Potentiation of Endogenous Fibrinolysis and Rescue from Lung Ischemia/Reperfusion Injury in Interleukin (IL)-10-reconstituted IL-10 Null Mice

doi:10.1074/jbc.M002682200

Potentiation of Endogenous Fibrinolysis and Rescue from Lung Ischemia/Reperfusion Injury in Interleukin (IL)-10-reconstituted IL-10 Null Mice^*

Kenji Okada, Tomoyuki Fujita, Kanji Minamoto, Hui Liao, Yoshifumi Naka, and David J. Pinsky

From the Columbia University, College of Physicians and Surgeons, New York, New York 10032

Received for publication, March 28, 2000

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Little is known about interactions between endogenous anti-inflammatory paradigms and microvascular thrombosis in lung ischemia/reperfusion(I/R) injury. Interleukin (IL)-10 suppresses macrophage activationand down-regulates proinflammatory cytokine production, but thereare no available data to suggest a link between IL-10, thrombosis,and fibrinolysis in the setting of I/R. We hypothesized that hypoxia/ischemiatriggers IL-10 production, to dampen proinflammatory cytokineand adhesion receptor cascades and to restore vascular patencyby fibrinolytic potentiation. Studies were performed in a mouselung I/R model. IL-10 mRNA levels in lung were increased 43-foldover base line by 1 h of ischemia/2 h of reperfusion, with a correspondingincrease in plasma IL-10. Expression was prominently localizedin bronchial epithelial cells and mononuclear phagocytes. To studythe link between IL-10 and fibrinolysis in vivo, the inductionof plasminogen activator inhibitor-1 (PAI-1) was evaluated. Northernanalysis demonstrated exaggerated pulmonary PAI-1 expression inIL-10 ( $-$ / $-$ ) mice after I/R, with a corresponding increase in plasmaPAI/tissue-type plasminogen activator activity. In vivo, IL-10( $-$ / $-$ ) mice showed poor postischemic lung function and survivalafter I/R compared with IL-10 (+/+) mice. Despite a decrease ininfiltration of mononuclear phagocytes in I/R lungs of IL-10 ( $-$ / $-$ )mice, an increased intravascular pulmonary fibrin deposition wasobserved by immunohistochemistry and Western blotting, along withincreased IL-1 expression. Recombinant IL-10 given to IL-10 ( $-$ / $-$ )mice normalized the PAI/tissue-type plasminogen activator ratio,reduced pulmonary vascular fibrin deposition, and rescued micefrom lung injury. Since recombinant hirudin (direct thrombin inhibitor)also sufficed to rescue IL-10 ( $-$ / $-$ ) mice, these data suggest apreeminent role for microvascular thrombosis in I/R lung injury.Ischemia-driven IL-10 expression confers postischemic pulmonaryprotection by augmenting endogenous fibrinolyticmechanisms.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Ischemia/reperfusion (I/R)¹ lung injury plays a significant role in clinical situations such as lung transplantation (1-3).Lung failure associated with I/R is characterized by increasedmicrovascular permeability, pulmonary vascular resistance withsubsequent edema formation and impairment of gas exchange, andmicroembolism. The lungs are particularly susceptible to ischemia/reperfusioninjury, presumably due to the rich vascularity of the lungs andthe relatively large surface area over which blood-borne componentscan interact with endothelium. The proximate mechanisms of ischemiclung injury are diverse and include leukocyte activation and recruitment(1), complement activation (4), abnormalities in pulmonaryvascular tone, and increased procoagulant activity, resultingin microcirculatory failure, cellular dysfunction, edema, andcell death. The local production of proinflammatory cytokines,such as IL-1 $alpha$ and tumor necrosis factor- $alpha$ , is considerably increasedin I/R injury (5, 6), which can also feedback to increaseexpression of intercellular adhesion molecule (ICAM-1) or P-selectinon pulmonary vascular endothelial cells, the expression of whichis likewise deleterious (7-10). Although clear roles for proinflammatorycytokines and leukocyte adhesion receptors have been defined inthe setting of frank pulmonary I/R (1, 11, 12), the pathophysiologicalrole for localized thrombosis has been ascribed only byinference.

Since microvascular thrombosis can impede the return of blood flow even when perfusion pressure is normalized, this can exacerbateand create ongoing tissue damage. In the brain, postischemic microvascularthrombosis and leukocyte recruitment contribute significantlyto ischemic cerebral tissue damage (13-15). In the heart, postischemicno reflow has been documented even following relief of the majorvascular obstruction. Although the lungs are a particularly vulnerabletissue in terms of their response to I/R injury, and even relativelyminor interruptions of blood flow might lead to postischemic hypoperfusionand microvascular dysfunction (16), the contribution of in situthrombosis to the postischemic no-reflow phenomenon in the lungsremains unclear. The important role of fibrinolysis by the plasminogenactivator system has been well studied in the case of large macrovascularthrombotic occlusions, and exogenous tissue-type plasminogen activator(tPA) has been widely used in clinical settings such as acutemyocardial infarction or deep vein thrombosis. Plasminogen activatorinhibitor-1 (PAI-1) is a 52-kDa serine protease inhibitor thatserves as the major plasma inhibitor of tPA and urokinase-typeplasminogen activator (uPA) and therefore has been the focus forstudy as the critical inhibitor of fibrinolysis (17-22). Some studieshave suggested a relation between the increased synthesis of PAI-1and persistence or recurrence of thrombosis (17, 18) evenafter thrombolytic therapy. We have shown the physiologic relevanceof hypoxia-induced modulation of the fibrinolytic response inthe pathogenesis of fibrin accumulation in lungs using PAI-1-,tPA-, and uPA-deficient mice (23). Since hypoxia is an importantcomponent of the ischemic vascular milieu, these data suggestthat I/R injury might involve not only induction of the inflammatoryresponse but also abnormalities in the fibrinolytic system thatlead to clotformation.

In most biological systems, when one set of pathways is triggered, countervailing forces are activated to modulate the effectsof uncontrolled activation of the primary pathway. The currentstudies were undertaken to elucidate the potential negative regulatoryeffects of IL-10 on critically relevant issues of cytokine inductionand thrombosis in lung I/R injury. IL-10 is one of the Th2 typecytokines that is believed to exert anti-inflammatory effectsin different systems by its ability to suppress macrophage activationand down-regulate proinflammatory cytokine production (24).IL-10 inhibits several macrophage functions, including antigenpresentation to T cells, synthesis of several proinflammatorycytokines (such as IL-1 $alpha$ and - $beta$ , IL-6, IL-8, tumor necrosis factor- $alpha$ ,granulocyte-macrophage colony-stimulating factor, and granulocytecolony-stimulating factor), and production of reactive oxygenintermediates and nitric oxide (25-27). With regard to the lung,several studies have shown that IL-10 reduces the intensity ofcellular recruitment in pulmonary inflammation and is an inhibitorof the induced release of several proinflammatory cytokines suchas TNF- $alpha$ and macrophage inflammatory proteins 1 and 2, supportingan anti-inflammatory role of IL-10 in the lung (28). Furthermore,some studies have shown that IL-10 has significant protectiveeffects in lung inflammatory injury by suppressing the expressionICAM-1 (29, 30). Although a recent report shows that IL-10may inhibit coagulation and potentiate the fibrinolytic systemin human endotoxemia (31), no data are available with respectto its effects on the coagulant/fibrinolytic mechanism in I/R.Therefore, the current studies were driven by a 2-fold hypothesis:1) that microvascular thrombosis represents a significant componentof lung I/R injury and 2) that endogenous IL-10 plays a pivotalrole in regulating the fibrinolytic system in lung I/Rinjury.

