the chromogenic substrate S-2288 in 100 µlofTBS, pH 7.4. The hydrolysis of S-2288 by FSAP was measured spectrophotometricallyat 405 nm every 30 s at 37 °C for 30 min in an EL 808 microtiterplate reader.

To investigate the influence of vitronectin, heparin, RNA, orDNA on the PAI-1-mediated inhibition of FSAP amidolytic activity,14 nM (by mass) tcFSAP or scFSAP was mixed with 10 nM PAI-1(by active site titration against tPA) and increasing concentrationsof vitronectin (0–40 nM), heparin (0–24 nM), RNA(0–4 µg·ml^–1), or DNA (0–4 µg·ml^–1).Hydrolysis of S-2288 (0.3 mM) was measured spectrophotometricallyas described above.

The second-order inhibition rate constant K_a was determinedusing a continuous progress curve method essentially as describedby Futamura and Gettins (30). The change in absorbance resultingfrom hydrolysis of 1.5 mM S-2288 by FSAP (8 nM, by mass) inthe presence of PAI-1 (0–200 nM, by active site titrationagainst tPA) was monitored at 405 nm. A pseudo-first order inhibitionrate constant, k_obs, was determined by fitting data to a monoexponentialequation [P]_t = [P](1 – e^k^obs·^t), where [P]_t and[P] are the product concentrations at time t and infinite time,respectively, proportional to the recorded A₄₀₅ values. TheK_a was then calculated from the equation, correcting for thepresence of competing substrate, by k = k_obs(1 + [S-2288]₀/K_m)/[PAI-1]₀,where [S-2288]₀ is the concentration of S-2288 at time 0, and[PAI-1]₀ is the PAI-1 concentration at time 0. Under the conditionsused, the K_m was determined to be 70.4 ± 4.4 µM(n = 5).

Inhibition of FSAP by PAI-1 R346A—Two-chain FSAP (14 nM)was incubated with wild-type PAI-1 or PAI-1 R346A (24 nM activePAI-1, titrated against tPA) in a total volume of 100 µlofTBS buffer. After 30 min at 37 °C, 10 µl of 0.3 mMS-2288 was added, and FSAP activity was determined from thelinear increase of absorbance at 405 nm. The increase of absorbancemeasured for the sample containing FSAP alone was taken as 100%.

Binding of RNA and DNA to PAI-1—For fragmentation of nucleicacids, 1 mg of biotinylated RNA or DNA was dissolved in 1 mlof RNase-, DNase-free water and sonicated for 2, 4, 6, 8, 10,or 12 s. At the indicated time points, 100-µl sampleswere withdrawn, and nucleic acids were precipitated with ethanol.The RNA and DNA were dissolved in RNase-, DNase-free water andtested for PAI-1-binding capacity (see below). Parallel sampleswere subjected to agarose gel electrophoresis and visualizedby ethidium bromide staining.

The wells of a microtiter plate were coated at 4 °C overnightwith wild-type PAI-1 at 200 nM (by mass) in 50 mM NaHCO₃, pH9.6. Nonspecific binding sites were blocked by incubation with3% (m/v) BSA in TBS at room temperature for 1 h. Binding assayswere performed by adding increasing concentrations of biotinylatedRNA (0–25 µg·ml^–1 in TBS) or DNA (0–5µg·ml^–1 in TBS) to immobilized wild-typePAI-1. After a 2-h incubation at room temperature, the platewas extensively washed with TBS, and bound nucleic acids weredetected using peroxidase-labeled streptavidin. Final detectionwas performed with a TMB substrate kit from Pierce. The bindingof nucleic acids to BSA-coated wells was employed as a blankin all experiments and was subtracted from experimental valuesto obtain specific binding. Binding of biotinylated RNA or DNAto PAI-1 in the presence of 1 mM heparin, a 100-fold excessof unlabeled RNA or DNA, or 10 mM tranexamic acid (Sigma) servedas controls. To determine the RNA and DNA binding sites on PAI-1,the wells of a microtiter plate were coated at 4 °C overnightwith PAI-1 variants K65A, K69A, R76A, K80A, and K88A all at200 nM (by mass) in 50 mM NaHCO₃, pH 9.6. After blocking with3% (m/v) BSA in TBS, 10 µg·ml^–1 of biotinylatedRNA or 3 µg·ml^–1 of DNA were added, and theplate was incubated at room temperature for 2 h. Final detectionof PAI-1-bound RNA or DNA was performed as described above.Since PAI-1 is partially denatured by adsorption to plasticat 4 °C overnight, data obtained in the microplate assayreflect nucleic acid binding to denatured PAI-1. To assess nucleicacid binding to active PAI-1, a filter-binding assay was performed,where nitrocellulose membranes were soaked with buffer A (seeabove) and fixed into a slot-blot apparatus. Increasing concentrations(0–6 µg·ml^–1) of either wild-type PAI-1or PAI-1 variants (R76A and K80A) were mixed with 10 µg·ml^–1of RNA or 3 µg·ml^–1 of DNA, incubated onthe filters in 100 µl of TBS for 15 min, and then aspiratedthrough the filters. After extensive washing with buffer A,the membrane was incubated with peroxidase-labeled streptavidin,and PAI-1-nucleic acid complexes were detected by enhanced chemiluminescence(Pierce).