EXPERIMENTAL PROCEDURES

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Animals-- IL-10-deficient mice (IL-10 ( $-$ / $-$ ), C57/6-IL-10^tm1cgn, male, 10 weeks old) (32) and their wild-type controls (IL-10 (+/+), C57/6J,male, 10 weeks old), which were purchased from Jackson Laboratories(Bar Harbor, ME), were used in these experiments according toa protocol approved by the Institutional Animal Care and Use Committeeat Columbia University, in accordance with guidelines of the AmericanAssociation for the Accreditation of Laboratory AnimalCare.

Murine Ischemia/Reperfusion Model-- Animals were initially anesthetized intraperitoneally with 0.1 mg/g of mouse weight of ketamine and 0.01 mg/g of mouse weightof xylazine, followed by intraperitoneal continuous infusion ofone-third of the initial dose per hour using a syringe pump (model100 series, KD Scientific Inc.). After ensuring appropriate depthof anesthesia, mice were intubated via tracheostomy and placedon a Harvard ventilator (tidal volume = 0.75 ml, respiratory rate= 120/min) with room air, followed by bilateral thoracotomy. Theleft hilum was cross-clamped for a period of 1 h, after whichthe cross-clamp was released. Reperfusion proceeded from 1 to3 h according to the following groups: untreated lung in shamoperation; group I, 1-h ischemia without reperfusion; and R-1,R-2, or R-3 groups, consisting of 1-h ischemia followed by 1-,2-, and 3-h reperfusion, respectively. After observation, bloodsamples were obtained for ELISA (IL-10), and lung specimens weretaken for Northern blotanalysis.

Survival Experiments-- For all experiments, the surgical operator was blinded by a colleague in the laboratory as to either the strain of mice beingused (all mice were black in appearance) or to the specific substancebeing injected. Four groups were studied: 1) IL-10 (+/+) mice(received 300 µl of PBS without additive); 2) IL-10 ( $-$ / $-$ ) mice(received 300 µl of PBS without additive); 3) IL-10 ( $-$ / $-$ ) micegiven 1 µg of recombinant murine IL-10 (R & D Systems) after thoracotomybut before pulmonary ischemia. rmIL-10 was prepared as 1 µg/300µl in PBS; 4) IL-10 ( $-$ / $-$ ) mice given 1.0 mg/kg recombinant hirudin(direct and specific thrombin inhibitor; Sigma) after thoracotomybut before pulmonary ischemia. Recombinant hirudin was preparedfor a 1.0 mg/kg injection in 300 µl in PBS. For all four groups,the experimental procedures were as follows. After 1-h ischemiafollowed by 2-h reperfusion, the contralateral (right) hilum waspermanently ligated, so that the animal's survival and gas exchangedepended solely upon the reperfused lung, and observation continuedfor 1 h among these four groups. As the mouse continued to beventilated, death of the mouse was defined as a combination of1) cessation of regular cardiac activity; 2) the apparent collapseof the left atrium; and 3) brief clonic activity indicating cessationof cerebral blood flow. At the time of death, blood samples wereobtained for ELISA (IL-1 $alpha$ , sICAM-1) or PAI/tPA activity assays,and lung specimens were taken for the measurement of wet/dry ratiosor Northern blot analyses .

In a separate series of survival experiments, lung function was ascertained by arterial blood gas analysis (sampled from theleft ventricle) in mice that survived for 30 min after right hilarligation. Immediately after determination of lung function, micewere heparinized, and lung specimens were taken for Western blotor immunohistochemical analysis for fibrin. These experimentswere performed as a separate group so that obtaining the leftventricular sample of blood did not impact on mousesurvival.

Wet/Dry Ratio-- When mice were sacrificed after the survival experiments, the left hilum was ligated, and then the left lung (including residualblood) was taken and weighed as a wet weight. The lung specimenwas desiccated at 80 °C for 24 h and weighed again as dry weight.Wet weight was divided by dry weight for the calculation of wet/dryratio.

ELISA for IL-10, IL-1 $alpha$ , and sICAM-1-- IL-10 (+/+) mice were divided into untreated, I, R-1, R-2, and R-3 groups. In each group, blood was drawn from the heart,kept at 4 °C overnight, and centrifuged at 13,000 rpm for 20 minto obtain serum, which was then divided into aliquots and frozenat $-$ 80 °C until the time of use. The serum IL-10 level was assayedby ELISA kits (R & D Systems), and IL-1 $alpha$ and sICAM-1 levels wereassayed by an ELISA kit (Endogen). The lower limits of detectionfor IL-10, IL-1 $alpha$ , and sICAM-1 assays are 4 pg/ml, 6 pg/ml, and5 ng/ml, respectively. Values are expressed as the mean ± S.E.of duplicatedeterminations.

RNA Extraction from Lung Tissues and Northern Blot Analysis-- In dedicated experiments, the left lung was rapidly excised and snap-frozen in liquid nitrogen until the time of mRNA extraction.After tissue homogenization using a Brinkmann Polytron homogenizer,total RNA from the lung tissues was isolated by the Tryzol method(Life Technologies, Inc.), and then poly(A) mRNA were purifiedusing Poly(A)Ttract^® mRNA Isolation Systems (Promega, Madison,WI).

To detect IL-1 $alpha$ , IL-10, PAI-1, and tPA transcripts, equal amounts of poly(A) mRNA (2.5 µg/lane) or total RNA (25 µg/lane)were loaded onto an 0.8% agarose gel containing 2.2 M formaldehydefor size fractionation and then transferred overnight to nylonmembranes (Duralon-UV^TM membranes; Strategene) with 20× SSC buffer. A murine IL-10 (1.5kilobases; American Type Culture Collection), IL-1 $alpha$ (789 bp),PAI-1 (900 bp; the plasmid, containing a pBS vector and a 3014-bpinsert, was generously provided by M. Cole), and tPA (800 bp;composed of a 2.5-kb insert from a pKS +/ $-$ plasmid vector (33))cDNAs were purified using a Qiagen II gel extraction kit (QIAGENInc.). These fragments were used as cDNA probes after ³²P-random primer labeling (Prime-It RmT; Strategene) with [ $alpha$ -³²P]dCTP. After prehybridization and hybridization using QuikHybhybridization solution (Strategene) at 68 °C for 1 h, the blotswere washed twice for 15 min with 2× SSC, 0.1% SDS at room temperature,followed by one wash for 30 min with 0.1× SSC, 0.1% SDS at 60°C. Blots were developed with X-Omat AR film exposed with an intensifyinglight screen at $-$ 80 °C for 3 days. Normalized absorption valueswere obtained by densitometry scanning (Molecular Imager^® System; Bio-Rad) of cDNAs including $beta$ -actinbands.

In Situ Hybridization-- In order to make RNA probes for in situ hybridization, the polymerase chain reaction was first performed using total RNA fromthe lung tissue after 1-h ischemia followed by 2-h reperfusion.Reverse transcription was performed on total RNA with oligo(dT)primers, and amplification was carried out for 35 cycles by polymerasechain reaction with specific primers for IL-10 (CLONTECH): 5'primer, 5'-ATGCAGGACTTTAAGGGTTACTTGGGTT-3'; 3' primer, 5'-ATTTCGGAGAGAGGTACAAACGAGGTTT-3'.An aliquot of the polymerase chain reaction product mixture wasrun in a 1% agarose gel stained with ethidium bromide. The polymerasechain reaction products (455 bp) were recovered using a QiagenII gel extraction kit (QIAGEN) and inserted to pGEM-T^® Easy Vector using the T4 ligation method (Promega). The RNA expressionplasmid was linearized with NcoI and SalI enzymes to allow invitro run-off synthesis of both sense- and antisense-orientedRNA probes. Both sense and antisense probes were labeled by transcriptionwith a digoxigenin RNA labeling kit (Roche Molecular Biochemicals),and the labeled probes were thenpurified.

Both untreated lungs and left lungs after 1-h ischemia/2-h reperfusion were snap-frozen embedded in OCT compound (Miles Scientific)in a cryomold in liquid nitrogen. The frozen sections were cutat 5 µm thick and placed on glass slides precoated with opaque(VWR Scientific Products). Briefly, slides were prefixed in 4%paraformaldehyde for 20 min and then digested with 14 µg/ml proteinaseK in Tris-EDTA (pH 8.0) for 15 min at 37 °C, fixed in 4% paraformaldehydefor 10 min. Sections were acetylated with 0.1 mol/liter triethanolamine(pH 8.0) with 0.25% (v/v) acetic anhydride. Sections were thenequilibrated for 60 min in hybridization buffer consisting of4× SSC, 50% formamide, 5% dextran sulfate, 0.1 mg/ml yeast tRNA,and 0.05 mg/ml salmon sperm DNA. Hybridization was carried outovernight at 45 °C with either IL-10 sense or antisense probe(1:25 dilution in prehybridization buffer). Sections were subjectedto stringent washes consisting of a single wash with 2× SSC, two30-min washes with 1 × SSC at room temperature, two 30-min washeswith 0.1× SSC at 37 °, and two 20-min washes with Tris buffer(100 mmol/liter Tris-HCl, 150 mmol/liter NaCl). After blockingwith blocking buffer (0.1% Triton X-100, 4% sheep serum, 100 mmol/literTris-HCl, and 150 mmol/liter NaCl), sections were incubated witha 1:100 dilution of anti-digoxigenin antibody (Roche MolecularBiochemicals) for 2 h at room temperature. After four washes,color was allowed to develop for 4 h, and development was stoppedby dipping the slides briefly in Tris-EDTA buffer (pH 8.0) andthen rinsing. Sections were covered with coverslips with water-solublemountingmedium.

PAI and tPA Activity Assay-- PAI/tPA activity was determined by a functional rate assay described by Ranby et al. (34) and its adaptation to plasma samples,as described by Wiman et al. (35). Blood samples (F, n = 9;IL-10 (+/+), n = 9; IL-10 ( $-$ / $-$ ), n = 9; and IL-10 ( $-$ / $-$ ) plus rmIL-10,n = 9) were drawn at the end of survival experiments and acidifiedby acetate buffer immediately. The samples were centrifuged at2000 × g for 5 min. Equal volumes of acetate buffer and Tris bufferwere added to acidified plasma and incubated at 37 °C for 20 min.The activity was assayed by Spectrolyse^® tPA/PAI activity assay kits (American Diagnostica). In brief,each sample was added to reaction mixture containing a known quantityof tPA, soluble fibrin (Desafib; American Diagnostica), and aplasmin substrate (Spectrozyme PL; American Diagnostica). Plasmingenerated by the reaction of tPA and fibrin cleaves the Spectrozymesubstrate to generate a yellow color, which can be measured atan OD of 405 nm. PAI activity is expressed as the amount of PAIthat inhibits 1 IU of tPA.

Western Blotting for Fibrin Accumulation-- Lung tissues were harvested following systemic heparinization and snap-frozen in liquid nitrogen until the time of fibrinextraction. These tissues were placed in buffer (0.05 M Tris,0.15 M NaCl, 500 units/ml heparin, final pH 7.6) on ice and homogenized.Plasmin digestion was performed by a modification of the methodsof Francis (36), as described previously (34). Human plasmin(0.32 units/ml; Sigma) was added to the tissue homogenate, followedby agitation at 37 °C for 6 h. More plasmin (0.32 units/ml) wasthen added, and samples were agitated for an additional 2 h, andthen the mixture was centrifuged at 2300 × g for 15 min, and thesupernatant was aspirated. As a positive control, mouse fibrinogen(2.5 mg in 0.25 ml; Sigma) was clotted with human thrombin (4units; Sigma) in Tris-buffered saline (1.75 ml) in the presenceof calcium chloride (0.013 ml of 2.5 M) for 4 h at room temperature.Clotted fibrinogen was centrifuged for 5 min, and the pellet wassuspended in Tris-buffered saline (1.0 ml) containing human plasmin(0.32 units/ml) and agitated at 37 °C. Additional plasmin (0.32unit/ml) was added after 6 h, and samples were agitated for anadditional 2 h. As a negative control, unclotted mouse fibrinogenwas processed in an identical manner. Protein concentration ofplasmin-treated lung supernatants and plasmin-treated unclottedand clotted fibrinogen solutions was measured by the Bradfordmethod (37) before loading the gel. Samples were boiled for3 min under reducing conditions, loaded onto a SDS-polyacrylamidegel (7.5% reduced gel; 10 µg of protein/lane), and subjected toelectrophoresis. Samples were electrophoretically transferredto nitrocellulose, and blots were reacted with a monoclonal anti-fibrinIgG1 (Biodesign International) that had been prepared with humanfibrin-like $beta$ peptide as immunogen (38). The cross-reactivityof this antibody with murine fibrin was confirmed by blottingwith the positive (murine fibrin) and negative (murine fibrinogen)controls prepared as described above. Secondary detection of sitesof primary antibody localization was accomplished using a horseradishperoxidase-conjugated goat anti-mouse IgG (Fc) (Sigma). Finaldetection of bands was performed using the enhanced chemiluminescenceWestern blotting system (Amersham PharmaciaBiotech).

Immunohistochemistry-- In addition to Western blot analyses performed as described above, fibrin accumulation was determined by immunohistochemistry.Left lung tissue from untreated and IL-10 ( $-$ / $-$ ) groups, harvestedin survival experiments (with antemortem heparinization to limitpostmortem thrombosis) was used to identify the fibrin accumulationby immunostaining. The left lung was snap-frozen embedded in OCTcompound, and sections were cut at 5 µm thick, air-dried, andacetone-fixed. Endogenous peroxidase activity was blocked by incubationfor 20 min in PBS containing 0.3% hydrogen peroxide. Sectionswere immunostained using the same primary antibody (1:50) as thatused for Western blotting, which is reactive to murine fibrin.Sites of primary antibody binding were visualized with mouse ExtraAvidin^® alkaline phosphatase staining kit (Sigma) and Sigma FAST 228FAST RED (Sigma). In order to more specifically localize fibrindeposits, a double immunostaining technique was employed on thesesame sections. Sections were overlaid with 20% goat serum for30 min, washed, and then incubated for 1 h at room temperaturewith a rabbit polyclonal antihuman von Willebrand's antibody (CortexBiochem, San Leandro CA). Detection of the primary antibody wasaccomplished using a biotinylated goat anti-rabbit IgG and theperoxidase avidin-biotin staining procedure. Immunostaining formononuclear phagocytes was accomplished using a primary rat monoclonalanti-mouse panmacrophage marker (MOMA-2; BIOSOURCE International,Camarillo, CA) (39). Development and visualization were accomplishedas described above with the exception that slides were counterstainedwith methyl green. The number of positively stained macrophageswas determined in 10 random high power fields (× 400 magnification),and the average number of macrophages/field was calculated foreachgroup.