Assessment of PAI-1 Activity—Samples of PAI-1 (24 nM,by active site titration against tPA) dissolved in TBS, pH 7.4,were incubated at 37 °C for 1–5 h in the absence orpresence of either vitronectin (70 nM), RNA (4 µg·ml^–1),or DNA (4 µg·ml^–1). Inhibition of uPA byPAI-1 was measured with the peptide-derived chromogenic substrateS-2444 (L-pyroglutamyl-L-glycyl-L-argininyl-para-nitroanilide;Chromogenix) at various time points. A ratio was determinedfor the residual PAI-1 activity at time t (v_t) versus the initial,uninhibited activity (v₀). Linear regression of a semilog plotof ln(v_t/v₀) versus time yielded a graph with a slope = k, wherek is the rate of disappearance of active PAI-1. The half-lifefor inactivation of PAI-1, t_(inact), is given by t_(inact) = ${ell}$ n2/k.

Cell Proliferation Assay—Proliferation of mouse vascularsmooth muscle cells (VSMC) in the presence of different testreagents (FSAP (12 µg·ml^–1), PDGF-BB (20ng·ml^–1), PAI-1 (60 µg·ml^–1))or combinations thereof was determined by DNA synthesis assaysbased on the uptake of bromodeoxyuridine as previously described(26).

Statistics—Data are presented as mean ± S.D. Thestatistical analyses were performed with SPSS version 9.0.1(SPSS Inc., Chicago, IL). Differences between two groups weretested with Student's t test.

RESULTS

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Complex Formation between FSAP and PAI-1 and RNA Levels in ARDSBAL Fluids—Dysregulated proteolysis is an emerging areaof interest in the pathogenesis and management of acute lunginjury (31–33). During the course of a broad screen ofproteolytic enzymes in patients with ARDS, we detected significantlyincreased levels of FSAP protein and FSAP activity in BAL fluidsof these patients. Remarkably, almost no FSAP was detectablein BAL fluids from healthy patients (data not shown). Upon electrophoreticanalysis and Western blotting, BAL fluids from ARDS patientsexhibited a high molecular mass band of 120 kDa, together withan expected band of 64 kDa, when probed with anti-FSAP antibodies(Fig. 1A). These data suggested the presence of high molecularmass complexes of FSAP with other proteins in the BAL fluidsof ARDS patients. Most likely, these complexes consisted ofFSAP bound to a cognate inhibitor also present in the lung.Therefore, to identify potential interaction partners of FSAP,co-immunoprecipitation studies of the BAL fluids with a murinemonoclonal antibody against FSAP, as well as antibodies directedagainst a spectrum of serine protease inhibitors, were performed.As is evident from Fig. 2A, PAI-1 co-immunoprecipitated withFSAP, whereas C1 inhibitor, ${alpha}$ ₁-proteinase inhibitor, antithrombin,and ${alpha}$ ₂-antiplasmin did not. Interestingly, PAI-1·FSAPcomplexes precipitated as a 70 kDa band. To examine whether70 kDa bands represent PAI-1·FSAP complexes, the blotswere stripped and reprobed with FSAP-specific and PAI-1-specificantibodies, respectively. The 70 kDa band was detected by bothof these antibodies, indicating PAI-1·FSAP complex formationin the BAL fluids from ARDS patients (data not shown). We werenot able to co-immunoprecipitate C1 inhibitor with FSAP fromBAL fluids from ARDS patients, although C1 inhibitor is knownto be a strong inhibitor of FSAP in plasma (7, 9). It may wellbe that such complexes do exist and simply could not be detectedbecause the complex formation masks an essential epitope andprevents recognition by the antibodies employed. Alternatively,C1 inhibitor may not be a relevant FSAP inhibitor in the BALfluids (contrasting with the important role of C1 in the plasmawith respect to FSAP inhibition). Indeed, we did observe formationof SDS-stable complexes between FSAP and PAI-1, and also betweenFSAP and C1 inhibitor and between FASP and ${alpha}$ ₂-antiplasmin, ina purified system, utilizing nonreducing SDS-PAGE followed byCoomassie staining (Fig. 2B). In contrast, no complex formationbetween FSAP and ${alpha}$ ₁-proteinase inhibitor or between FSAP andantithrombin was noted (Fig. 2B), despite the fact that ${alpha}$ ₁-proteinaseinhibitor levels are dramatically elevated in lavage fluidsfrom ARDS patients (34). To further validate these complex formationdata, we assessed the inhibition of FSAP catalytic activityby these five protease inhibitors. The amidolytic activity ofFSAP was potently inhibited by PAI-1, C1 inhibitor, and ${alpha}$ ₂-antiplasmin,although ${alpha}$ ₁-proteinase inhibitor and antithrombin were largelywithout effect (Fig. 2C). These trends parallel the trends observedin the in vitro FSAP-serpin complex formation assays (Fig. 2B).Together, our data suggest that FSAP and PAI-1 form a 1:1 stoichiometriccomplex in the lavage fluids of ARDS patients. This was theonly FSAP-serpin complex that we were able to detect in thelavage fluid of ARDS patients, although other serpins were ableto inhibit and form complexes with FSAP when assessed in purifiedsystems in vitro. For this reason, we elected to further explorethe interaction of FSAP with PAI-1 in the context of ARDS.