Statistical Analysis-- The data were expressed as mean ± S.E. All statistical comparisons were performed using a commercially available statisticalpackage for the Macintosh personal computer (STAT VIEW-J 5.0;Abacus Concepts). Analysis of variance was used to compare differentconditions among the groups of mice. The product limit (Kaplan-Meier)estimate of the cumulative survival was assessed with the log-ranktest to evaluate significance differences. Differences were consideredsignificant at the level of p < 0.05.

RESULTS

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

ELISA for IL-10, IL-1 $alpha$ , and sICAM-1-- To investigate the role of IL-10 in lung I/R injury, we first examined the serum levels of IL-10, IL-1 $alpha$ , and sICAM-1 in bothIL-10 (+/+) and ( $-$ / $-$ ) mice during ischemia and reperfusion. Serumlevels of IL-10 in IL-10 (+/+) mice increased time-dependently(R-3 was the longest time studied) (Fig. 1A). Under conditionsof 1 h ischemia/2 h reperfusion, IL-1 $alpha$ levels in IL-10 ( $-$ / $-$ ) micewere significantly higher than those in IL-10 (+/+) mice. Administrationof rmIL-10 to IL-10 ( $-$ / $-$ ) mice reduced levels of IL-1 $alpha$ significantly(Fig. 1B). No significant differences in sICAM-1 levels were notedamong these four groups (Fig. 1C).

View larger version (29K):
[in this window]
[in a new window]

Fig. 1. Serum levels of IL-10, IL-1 $alpha$ , and sICAM-1 were measured by ELISA. IL-10 in the I/R model showed a time-dependent increase after reperfusion (A). For IL-1 $alpha$ and sICAM-1, the values were compared among untreated, IL-10 (+/+), ( $-$ / $-$ ), and ( $-$ / $-$ ) plus rmIL-10 mice. IL-1 $alpha$ levels in the IL-10 ( $-$ / $-$ ) group showed elevated values compared with other groups, which were reduced by exogenous rmIL-10 administration (B). There was no significant difference between sICAM-1 levels among these groups (C). Means ± S.E. are shown. *, p < 0.05.

Time Course of IL-10 and IL-1 $alpha$ mRNA Expression in Mouse Lung I/R-- To investigate the time course of proinflammatory cytokine IL-1 $alpha$ and anti-inflammatory cytokine IL-10 expression in our model,2.5 µg of poly(A) RNA was derived from the untreated, I, R-1,and R-2 groups (five lungs were homogenized for each group toisolate 2.5 µg of poly(A) RNA for each group). mRNA was loadedinto each lane of an agarose gel, and Northern blotting procedureswere performed as described. IL-1 $alpha$ mRNA expression was up-regulatedas early as 1 h after ischemia, and this increase continued afterreperfusion (7.1-fold increase by 2 h of reperfusion) (Fig. 2,A-C). Although IL-10 mRNA induction during ischemia was modest,induction during reperfusion was even more pronounced (43-foldincrease at 2 h of reperfusion).

View larger version (27K):
[in this window]
[in a new window]

Fig. 2. Time course of IL-10 and IL-1 $alpha$ mRNA expression after I/R in IL-10 (+/+) mice lungs. Northern blots to investigate the time course during 1-h ischemia followed by a 2-h reperfusion period in this mouse I/R model. Blots were stripped and then probed with a cDNA for $beta$ -actin in order to confirm equal loading of lanes (A). Densitometric scanning analysis is shown for IL-10 mRNA (B) and IL-1 $alpha$ mRNA expression (C).

Localization of IL-10 mRNA Expression in I/R Lungs-- To localize the cells in the lungs in which IL-10 mRNA was induced by I/R, in situ hybridization was performed using murinesense and antisense probes. Lung tissue from the R-2 group demonstratedincreased IL-10 mRNA levels in bronchial epithelial cells (Fig.3A) and mononuclear cells (Fig. 3C), but not in the endothelialcells. As negative controls, this staining was not observed inantisense-stained adjacent sections (Fig. 3, B and D) or in untreatedlungs (Fig. 3, E-H). Quantitative analysis of these data indicatesa 17-fold increase in IL-10 mRNA under ischemic compared withuntreated control conditions for epithelium and an 11-fold increasefor mononuclear phagocytes.

View larger version (107K):
[in this window]
[in a new window]

Fig. 3. Localization of mRNA for IL-10. Serial sections of lung tissue were taken from 1-h ischemia, followed by 2-h reperfusion group (A-D) and lungs from untreated mice (E-H). In situ hybridization for IL-10 mRNA expression was performed using either a murine sense probe (B, D, F, and H) as a negative control or an antisense probe (A, C, E, and G) to detect the presence of IL-10 mRNA. IL-10 mRNA was identified in the bronchial epithelial cells (arrows in A) as blue-purple coloring. Mononuclear cells also showed prominent expression (arrowheads in C; note that these represent adjacent sections).

PAI-1 mRNA Expression in IL-10 (+/+), ( $-$ / $-$ ), and ( $-$ / $-$ ) Plus rmIL-10 Mice Lungs-- To investigate the contribution of IL-10 to the fibrinolytic balance in I/R, PAI-1 mRNA expression was studied by Northernblot analysis in IL-10 (+/+), IL-10 ( $-$ / $-$ ), and IL-10 ( $-$ / $-$ ) plusrmIL-10 mice. Blots were performed four separate times using fourmice in each group, and normalized absorption values (by densitometryscanning) were analyzed statistically. One-h ischemia/2 h reperfusionup-regulated PAI-1 mRNA levels compared with untreated lung inIL-10 (+/+) mouse (2.6-fold increase) (Fig. 4, A and B). PAI-1expression was significantly up-regulated in IL-10 ( $-$ / $-$ ) mice(4.7-fold increase); this up-regulation was suppressed by administrationof exogenous rmIL-10 (Fig. 4, A and B). In contrast to increasedPAI-1 mRNA expression, although tPA mRNA appeared to increasein IL-10 ( $-$ / $-$ ) mice, this difference did not achieve the levelof a significant difference on multiple blots (data not shown).These data suggested that in wild-type mice, IL-10 induction mightcontribute to up-regulation of fibrinolytic activity in lung I/Rinjury.

View larger version (34K):
[in this window]
[in a new window]

Fig. 4. PAI-1 mRNA expression in untreated, IL-10 (+/+), ( $-$ / $-$ ), and ( $-$ / $-$ ) plus rmIL-10 mice lungs (A) and quantitative analysis by densitometric scanning (B). Normalized absorption values were obtained by densitometric scanning of PAI-1 and $beta$ -actin bands. Data are shown as means ± S.E. *, p < 0.05.