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FIGURE 1.
FSAP·PAI-1 complexes and extracellular RNA are present in the BAL fluids of ARDS patients. A, BAL fluids from seven ARDS patients were subjected to SDS-PAGE under nonreducing conditions after treatment with 6 M guanidine hydrochloride, and FSAP or PAI-1 was detected on Western blots using an anti-FSAP antibody (left) or anti-PAI-1 antibody (right). Seven representative patients of 12 are illustrated. B, the nucleic acid levels in BAL fluids of ARDS patients and healthy controls were determined by filter-binding assay, where nucleic acids were extracted from BAL fluids from ARDS patients and healthy controls (n = 8 per group), biotinylated, and incubated on nitrocellulose filters. Bound nucleic acids were detected using peroxidase-labeled streptavidin and enhanced chemiluminescence. C, the nucleic acid levels in BAL fluids were also assessed by real time quantitative reverse transcription-PCR for GAPDH (RNA) and for $beta$ -globin (DNA). *, p = 0.005 (ARDS versus healthy controls).

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FIGURE 2.
FSAP co-immunoprecipitates with PAI-1 in the BAL fluids of ARDS patients. A, immunoprecipitation (IP) was performed from BAL fluids (100 µl) using a mouse anti-FSAP or mouse anti-PAI-1 antibody, followed by Western blot (WB) analysis of the immunoprecipitate with antibodies directed against different serine protease inhibitors or FSAP, as indicated. Each reference protein is indicated in lane 1 of each blot. B, two-chain FSAP (1 µg) was incubated with C1 inhibitor (C1 INH), ${alpha}$ ₁-proteinase inhibitor ( ${alpha}$ ₁PI), antithrombin (AT), ${alpha}$ ₂-antiplasmin ( ${alpha}$ ₂AP), and PAI-1 (2–4 µg each) for 30 min. The samples were run on a 10% polyacrylamide gel under nonreducing conditions and stained with Coomassie Blue R-250. Arrowheads, FSAP-inhibitor complexes. C, two-chain FSAP (14 nM) was incubated with C1 INH (50 nM), ${alpha}$ ₁PI (50 µM), AT (50 µM), ${alpha}$ ₂AP (100 nM), and PAI-1 (50 nM) for 5 min. Remaining FSAP activity was measured with the conversion of the chromogenic substrate S-2288 at 405 nm. FSAP activity is depicted as percentage of control (100% – activity of FSAP in the absence of an inhibitor). Data represent the mean ± S.D. (n = 5). ***, p = 0.0004; **, p = 0.002 versus FSAP in the absence of an inhibitor.

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FIGURE 3.
PAI-1 forms SDS-stable complexes with two-chain FSAP. Complexes between PAI-1 (applied at different concentrations) and tcFSAP, were formed for 30 min, and samples were analyzed by SDS-PAGE under nonreducing (A) and reducing (B) conditions, followed by Western blot analysis with a rabbit antibody directed against FSAP (top) and a rabbit antibody directed against PAI-1 (bottom). C, the tcFSAP (14 nM) was incubated with 50 nM PAI-1 for 30 min. After gel electrophoresis under reducing conditions, proteins were transferred to a polyvinylidene difluoride membrane, and complexes were immunodetected with anti-heavy- and light-chain FSAP-specific monoclonal antibodies (top panel) and a PAI-1-specific polyclonal antibody (bottom). D, schematic structure of human FSAP. The 10 NH₂-terminal residues of the light chain of FSAP are indicated. E, binding of PAI-1 in the absence ( ${blacksquare}$ ) or presence (•) of a rabbit anti-FSAP antibody or of preformed PAI-1-uPA complexes ( ${blacktriangleup}$ ) to immobilized tcFSAP was performed in microtiter plates, and bound PAI-1 was quantified with a rabbit polyclonal antibody directed against PAI-1. Data represent the mean ± S.D. (n = 5) of a single representative experiment of three separate experiments. hcFSAP, heavy chain FSAP; lcFSAP, light chain FSAP, E1, E2, and E3, EGF-like domain 1, 2, and 3, respectively.

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FIGURE 4.
PAI-1 does not form complexes with single-chain FSAP. A, complexes between PAI-1 (applied at different concentrations) and scFSAP were formed for 30 min, and samples were analyzed by SDS-PAGE under nonreducing conditions, followed by Western blot analysis with a FSAP-specific antibody (top) and a PAI-1-specific antibody (bottom). B, binding of PAI-1 in the absence ( ${blacksquare}$ ) or presence (•) of a rabbit anti-FSAP antibody or of preformed PAI-1-uPA complexes ( ${blacktriangleup}$ ) to immobilized scFSAP was performed in microtiter plates, and bound PAI-1 was quantified with a rabbit polyclonal antibody directed against PAI-1. Inset, autoconversion of scFSAP to tcFSAP (indicated by the appearance of the FSAP heavy chain (hcFSAP)) after a 16-h incubation at 4 °C. Data represent the mean ± S.D. (n = 5) of a single representative experiment of three independent experiments.

We have previously demonstrated that extracellular RNA but notDNA is an important cofactor that mediates the autoactivationof scFSAP to tcFSAP (8). For this reason, we also screened theBAL fluids from ARDS patients for extracellular nucleic acids.Significantly elevated levels of RNA were found in BAL fluidsfrom ARDS patients, as assessed by a filter-binding assay (Fig. 1B).Real time quantitative reverse transcription-PCR analysis alsodemonstrated a significant increase in GAPDH RNA levels in theseARDS BAL fluids in comparison with those from healthy volunteers(Fig. 1C). While the levels of DNA in the BAL fluids from ARDSpatients exhibited trends toward an increase, the increase didnot achieve statistical significance (Fig. 1C).

Complex Formation and Binding between Purified PAI-1 and FSAP—Complexformation between FSAP and PAI-1 was assessed by incubationof both two-chain (Fig. 3) and single-chain (Fig. 4) forms ofFSAP with increasing amounts of PAI-1 for 30 min, followed byWestern blot analysis with anti-FSAP and anti-PAI-1 antibodies.No complex formation between PAI-1 and scFSAP was observed (Fig. 4A).However, PAI-1 formed complexes with tcFSAP, detectable as a120 kDa band after separation by SDS-PAGE under nonreducingconditions (Fig. 3A). Interestingly, under reducing conditions,formation of a 70-kDa complex between PAI-1 and tcFSAP occurred(Fig. 3B). To identify the components of the 70 kDa band, Westernblots with FSAP heavy chain- and light chain-specific antibodieswere performed. The 70-kDa band was detected by the FSAP lightchain-specific antibody and by PAI-1-specific antibody but notby the antibody directed against heavy chain of FSAP (Fig. 3C).In line with this observation, the 70 kDa band was analyzedby amino-terminal sequencing, and this led to the identificationof two separate NH₂ termini in the band: IYGGFKSTAG (the NH₂terminus of light chain FSAP (Fig. 3D)) and the other from PAI-1.In contrast, no complex formation between PAI-1 and the FSAPheavy chain was observed (Fig. 3C).

Binding experiments conducted in microtiter plates employingisolated PAI-1 and FSAP revealed a dose-dependent and saturableinteraction between PAI-1 and tcFSAP (Fig. 3E). Binding of PAI-1to tcFSAP was almost completely abrogated by a polyclonal anti-FSAPantibody or when PAI-1 was complexed to uPA prior to combinationwith FSAP (Fig. 3E). Likewise, PAI-1 binding to scFSAP was noted,yet to a lesser degree (Fig. 4B), which would be expected, sincescFSAP is largely proteolytically inactive and therefore effectivelyunable to interact with protease inhibitors. Indeed, the apparentbinding of PAI-1 to scFSAP that was observed probably reflectsthe binding of PAI-1 to tcFSAP, since small amounts of tcFSAPwere generated by autoactivation of scFSAP over the course ofthe binding reaction at 4 °C (Fig. 4B, inset).

Inhibition of FSAP Amidolytic Activity by Wild-type PAI-1 anda PAI-1 R346A Variant—To characterize the inhibitory capacityof PAI-1 against FSAP amidolytic activity, tcFSAP was incubatedwith increasing amounts of active and inactivated wild-typePAI-1. Active PAI-1 inhibited the serine protease activity oftcFSAP in a dose-dependent manner (Fig. 5A). The second-orderinhibition rate constant (K_a) for the FSAP inhibition by PAI-1was calculated as 3.38 ± 1.12 x 10⁵ M^–1·s^–1(Table 1).

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TABLE 1
Inhibition of tcFSAP activity by PAI-1 in the presence of modulators

FSAP preferentially attacks substrates with an Arg or Lys residueat P₁ (35). Analysis of PAI-1 mutants has previously demonstratedthat a basic residue (Arg or Lys) at P₁ is required for theinhibitory activity of PAI-1 toward uPA (36). A PAI-1 R346Avariant exhibited a 20-fold reduced inhibitory capacity againstFSAP, compared with wild-type PAI-1 (Fig. 5A, inset), indicatingthat a basic residue at P₁ in the reactive center of PAI-1 wasrequired for FSAP inhibition as well.

Influence of Cofactors on FSAP Inhibition by PAI-1—Wedemonstrate in this study not only that FSAP·PAI-1 complexesare the principal FSAP-serpin complexes formed in the BAL fluidsof ARDS patients but also that large amounts of extracellularRNA, but not DNA, are present in these BAL fluids. Other reportshave demonstrated that double-stranded nucleic acids preventthe inhibition of serine proteinases (such as cathepsin G) bytheir cognate serpins, including ${alpha}$ ₁-proteinase inhibitor and ${alpha}$ ₁-antichymotrypsin (37, 38). Therefore, we felt it relevantto explore whether the presence of large amounts of extracellularRNA impacted the FSAP-PAI-1 interaction.

The presence of RNA significantly increased the ability of PAI-1to inhibit tcFSAP (Fig. 5B). A similar trend was observed forDNA; however, DNA was significantly less potent than was RNA(Fig. 5C). The inhibition of tcFSAP by PAI-1 exhibited a lineardose dependence on RNA and DNA concentration over the nucleicacid concentration range 1–4 µg·ml^–1when assessed under second-order conditions (Fig. 5, B (inset)and C (inset)).

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FIGURE 5.
Inhibition of FSAP hydrolytic activity by PAI-1. A, two-chain FSAP (14 nM, by mass) was incubated in the absence (•) or in the presence of active wild-type PAI-1 at a concentration of 10 nM ( ${blacktriangledown}$ ), 14 nM ( ${triangledown}$ ), 19 nM ( ${blacksquare}$ ), or 24 nM ( ${square}$ ) or in the presence of 19 nM heat-inactivated PAI-1 ( ${circ}$ ) in 100 µl of TBS buffer. Amidolytic activity was followed as the conversion of the chromogenic substrate S-2288 at 405 nm. A single representative experiment of seven is illustrated. Amidolytic activity of tcFSAP (14 nM, by mass) against S-2288 was evaluated after a 30-min preincubation with WT PAI-1, or PAI-1 R346A (both at 24 nM, by mass) as described above (inset). Data represent mean ± S.D. (n = 7). *, p < 0.001 between PAI-1 WT- and R346A-treated tcFSAP. The effect of RNA (B) or DNA (C) on the inhibition of tcFSAP by PAI-1 was also assessed. In both instances, the linear dependence of PAI-1 inhibitory capacity on RNA and DNA concentration was assessed by a semilog plot of residual enzyme activity versus RNA or DNA concentration (insets). The correlation coefficient, r², is indicated in the insets. Data represent mean ± S.D. (n = 7). B, *, p < 0.001 versus PAI-1 in the absence of nucleic acids.