PAI and tPA Activity Assay-- Because PAI can circulate in both active and latent forms (40), plasma PAI activity was measured using a microtiter systemthat monitors PAI-mediated inhibition of plasminogen activatoractivity (34, 35) as well as tPA activity. IL-10 ( $-$ / $-$ ) miceshowed significantly higher PAI activity compared with that ofIL-10 (+/+) mice. PAI activity was significantly reduced by administrationof exogenous rmIL-10 (Fig. 5A). Although lack of the IL-10 genedid not appear to alter tPA activity, reconstitution of the IL-10null mice with rmIL-10 appeared to augment tPA activity (Fig.5B).

View larger version (29K):
[in this window]
[in a new window]

Fig. 5. Effect of endogenous IL-10 on PAI and tPA activity. All blood samples were drawn at the end of survival experiments and acidified by acetate buffer immediately (n = 9 in each group). A, PAI activity; B, tPA activity; C, PAI/tPA ratio. This ratio was calculated as PAI activity/tPA values in each group. The values expressed are the means ± S.E. *, p < 0.05.

Although tPA mRNA is reportedly unchanged after endothelial exposure to anoxia (41) or hypoxia (42), the PAI/tPA activityratio appears to be increased (42), which may contribute tothe apparent hypofibrinolytic state of endothelial cells exposedto hypoxia in vitro (42). In a whole animal hypoxia model, itappears that tPA mRNA levels are actually reduced in the lungs,which, along with induction of PAI-1 mRNA, may provide a potentstimulus for thrombus accrual (23). In the current lung I/Rmodel, the PAI/tPA ratio was therefore calculated to provide insightsinto the relative fibrinolytic "balance" in this model. The PAI/tPAratio in IL-10 ( $-$ / $-$ ) mice was significantly greater than thatobserved in IL-10 (+/+) mice, and this ratio was normalized byreconstitution of IL-10 null mice with rmIL-10 (Fig. 5C).

Detection of Fibrin-- The data shown so far regarding the role of IL-10 in modulating the fibrinolytic state suggest that in vivo, changes in thefibrinolytic balance in IL-10 ( $-$ / $-$ ) mice incited by I/R are likelyto be of pathologic significance with respect to the accrual fibrin.Immunohistochemical analysis revealed that I/R-driven fibrin accumulationoccurred predominantly at intravascular sites (Fig. 6A); controlsshowed a relative absence of fibrin accumulation in untreatedlung sections stained with identical procedures or in I/R lungtissue subjected to similar staining procedures in the absenceof the primary anti-fibrin antibody (Fig. 6B). To confirm thatIL-10 ( $-$ / $-$ ) mice actually exhibit I/R-induced accumulation offibrin, fibrin accumulation was quantified using two differentmethods in tissue from mice heparinized immediately prior to sacrificeto reduce nonspecific/postmortem thrombosis. In the first method,vessels staining for fibrin were counted by an observer blindedto experimental conditions (Fig. 6C). Although I/R increased thenumber of fibrin-positive vessels significantly, there was aneven more marked increase in fibrin-positive vessels in the IL-10( $-$ / $-$ ) mice. Recombinant murine IL-10 reduced the number of fibrin-positivevessels, suggesting a direct role of IL-10 in fibrin accumulationfollowing I/R. In the second method for quantifying fibrin accumulation,immunoblotting for fibrin was performed on lung tissue. IL-10(+/+) mice showed that the I/R stimulus does indeed cause fibrinaccumulation, compared with the absence of detectable fibrin inuntreated lung (Fig. 6D). IL-10 ( $-$ / $-$ ) mice showed a marked increasein fibrin accumulation compared with that seen under identicalI/R conditions in IL-10 (+/+) mice. Note that IL-10 ( $-$ / $-$ ) micegiven hirudin (1.0 mg/kg) also had a marked diminution in I/R-inducedfibrin accumulation. Provision of exogenous rmIL-10 to reconstitutethe IL-10 null mice resulted in marked suppression of fibrin accumulationin lung tissue (Fig. 6, C and D). These data demonstrate thatendogenous IL-10 plays a pivotal role in potentiating fibrinolysisand reducing fibrin accumulation after I/R injury.

View larger version (72K):
[in this window]
[in a new window]

Fig. 6. Effect of endogenous IL-10 on I/R-induced fibrin accumulation as detected by immunohistochemistry and immunoblotting for fibrin (with antemortem heparinization to limit postmortem thrombosis). A, fibrin (red staining) is seen to have accumulated in the ischemic/reperfused vessels (delineated by the endothelial marker, von Willebrand's; black) in A. B represents an adjacent section stained in the absence of the primary anti-fibrin antibody. C, quantification of intravascular fibrin accumulation determined by counting fibrin-positive vessels per high power field. D, plasmin digests of lung tissue taken from the following groups were used as an additional way to quantify fibrin deposition: fibrin (prepared from clotted fibrinogen in vitro as a positive control), untreated, IL-10 (+/+), IL-10 ( $-$ / $-$ ), IL-10 ( $-$ / $-$ ) plus rmIL-10, and IL-10 ( $-$ / $-$ ) plus hirudin mice (these conditions are as described under "Experimental Procedures").

Quantification of Leukocyte Infiltration-- In order to determine whether IL-10 modulates the recruitment of leukocytes (mononuclear phagocytes or polymorphonuclear leukocytes)in the setting of lung I/R injury, specific immunostaining andmyeloperoxidase assays were performed. These data show that IL-10(+/+) mice demonstrated increased recruitment of both leukocytetypes following lung I/R injury (Fig. 7, A and B). Mice in whichthe IL-10 gene was absent exhibited reduced accumulation of bothleukocyte types, but particularly of mononuclear phagocytes. Reconstitutionof IL-10 null mice with rmIL-10 resulted in an intermediate levelof accumulation.

View larger version (30K):
[in this window]
[in a new window]

Fig. 7. Quantification of leukocyte infiltration. Specific immunostaining for macrophages (A) or myeloperoxidase assays (B) was performed to quantify polymorphonuclear leukocyte infiltration. Experimental conditions were identical to those shown in Fig. 4.

Arterial Blood Gas Analysis-- Because these data show pathological accumulation of fibrin in I/R and especially in IL-10 ( $-$ / $-$ ) mice exposed to I/R, additionalexperiments were performed to show that the pathological accumulationof fibrin is liable to be pathologically relevant. Arterial bloodsamples were taken 30 min after 1-h ischemia/2-h reperfusion fromIL-10 (+/+) mice, IL-10 ( $-$ / $-$ ) mice, rmIL-10-reconstituted IL-10( $-$ / $-$ ) mice, and IL-10 ( $-$ / $-$ ) mice given hirudin. For these experiments,the contralateral (nonischemic right) lung was excluded from thecirculation so that both animal survival and gas exchange werecompletely dependent upon the function of the postischemic leftlung. Arterial oxygenation and PaO₂ deteriorated in IL-10 ( $-$ / $-$ )mice compared with IL-10 (+/+) mice, while exogenous rmIL-10 significantlyameliorated these hallmarks of lung function. IL-10 ( $-$ / $-$ ) givenhirudin mice also showed significant improvement in PaO₂ comparedwith IL-10 ( $-$ / $-$ ) mice (Fig. 8A). PaCO₂ tracked the arterial oxygenationdata in inverse relationship, as one would expect (Fig. 8B).