The second-order inhibition rate constant (K_a) for the inhibitionof tcFSAP by PAI-1 was increased from 3.38 ± 1.12 x 10⁵to 1.61 ± 0.94 x 10⁶ M^–1·s^–1 in thepresence of RNA (4 µg·ml^–1) and to 6.23 ±1.17 x 10⁵ M^–1·s^–1 in the presence of DNA(4 µg·ml^–1) (Table 1). The PAI-1-mediatedinhibition of FSAP amidolytic activity was also enhanced byvitronectin (where the K_a was increased to 5.58 ± 1.02x 10⁵ M^–1·s^–1) and thus to a lesser extentthan that observed for RNA (Table 1). Heparin also has a cofactorfunction for the autoactivation of scFSAP to tcFSAP but, incontrast to RNA and vitronectin, did not significantly influencePAI-1-mediated inhibition of FSAP proteolytic activity (Table 1).

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FIGURE 6.
PAI-1 binds nucleic acids. Increasing amounts of biotinylated RNA (0–12.5 µg·ml^–1)(A) or DNA (0–5 µg·ml^–1)(B) were added to wells of a microtiter plate coated with wild type PAI-1 (200 nM) in the absence ( ${blacksquare}$ ) or presence of 10 mM tranexamic acid ( ${diamondsuit}$ ), 1 mM heparin ( ${blacktriangleup}$ ), or a 100-fold excess of unlabeled RNA (•) or DNA (•), respectively. Bound nucleic acids were detected using peroxidase-labeled streptavidin and TMB as the substrate. Data represent mean ± S.D. (n = 7) of a typical experiment of three. C, biotinylated RNA (10 µg·ml^–1; black bars) or DNA (5 µg·ml^–1; open bars) was added to wells of a microtiter plate coated with either WT PAI-1 or PAI-1 variant K65A, K69A, R76A, K80A, or K88A (200 nM) and incubated for 2 h at room temperature. Bound nucleic acids were detected using peroxidase-labeled streptavidin and TMB as the substrate and are depicted as percentage of control. Controls represent amounts of RNA or DNA bound to wild type PAI-1, set at 100%. Data represent mean ± S.D. (n = 7) of a typical experiment of three. *, p < 0.001; **, p < 0.0001; ***, p < 0.00001 versus wild type PAI-1. D, filter-binding assays with increasing amounts (0–6 µg·ml^–1) of either WT PAI-1 or PAI-1 variant R76A or K80A and 10 µg·ml^–1 of biotinylated RNA were performed. E, filter-binding assay with increasing amounts (0–6 µg·ml^–1) of either WT PAI-1 or PAI-1 variant K80A and 3 µg·ml^–1 of biotinylated DNA was performed.

Interaction of PAI-1 with RNA and DNA—Solid-phase bindingassays revealed a dose-dependent and saturable interaction betweenPAI-1 and RNA (Fig. 6A) and between PAI-1 and DNA (Fig. 6B).Binding of biotinylated RNA or DNA to PAI-1 was almost completelyabrogated by the lysine analog tranexamic acid or when unlabeledRNA or DNA was added in a 100-fold molar excess. Additionally,RNA, as well as DNA, did not bind to PAI-1 in the presence of1 mM heparin, suggesting that the binding sites on PAI-1 fornucleic acids and heparin may be the same or are located inclose proximity to each other. The major determinants for interactionof PAI-1 with heparin are the amino acid residues Lys⁶⁵, Lys⁶⁹,Arg⁷⁶, Lys⁸⁰, and Lys⁸⁸ located in and around helix D of PAI-1(19). Therefore, PAI-1 variants (K65A, K69A, R76A, K80A, andK88A) were subsequently evaluated for nucleic acid-binding capacityin a solid-phase (microtiter plate-based) binding assay. A significantreduction in the RNA-binding capacity of PAI-1 variants K69A,R76A, and K80A was observed when compared with wild-type PAI-1(Fig. 6C). The most dramatic reduction in binding capacity wasobserved for variants R76A and K80A, suggesting a particularlycritical role in RNA binding for the amino acid residues Arg⁷⁶and Lys⁸⁰ (Fig. 6C). Since PAI-1 is partially denatured by adsorptionto plastic at 4 °C overnight, data obtained in the microplateassay reflect nucleic acid binding to denatured PAI-1. To assessnucleic acid binding to active PAI-1, a filter-binding assaywas performed, where essentially the same trends were observed.In a slot-blot filter-binding assay, although the R76A PAI-1variant retained weak RNA binding activity, no RNA binding wasobserved for the K80A variant (Fig. 6D). Similarly, DNA interactionwith PAI-1 was dependent upon amino acid residue Arg⁷⁶ and wasalmost completely abrogated when residue Lys⁸⁰ was replacedby alanine (Fig. 6C). In a slot-blot filter-binding assay, almostnegligible binding of DNA to the K80A PAI-1 variant was noted(Fig. 6E). The ability of PAI-1 to bind nucleic acids was alsodependent upon the size of the RNA and DNA fragments. Shearingof RNA and DNA fragments by sonication (Fig. 7A) led to a gradualloss of RNA and DNA binding by PAI-1 (Fig. 7B). This was particularlyevident when RNA or DNA fragments were sheared to less than400 ribonucleotide or deoxyribonucleotide bases in length (Fig. 7B).These data suggest that binding of nucleic acids to PAI-1 isachieved only when RNA or DNA fragments are sufficiently long(>400 bases for RNA and >500 bases for DNA). These dataalso indicate that RNA and DNA can bind to both active and latentforms of PAI-1.