View larger version (34K):
[in this window]
[in a new window]

Fig. 8. Effect of endogenous IL-10 on lung function after 1 h of ischemia followed by 2 h of reperfusion. A and B, effect on gas exchange. Arterial blood samples were drawn from untreated and IL-10 (+/+), IL-10 ( $-$ / $-$ ), IL-10 ( $-$ / $-$ ) plus rmIL-10, and IL-10 ( $-$ / $-$ ) plus hirudin mice that survived for 30 min after right hilar ligation (n = 7 in each group). C, effect on edema formation, measured as the wet/dry weight ratio of the excised lung tissue. Wet/dry ratio was calculated among five groups, including untreated lung (n = 9 in each group). The values expressed are the means ± S.E. *, p < 0.05.

Wet/Dry Ratio-- To further assess lung tissue damage after I/R, we measured wet/dry ratio after the completion of the survival experiments.The data showed that IL-10 ( $-$ / $-$ ) mice contained significantlymore water than did IL-10 (+/+) mice, while edema formation wasreduced by the administration of rmIL-10 or hirudin (Fig. 8C).

Survival-- Because in vivo, there are many different mechanisms contributing to lung injury and demise of an animal after an ischemicinsult, survival experiments were performed to "summate" the multitudeof competing forces and to establish the role of endogenous IL-10and thrombosis in lung I/R injury. Again for these experiments,following ischemia and reperfusion, the contralateral (nonischemicright) lung was excluded from the circulation so that survivaldepended entirely on the postischemic left lung. IL-10 (+/+) micesubjected to 1 h of ischemia followed by 2 h of reperfusion showed67% survival during 60 min of observation after ligation of theright hilum. Survival was significantly less in IL-10 ( $-$ / $-$ ) (11%)mice during the same observation period. Reconstitution of IL-10null mice with exogenous rmIL-10 improved not only lung functionbut also the survival (44%) significantly. To demonstrate thatthrombus accumulation is a critical mechanism responsible forthe poor survival of IL-10 null mice after lung I/R, a directand specific thrombin inhibitor, recombinant hirudin was administeredto IL-10 ( $-$ / $-$ ) mice prior to ischemia. One mg/kg of recombinanthirudin markedly improved survival of IL-10 ( $-$ / $-$ ) mice (78%).These data suggest that thrombus accumulation is a significantcause of high mortality in IL-10 ( $-$ / $-$ ) mice (Fig. 9).

View larger version (16K):
[in this window]
[in a new window]

Fig. 9. Effect of endogenous IL-10 on mouse survival after I/R injury. Animal survival depended solely upon the ischemia/reperfused lung (the contralateral lung was excluded from the circulation; mice were observed for 1 h after exclusion of the contralateral lung). IL-10 (+/+), IL-10 ( $-$ / $-$ ), IL-10 ( $-$ / $-$ ) plus rmIL-10, and IL-10 ( $-$ / $-$ ) plus recombinant hirudin (n = 9 in each group) mice were used. The product limit (Kaplan-Meier) estimate of the cumulative survival was assessed with the log-rank test to evaluate for significant differences in survival. *, p < 0.05.

	DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

The major findings in these experiments are as follows: 1) endogenous IL-10 expression increases following lung ischemia andreperfusion in parallel with IL-1 $alpha$ expression; 2) the absenceof the IL-10 gene increases PAI-1 expression and results in augmentedfibrin accumulation in postischemic lungs; 3) thrombus accumulationis a significant adverse event responsible for poor postischemiclung function and survival; and 4) provision of recombinant IL-10(or an anti-thrombin agent) can rescue IL-10 null mice from thrombusaccumulation and lung failure following ischemia. Since IL-10null mice exhibited reduced recruitment of mononuclear phagocytesbut the highest levels of fibrin, the potentiation of fibrinolysisby IL-10 cannot be explained on the basis of IL-10 suppressingmononuclear phagocyte infiltration into the lungs following I/R.More likely, IL-10 has a direct effect on macrophages to reducePAI-1 expression, a claim that is indirectly supported by in vitrodata (not shown) in which mononuclear phagocytes exhibited IL-10-mediatedsuppression of hypoxic induction of PAI-1. In vivo, IL-10 notonly potentiates fibrinolysis but suppresses the expression ofa potent proinflammatory cytokine (IL-1 $alpha$ ), whose expression inischemia also contributes to leukocyte recruitment and tissuedamage (43).

Like many other cytokines, IL-10 is produced by many cell types and mediates diverse cellular functions. In addition to Tcells, IL-10 is also expressed by stimulated B lymphocytes, monocytes-macrophages(44), keratinocytes (45, 46), mast cells (46), and epithelialcells (47). With regard to the lung, it has been demonstratedthat alveolar macrophages can produce significant amounts of IL-10(48). In our study, in situ hybridization identified mononuclearphagocytes and bronchial epithelial cells as major cellular sourcesof IL-10 in lung. Bonfield et al. (49) have demonstrated thatbronchial epithelial cells from healthy control subjects constitutivelyproduce IL-10, which appears to be down-regulated in cystic fibrosispatients. However, in our acute lung I/R model, Northern blotanalysis and serum levels showed that IL-10 was expressed littleconstitutively but strongly up-regulated in a time-dependent fashionafter reperfusion; this may serve as compensatory regulation againstthe inflammatory response after ischemicinjury.

The prevailing belief is that the mechanism by which IL-10 exerts cytoprotective effects against I/R injury is due to 1) theability of IL-10 to inhibit macrophage function and to inhibitthe synthesis of several proinflammatory cytokines (25-28) and2) its ability to suppress leukocyte-endothelial cell interactions(29, 30). In order to elucidate the role of endogenous IL-10in lung I/R injury, we used IL-10-deficient mice, which couldbe reconstituted with exogenous rmIL-10, as a critical way todissect the mechanism by which IL-10 works in vivo. Accordingto our data, IL-10 ( $-$ / $-$ ) mice showed the greatest expression ofIL-1 $alpha$ , prominent edema formation, the worst postischemic lungfunction, and the lowest survival compared with IL-10 (+/+) mice.Whereas exogenous rmIL-10 administration reversed these adverseeffects (including the high mortality), sICAM-1 levels were notsignificantly affected by the IL-10 deficiency (nor was ICAM-1on Northern blots; data not shown). These data suggest that althoughendogenous IL-10 suppresses IL-1 expression, its protective rolein lung ischemia is not likely to be mediated by inhibiting ICAM-1expression.

In contrast to our initial expectations that macrophage infiltration might be suppressed by IL-10, our data showed exactlythe opposite effect, that the presence of IL-10 was associatedwith increased accumulation of mononuclear phagocytes. Similaralbeit much less pronounced effects were seen with regard to neutrophilinfiltration when tissue was analyzed for the relatively neutrophil-specificenzyme myeloperoxidase. Although the I/R procedure caused a dramaticincrease in the number of infiltrating MPs, lack of the IL-10gene was associated with a significant reduction in MP recruitment."Rescue" of the IL-10 null mice with IL-10 caused a significantincrease in MP recruitment following I/R, albeit absolute levelswere highest in mice capable of expressing the IL-10 gene. AlthoughIL-10 generally has anti-inflammatory properties, there is supportin the literature for an effect of IL-10 to increase levels ofmonocyte chemoattractant protein-1 under certain conditions (dependentupon cell type and activation state) (50).