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FIGURE 7.
Binding of RNA and DNA fragments to PAI-1. A, biotinylated RNA or DNA was sonicated for the indicated times, subjected to agarose gel electrophoresis, and visualized by ethidium bromide staining. B, after sonication, the same RNA (black bars) or DNA (open bars) samples were added to wells of a microtiter plate coated with wild type PAI-1 and incubated for 2 h at room temperature. Bound nucleic acids were detected using peroxidase-labeled streptavidin and TMB as substrate. Data represent mean ± S.D. (n = 8) of a typical experiment of three. **, p < 0.0001; ***, p < 0.00001 versus nonsonicated RNA or DNA.

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FIGURE 8.
Stabilization of the active conformational state of PAI-1 by nucleic acids. PAI-1 was incubated alone (A) or together with vitronectin (B), RNA (C), or DNA (D) for 1–5 h at 37 °C prior to evaluation of PAI-1 inhibitory activity against uPA. Data points indicate the mean ± S.D. (n = 5 for each time point). The dashed lines indicate the 95% confidence intervals of the regression analysis. The calculated half-life for spontaneous inactivation (t_(inact)) of PAI-1 is indicated within the plots.

We next investigated the effects of RNA binding on PAI-1 stability.Incubation of PAI-1 alone for 5 h at 37 °C resulted in acomplete loss of inhibitory activity toward uPA (Fig. 8A), witha half-life for the spontaneous inactivation (t_(inact)) of PAI-1of 48.4 ± 8 min. This phenomenon was prevented by vitronectin(Fig. 8B) (41, 42), where the t_(inact) for PAI-1 was increasedto 138.6 ± 9 min in the presence of 70 nM vitronectin(Fig. 8B). We demonstrate here that RNA was also a potent stabilizerof PAI-1, since the t_(inact) for PAI-1 in the presence of RNA(4 µg·ml^–1) was increased to 114.6 ±5 min (Fig. 8C). In contrast to RNA, DNA was a markedly weakerstabilizer of the active conformation of PAI-1, since the t_(inact)for PAI-1 in the presence of DNA (4 µg·ml^–1)was increased to 60.8 ± 7 min (Fig. 8D). These data indicatethat RNA, as well as vitronectin, is an effective stabilizerof the active conformation of PAI-1.

PAI-1-mediated Inhibition of Cellular Activities of FSAP—Cellularactivities of tcFSAP have been recently described, particularlywith respect to the inhibition of PDGF-BB-induced proliferationof VSMC (26). In the absence of PAI-1, FSAP inhibited PDGF-BB-inducedVSMC proliferation (Fig. 9). This effect was significantly attenuatedin the presence of 10 nM PAI-1 (Fig. 9). In the absence of FSAP,PAI-1 did not influence VSMC proliferation (not shown). Together,these data clearly indicate that the inhibition of FSAP by PAI-1alters the cellular effects of FSAP.

DISCUSSION

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Plasminogen activator inhibitor-1 in a stabilized conformationis a rapid and specific inhibitor of tPA and uPA (10–13).Thus, PAI-1 represents the major plasminogen activator inhibitorin plasma and tissues and regulates fibrinolysis and other processesmediated by plasmin (10–13). In the present study, PAI-1was identified as a novel inhibitor of the recently describedplasma-derived serine protease FSAP. In particular, the presenceof large amounts of FSAP, in free as well as in complexed highmolecular mass forms in the BAL fluids of patients with ARDS,led us to search for serpins that can form complexes with FSAP.Co-immunoprecipitation studies revealed that PAI-1, levels ofwhich are elevated in the circulation and in the alveolar compartmentof ARDS patients (39), binds to FSAP in BAL fluids from ARDSpatients and may, therefore, function as an important regulatorof FSAP activity in the alveolar space under inflammatory conditions.These findings were underscored by in vitro studies, demonstratingthe formation of a 1:1 stoichiometric complex between PAI-1and FSAP and dose-dependent binding of purified PAI-1 to purifiedFSAP. Interestingly, we were not able to co-immunoprecipitateFSAP from BAL fluids from ARDS patients with other known inhibitorsof this protease, including C1 inhibitor and ${alpha}$ ₂-antiplasmin (7,9). However, formation of SDS-stable complexes between FSAPand C1 inhibitor and FSAP and ${alpha}$ ₂-antiplasmin, as well as betweenFSAP and PAI-1, were observed in a purified in vitro system.Additionally, C1 inhibitor was a potent inhibitor of FSAP activity,exhibiting an inhibitory capacity comparable with that of PAI-1,thus supporting previous findings demonstrating C1 inhibitoras a major inhibitor of FSAP in the plasma (7). Since C1 inhibitoris known to be elevated in BAL fluids from ARDS patients (40),we cannot exclude the presence of FSAP-C1 inhibitor complexesin the alveolar space under inflammatory conditions, althoughthey were not detected in our study.