Recent evidence is emerging that, in concert with the shift toward a procoagulant phenotype, endothelial cells exhibit a diminishedfibrinolytic response under conditions of oxygen deprivation,especially when followed by reoxygenation and attendant productionof reactive oxygen intermediates (41, 51). We have shown thephysiologic relevance of hypoxia-induced modulation of the fibrinolyticresponse in the pathogenesis of fibrin accumulation using PAI-1-,tPA-, and uPA-deficient mice (23). Since microvascular thrombosiscan impede the return of blood flow even after recanalizationof a major vascular territory, alterations in the fibrinolyticbalance can exacerbate ongoing tissue damage and edema formation.Postischemic no-reflow generally consists of multiple effectormechanisms such as neutrophil plugging with enhanced adhesionreceptor expression (52, 53) and microvascular thrombosis.However, our studies point to the protective role of IL-10 likelyto be predominantly due to its effects on fibrin accumulationrather than leukocyte adhesion, since ICAM-1 expression was notsignificantly enhanced in IL-10 null mice compared with IL-10(+/+) mice, leukocyte accumulation was actually less in the IL-10null mice, and an anti-thrombin agent alone sufficed to normalizethe postischemic pulmonary function of IL-10 null mice. Pajkrtet al. (31) have shown that IL-10 not only inhibits activationof coagulation, but IL-10 also modulates the fibrinolytic system(reduced tPA plasmin- $alpha$ ₂-anti-plasmin complexes and D-dimer) duringhuman endotoxemia. The current studies provide the first solidevidence linking a deficiency in IL-10 to the inhibition of fibrinolyticmechanisms, fibrin accrual, and tissue injury followingischemia.

In this study, we have focused primarily on the effect of IL-10 on the regulation of the fibrinolytic system. In vitro, mousemacrophages subjected to hypoxia overexpressed PAI-1 mRNA, theinduction of which was suppressed by exogenous rmIL-10 (data notshown). Although in pathophysiological conditions, IL-1 $alpha$ releasedfrom activated macrophages might stimulate themselves by an autocrineloop to induce PAI-1 expression, it remains unclear whether IL-1 $alpha$ expression is a necessary intermediary in the augmented PAI-1expression seen following lung ischemia. Although IL-1 $alpha$ mightitself promote apoptotic cell death or inflammatory mechanismsof tissue injury, the ability of recombinant hirudin to rescueIL-10 null mice argues against the IL-1 production being criticallydeleterious. On the other hand, inflammatory and activation pathwaysin vivo are intertwined in complex fashion, and it is remotelypossible that hirudin could exert protective effects that areanti-inflammatory-based (thrombin can activate endothelial cellsindependent of its effects on coagulation). Notwithstanding thedifficulties of precisely identifying all pathways involved inin vivo lung I/R injury, the preponderance of the data here suggestthat the accrual of thrombus has a pivotal pathological role.The present results are the first to elucidate that ischemia-drivenendogenous IL-10 might have not only anti-inflammatory effectsbut also regulatory effects on the fibrinolytic system that contributeto the mitigation of postischemic lung tissueinjury.

ACKNOWLEDGEMENTS

We gratefully acknowledge the expert advice provided by Drs. Koichi Kayano and Shi-Du Yan during the course of thesestudies.

	FOOTNOTES

^* This work was supported in part by the U. S. Public Health Service, National Institutes of Health, Grants R01 HL55397, R01HL59488, and R01 60900.The costs of publication of this articlewere defrayed in part by the payment of page charges. The articlemust therefore be hereby marked "advertisement" in accordancewith 18 U.S.C. Section 1734 solely to indicate thisfact.

An Established Investigator of the American Heart Association. To whom correspondence should be addressed: Columbia University,College of Physicians and Surgeons, PH 10 Stem, 630 West, 168thSt., New York, NY 10032. Tel.: 212-305-6071; Fax: 212-305-7638;E-mail djp5@columbia.edu.

ABBREVIATIONS

The abbreviations used are: I/R, ischemia/reperfusion; ICAM-1, intercellular adhesion molecule-1; PAI-1, plasminogen activator inhibitor-1; IL, interleukin; rmIL-10, recombinant murine IL-10; tPA, tissue-type plasminogen activator; uPA, urokinase-type plasminogen activator; ELISA, enzyme-linked immunosorbent assay; PBS, phosphate-buffered saline; sICAM-1, soluble intercellular adhesion molecule-1.