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FIGURE 9.
Influence of PAI-1 on the FSAP-mediated inhibition of vascular smooth muscle cell proliferation. Cell proliferation was determined by a DNA synthesis assay based on the uptake of bromodeoxyuridine in the presence of different test reagents in the cell culture medium, as indicated. DNA synthesis is depicted as absorbance at 405 nm. Data represent the mean ± S.D. (n = 5) of a typical experiment of three. Levels of significance are indicated by p < 0.001 (***) and p = 0.004 (**).

We demonstrate in the current study the requirement for a basicamino acid residue at P₁ in the reactive center of PAI-1 forFSAP inhibition. Substitution of Arg³⁴⁶ with Ala at P₁ in thereactive center of PAI-1 abolished the inhibitory activity ofPAI-1 toward FSAP, indicating that Arg³⁴⁶ at P₁ is a crucialrecognition site on the serpin facilitating interaction withFSAP. The requirement for a basic residue at P₁ of PAI-1 hasalso been demonstrated for the inhibition of uPA; however, itwas not obligatory for the inhibition of tPA (36, 43).

PAI-1 inhibited FSAP activity with a second-order inhibitionrate constant (K_a) of 3.38 ± 1.12 x 10⁵ M^–1·s^–1.The presence of RNA enhanced the reactivity of PAI-1 with FSAP6-fold, thereby yielding a second-order inhibition rate constantcomparable with that observed for the reaction between PAI-1and uPA. In contrast, DNA weakly affected (causing a 1.8-foldelevation) the rate of inhibition of FSAP by PAI-1. These dataare particularly relevant, since the levels of extracellularRNA in the BAL fluids from ARDS patients were significantlyelevated compared with healthy controls. In contrast, levelsof DNA were not significantly increased. We further demonstratedthat RNA, but not DNA, stabilized the active conformation ofPAI-1 and that PAI-1 residues Arg⁷⁶ and Lys⁸⁰ were major determinantsof nucleic acids binding to the PAI-1 molecule. We have alsodocumented that the interactions between FSAP and PAI-1 havefunctional relevance, since PAI-1 can antagonize cellular activitiesmediated by FSAP, particularly those related to cell proliferation.

As a consequence of the cellular disruption sustained duringacute lung injury, such as that which occurs in ARDS, we speculatedthat nucleic acids may be released into the extracellular milieu.In line with this idea, the release of extracellular DNA byactivated neutrophils has already been reported in a murinemodel of pneumococcal pneumonia (44). Additionally, high concentrationsof DNA have been found in the airway secretions of cystic fibrosispatients (45). In this report, we show, for the first time,that levels of nucleic acids, particularly RNA, are elevatedin BAL fluids from ARDS patients. Our data indicate two separate,but related, phenomena that may impact PAI-1 activity as a consequenceof this RNA release. First, we have demonstrated that, in thelong term (30 min to 5 h), RNA can stabilize the active conformationof PAI-1 and thus dramatically decrease the rate of spontaneousinactivation of PAI-1. Thus, in the presence of RNA, PAI-1 inhibitoryactivity would be prolonged in vivo, and this would have theoverall effect of increasing the active concentration of PAI-1in the lung. Second, in the short term (0–4 min), RNAalso promoted a dramatic and significant increase in the rateat which PAI-1 associates with FSAP, which would have the overalleffect of increasing the inhibitory potency of PAI-1 againstFSAP and other proteases. Since the effect of RNA on the K_ais evident within seconds of exposure of PAI-1 to RNA, duringwhich time little effect of RNA on PAI-1 stability is observed,the increased K_a cannot be attributed to increased PAI-1 stabilitybut may well be explained by a template mechanism, such as thatpreviously proposed for RNA-assisted autoactivation of FSAP(8). A similar mechanism has been also described for other negativelycharged molecules and seems to be involved, for instance, inthe heparin-induced acceleration of the inhibition of thrombinby the serpin antithrombin (18, 19). The RNA-binding domainin FSAP has been recently identified; the amino acid residuesArg¹⁷⁰, Arg¹⁷¹, Ser¹⁷², and Lys¹⁷³ within the epidermal growthfactor-like domain 3 were found to be essential for RNA binding(46). In contrast, the possible RNA-binding domains in PAI-1have been investigated for the first time in the present study.We have demonstrated that the basic amino acid residues Arg⁷⁶and Lys⁸⁰, located in the helix D subdomain of PAI-1, that havebeen previously identified to be critical for the interactionof PAI-1 and heparin (18, 19) are also of critical importancefor the interaction of PAI-1 and RNA. Additional PAI-1 residuesclearly also play a role in RNA binding, since PAI-1 variantscontaining nonconservative substitutions in Lys⁶⁵, Lys⁶⁹, andLys⁸⁸ exhibited moderately reduced RNA-binding capacity.