	REFERENCES

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

1.	Naka, Y., Toda, K., Kayano, K., Oz, M. C., and Pinsky, D. J. (1997) Proc. Natl. Acad. Sci. U. S. A. 94, 757-761
2.	Pinsky, D. J. (1995) Thromb. Haemostasis 74, 58-65
3.	Snell, G. I., Rabinov, M., Griffiths, A., Williams, T., Ugoni, A., Salamonsson, R., and Esmore, D. (1996) J. Heart Lung Transplant. 15, 160-168
4.	Naka, Y., Marsh, H. C., Scesney, S. M., Oz, M. C., and Pinsky, D. J. (1997) Transplantation 64, 1248-1255
5.	Chang, D. M., Hsu, K., Ding, Y. A., and Chiang, C. H. (1997) Am. J. Respir. Crit. Care Med. 156, 1230-1234
6.	Colletti, L. M., Remick, D. G., Burtch, G. D., Kunkel, S. L., Strieter, R. M., and Campbell, D. A., Jr. (1990) J. Clin. Invest. 85, 1936-1943
7.	Lo, S. K., Everitt, J., Gu, J., and Malik, A. B. (1992) J. Clin. Invest. 89, 981-988
8.	Mulligan, M. S., Vaporciyan, A. A., Miyasaka, M., Tamatani, T., and Ward, P. A. (1993) Am. J. Pathol. 142, 1739-1749
9.	Weller, A., Isenmann, S., and Vestweber, D. (1992) J. Biol. Chem. 267, 15176-15183
10.	Ward, P. A. (1996) Ann. N. Y. Acad. Sci. 796, 104-112
11.	Kapelanski, D. P., Iguchi, A., Niles, S. D., and Mao, H. Z. (1993) J. Heart Lung Transplant. 12, 294-306
12.	Horgan, M. J., Wright, S. D., and Malik, A. B. (1990) Am. J. Physiol. 259, L315-L319
13.	Choudhri, T. F., Hoh, B. L., Zerwes, H. -G., Prestigiacomo, C. J., Kim, S. C., Connolly, E. S., Jr., Kottirsch, G., and Pinsky, D. J. (1998) J. Clin. Invest. 102, 1301-1310
14.	Huang, J., Kim, L. J., Mealey, R., Marsh, H. C. J., Zhang, Y., Tenner, A. J., Connolly, E. S. J., and Pinsky, D. J. (1999) Science 285, 595-599
15.	Choudhri, T. F., Hoh, B. L., Huang, J., Kim, L. J., Prestigiacomo, C. J., Schmidt, A. M., Kisiel, W., Connolly, E. S., Jr., and Pinsky, D. J. (1999) J. Exp. Med. 190, 91-99
16.	Gilroy, R. J., Jr., Bhatte, M. J., Wickersham, N. E., Pou, N. A., Loyd, J. E., and Overholser, K. A. (1993) Am. Rev. Respir. Dis. 147, 276-282
17.	Fujii, S., Sawa, H., Saffitz, J. E., Lucore, C. L., and Sobel, B. E. (1992) Circulation 86, 2000-2010
18.	Sobel, B. E., Woodcock-Mitchell, J., Schneider, D. J., Holt, R. E., Marutsuka, K., and Gold, H. (1998) Circulation 97, 2213-2221
19.	Handt, S., Jerome, W. G., Tietze, L., and Hantgan, R. R. (1996) Blood 87, 4204-4213
20.	Abrahamsson, T., Nerme, V., Stromqvist, M., Akerblom, B., Legnehed, A., Pettersson, K., and Westin Eriksson, A. (1996) Thromb. Haemostasis 75, 118-126
21.	Fay, W. P., Murphy, J. G., and Owen, W. G. (1996) Arterioscler. Thromb. Vasc. Biol. 16, 1277-1284
22.	Wiman, B. (1995) Thromb. Haemostasis 74, 71-76
23.	Pinsky, D. J., Liao, H., Lawson, C. A., Yan, S. F., Chen, J., Carmeliet, P., Loskutoff, D. J., and Stern, D. M. (1998) J. Clin. Invest. 102, 919-928
24.	Abbas, A. K., Murphy, K. M., and Sher, A. (1996) Nature 383, 787-793
25.	Fiorentino, D. F., Bond, M. W., and Mosmann, T. R. (1989) J. Exp. Med. 170, 2081-2095
26.	de Waal Malefyt, R., Abrams, J., Bennett, B., Figdor, C. G., and de Vries, J. E. (1991) J. Exp. Med. 174, 1209-1220
27.	Cunha, F. Q., Moncada, S., and Liew, F. Y. (1992) Biochem. Biophys. Res. Commun. 182, 1155-1159
28.	Greenberger, M. J., Strieter, R. M., Kunkel, S. L., Danforth, J. M., Goodman, R. E., and Standiford, T. J. (1995) J. Immunol. 155, 722-729
29.	Shanley, T. P., Schmal, H., Friedl, H. P., Jones, M. L., and Ward, P. A. (1995) J. Immunol. 154, 3454-3460
30.	Mulligan, M. S., Jones, M. L., Vaporciyan, A. A., Howard, M. C., and Ward, P. A. (1993) J. Immunol. 151, 5666-5674
31.	Pajkrt, D., van der Poll, T., Levi, M., Cutler, D. L., Affrime, M. B., van den Ende, A., ten Cate, J. W., and van Deventer, S. J. (1997) Blood 89, 2701-2705
32.	Kuhn, R., Lohler, J., Rennick, D., Rajewsky, K., and Muller, W. (1993) Cell 75, 263-274
33.	Rickles, R. J., Darrow, A. L., and Strickland, S. (1988) J. Biol. Chem. 263, 1563-1569
34.	Ranby, M., Norrman, B., and Wallen, P. (1982) Thromb. Res. 27, 743-749
35.	Wiman, B., Mellbring, G., and Ranby, M. (1983) Clin. Chim. Acta 127, 279-288
36.	Francis, C. W., Marder, V. J., and Martin, S. E. (1980) Blood 56, 456-464
37.	Bradford, M. M. (1976) Anal. Biochem. 72, 248-254
38.	Hui, K. Y., Haber, E., and Matsueda, G. R. (1983) Science 222, 1129-1132
39.	Lloyd, C. M., Minto, A. W., Dorf, M. E., Proudfoot, A., Wells, T. N., Salant, D. J., and Gutierrez-Ramos, J. C. (1997) J. Exp. Med. 185, 1371-1380
40.	Loskutoff, D. J., Sawdey, M., Keeton, M., and Schneiderman, J. (1993) Thromb. Haemostasis 70, 135-137
41.	Shatos, M. A., Doherty, J. M., Stump, D. C., Thompson, E. A., and Collen, D. (1990) J. Biol. Chem. 265, 20443-20448
42.	Gertler, J. P., Perry, L., L'Italien, G., Chung-Welch, N., Cambria, R. P., Orkin, R., and Abbott, W. M. (1993) J. Vasc. Surg. 18, 939-945
43.	Wang, C. Y., Naka, Y., Liao, H., Oz, M. C., Springer, T. A., Gutierrez-Ramos, J. C., and Pinsky, D. J. (1998) Circ. Res. 82, 762-772
44.	Jander, S., Pohl, J., D'Urso, D., Gillen, C., and Stoll, G. (1998) Am. J. Pathol. 152, 975-982
45.	Becherel, P. A., LeGoff, L., Frances, C., Chosidow, O., Guillosson, J. J., Debre, P., Mossalayi, M. D., and Arock, M. (1997) J. Immunol. 159, 5761-5765
46.	Lalani, I., Bhol, K., and Ahmed, A. R. (1997) Ann. Allergy Asthma Immunol. 79, 469-483
47.	Autschbach, F., Braunstein, J., Helmke, B., Zuna, I., Schurmann, G., Niemir, Z. I., Wallich, R., Otto, H. F., and Meuer, S. C. (1998) Am. J. Pathol. 153, 121-130
48.	Martinez, J. A., King, T. E., Jr., Brown, K., Jennings, C. A., Borish, L., Mortenson, R. L., Khan, T. Z., Bost, T. W., and Riches, D. W. (1997) Am. J. Physiol. 273, L676-L683
49.	Bonfield, T. L., Konstan, M. W., Burfeind, P., Panuska, J. R., Hilliard, J. B., and Berger, M. (1995) Am. J. Respir. Cell Mol. Biol. 13, 257-261
50.	Seitz, M., Loetscher, P., Dewald, B., Towbin, H., Gallati, H., and Baggiolini, M. (1995) Eur. J. Immunol. 25, 1129-1132
51.	Shatos, M. A., Doherty, J. M., Orfeo, T., Hoak, J. C., Collen, D., and Stump, D. C. (1992) J. Biol. Chem. 267, 597-601
52.	Connolly, E. S., Jr., Winfree, C. J., Prestigiacomo, C. J., Kim, S. C., Choudhri, T. F., Hoh, B. L., Naka, Y., Solomon, R. A., and Pinsky, D. J. (1997) Circ. Res. 81, 304-310
53.	Connolly, E. S., Jr., Winfree, C. J., Springer, T. A., Naka, Y., Liao, H., Yan, S. D., Stern, D. M., Solomon, R. A., Gutierrez-Ramos, J. C., and Pinsky, D. J. (1996) J. Clin. Invest. 97, 209-216

CiteULike

Complore

Connotea

Del.icio.us Add to Digg

Digg

Technorati What's this?

This article has been cited by other articles:

Potentiation of Endogenous Fibrinolysis and Rescue from Lung Ischemia/Reperfusion Injury in Interleukin (IL)-10-reconstituted IL-10 Null Mice*

Potentiation of Endogenous Fibrinolysis and Rescue from Lung Ischemia/Reperfusion Injury in Interleukin (IL)-10-reconstituted IL-10 Null Mice^*