To a much lesser extent than that observed for RNA, the inhibitionof FSAP by PAI-1 was also enhanced in the presence of the extracellularmatrix protein vitronectin (1.7-fold) and DNA (1.8-fold), whereasheparin had no effect on this interaction. These data are inline with other reports indicating that heparin did not enhancethe inhibitory potency of other FSAP inhibitors, such as aprotinin,C1 inhibitor, and ${alpha}$ ₂-antiplasmin (9). In contrast, antithrombininhibits FSAP only in the presence of heparin (9). Our datacontrast sharply with observations made concerning the effectof DNA on the interactions between cathepsin G and ${alpha}$ ₁-antichymotrypsinand between cathepsin G and ${alpha}$ ₁-proteinase inhibitor (38), wherecathepsin G-DNA complexes were resistant to the inhibition by ${alpha}$ ₁-antichymotrypsin and ${alpha}$ ₁-proteinase inhibitor. It remains unclearwhy RNA is a much better enhancer of the FSAP-PAI-1 interactionthan is DNA, although it might be speculated that single-strandedRNA is less sterically constrained than is double-stranded DNA.This flexibility might facilitate the FSAP-PAI-1 interactiondirectly, or it may alter the conformation of either FSAP orPAI-1 or both molecules, facilitating enhanced interaction.We do not currently have any data to support either suggestion.

The role of FSAP inhibition by PAI-1 under different physiologicaland pathophysiological conditions is presently unclear. A dualrole for FSAP in hemostasis was recently reported; FSAP activatescomponents of both the coagulation and the fibrinolytic systemsin vitro (3, 9). Which of these two hemostatic pathways predominatesin vivo may depend on local conditions (e.g. the presence orabsence of different components of the coagulation and fibrinolyticsystem, including protease inhibitors, such as PAI-1). Therefore,FSAP inhibition by PAI-1, as demonstrated in the present study,might be an important regulatory mechanism at play in hemostasisunder physiological and pathophysiological conditions. In acuteinflammatory lung diseases, such as ARDS, alterations to thealveolar hemostatic balance toward procoagulant activity andoverwhelming and persistent pulmonary fibrin deposition occurand are thought to contribute to the impairment of gas exchangeand to the induction of fibroproliferative processes (47–51).Whether increased FSAP levels³ and interactions between FSAPand PAI-1 (as demonstrated in the present study) in the lungsof patients with ARDS contribute to these phenomena is presentlyunresolved and warrants further investigation.

Apart from a potential role for FSAP in hemostasis, cellularactivities of FSAP have been described. It was recently shownthat FSAP reduces cell proliferation of human umbilical veinendothelial cells (52) as well as VSMC (26). Together with theobserved presence of FSAP in atherosclerotic lesions and theidentification of a single nucleotide polymorphism (MarburgI) as a risk predictor of carotid stenosis (53), FSAP was suggestedto be an important inhibitor of the proatherogenic phenotypeof VSMC (26). In the present study, we demonstrated that PAI-1can antagonize the FSAP-mediated inhibition of VSMC proliferation,underscoring the functional relevance of FSAP inhibition byPAI-1 and its possible involvement in cellular activities associatedwith cell proliferation. Whether inhibition of FSAP by PAI-1by interfering with FSAP-mediated inhibition of cell proliferationcontributes to the development of atherothrombotic events needsto be investigated in future studies.

To summarize, this study documents for the first time that PAI-1is an inhibitor of FSAP, potentially serving as an importantregulatory mechanism in hemostasis and vascular cell functions,particularly in processes such as inflammation and atherosclerosis.Moreover, under a variety of experimental conditions, we havedemonstrated that extracellular RNA but not DNA enhances thereactivity of PAI-1 with FSAP and stabilizes the active conformationalstate of PAI-1. Therefore, in addition to vitronectin, extracellularRNA may provide a reservoir of active PAI-1, particularly duringinflammation, when cell damage occurs and RNA is released.

FOOTNOTES

^* This work was supported in part by Deutsche Forschungsgemeinschaft(Bonn, Germany) Grant KFO 118. The costs of publication of thisarticle were defrayed in part by the payment of page charges.This article must therefore be hereby marked "advertisement"in accordance with 18 U.S.C. Section 1734 solely to indicatethis fact.

¹ To whom correspondence should be addressed: Dept. of Biochemistry, Faculty of Medicine, Justus-Liebig-University Giessen, Friedrichstrasse 24, 35392 Giessen, Germany. Tel.: 49-641-99-47501; E-mail: malgorzata.wygrecka{at}innere.med.uni-giessen.de.

² The abbreviations used are: FSAP, factor VII-activating protease;ARDS, acute respiratory distress syndrome; BAL, bronchoalveolarlavage fluid; PAI-1, plasminogen activator inhibitor-1; PDGF,platelet-derived growth factor; scFSAP, single-chain FSAP; TBS,Tris-buffered saline; tcFSAP, two-chain FSAP; TMB, 3,3',5,5'-tetramethylbenzidine;tPA, tissue-type plasminogen activator; VSMC, vascular smoothmuscle cell(s); uPA, urokinase-type plasminogen activator; WT,wild-type; BSA, bovine serum albumin; TBS, Tris-buffered saline;GAPDH, glyceraldehyde-3-phosphate dehydrogenase.

³ M. Wygrecka, P. Markart, L. Fink, A. Guenther, and K. T. Preissner,unpublished observations.

ACKNOWLEDGMENTS

We thank Gisela Müller and Horst Thiele for excellent technicalassistance.

REFERENCES

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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Plasminogen Activator Inhibitor-1 Is an Inhibitor of Factor VII-activating Protease in Patients with Acute Respiratory Distress Syndrome*

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