Leukocyte- and endothelial-derived microparticles: a circulating source for fibrinolysis
Romaric Lacroix, Laurent Plawinski, Stéphane Robert, Loïc Doeuvre, Florence Sabatier, Sara Martinez de Lizarrondo, Anna Mezzapesa, Francine Anfosso, Aurelie S. Leroyer, Pascale Poullin, Noémie Jourde, Makon-Sébastien Njock, Chantal M. Boulanger, Eduardo Anglés-Cano, Françoise Dignat-George
Haematologica December 2012 97: 1864-1872; doi:10.3324/haematol.2012.066167

Author Affiliations

  1. Romaric Lacroix1,2,*,
  2. Laurent Plawinski3,4,*,
  3. Stéphane Robert1,
  4. Loïc Doeuvre3,
  5. Florence Sabatier1,2,
  6. Sara Martinez de Lizarrondo3,
  7. Anna Mezzapesa3,
  8. Francine Anfosso1,
  9. Aurelie S. Leroyer1,
  10. Pascale Poullin5,
  11. Noémie Jourde1,6,
  12. Makon-Sébastien Njock1,
  13. Chantal M. Boulanger7,
  14. Eduardo Anglés-Cano3,** and
  15. Françoise Dignat-George1,2,**
  1. 1Aix Marseille Université, INSERM UMR-S1076, UFR de Pharmacie, Marseille, France
  2. 2Laboratoire d'Hématologie et de Biologie Vasculaire, CHU Conception, Marseille, France
  3. 3Inserm, UMR-S919, Université Caen Basse Normandie, Caen, France
  4. 4CNRS, UMS3408, Caen, France
  5. 5Service d'Hémaphérèse, Hôpital de la Conception, APHM, Marseille, France
  6. 6Service de Néphrologie, Hôpital de la Conception, APHM, Marseille, France
  7. 7Inserm, UMR-S970, Paris, France
  1. Correspondence: Françoise Dignat-George, Inserm UMR1076, UFR de Pharmacie, 27 Bd Jean Moulin, 13385-cdx Marseille 5, France. Phone: international +33.4.91835600. Fax: international +33.4.91835602. E-mail: dignat{at}pharmacie.univ-mrs.fr

  1. * RL and LP (alphabetical order) contributed equally to this work.

View Abstract

Abstract

Background We recently assigned a new fibrinolytic function to cell-derived microparticles in vitro. In this study we explored the relevance of this novel property of microparticles to the in vivo situation.

Design and Methods Circulating microparticles were isolated from the plasma of patients with thrombotic thrombocytopenic purpura or cardiovascular disease and from healthy subjects. Microparticles were also obtained from purified human blood cell subpopulations. The plasminogen activators on microparticles were identified by flow cytometry and enzyme-linked immunosorbent assays; their capacity to generate plasmin was quantified with a chromogenic assay and their fibrinolytic activity was determined by zymography.

Results Circulating microparticles isolated from patients generate a range of plasmin activity at their surface. This property was related to a variable content of urokinase-type plasminogen activator and/or tissue plasminogen activator. Using distinct microparticle subpopulations, we demonstrated that plasmin is generated on endothelial and leukocyte microparticles, but not on microparticles of platelet or erythrocyte origin. Leukocyte-derived microparticles bear urokinase-type plasminogen activator and its receptor whereas endothelial microparticles carry tissue plasminogen activator and tissue plasminogen activator/inhibitor complexes.

Conclusions Endothelial and leukocyte microparticles, bearing respectively tissue plasminogen activator or urokinase-type plasminogen activator, support a part of the fibrinolytic activity in the circulation which is modulated in pathological settings. Awareness of this blood-borne fibrinolytic activity conveyed by microparticles provides a more comprehensive view of the role of microparticles in the hemostatic equilibrium.

Key words

Introduction

Microparticles are small vesicles resulting from membrane blebbing of most activated or apoptotic cells. Microparticles derived from blood and vascular cells can be detected in the circulation and over the past decade have become accepted as diagnostic and prognostic biomarkers in cardiovascular and inflammatory diseases, and in cancer.1 Accumulating evidence indicates that beyond their clinical relevance as biomarkers, microparticles also convey various bioactive effectors from the parental cell. Previous in vitro and in vivo studies showed that microparticles propagate a spectrum of biological activities and are involved in many different processes, such as activation of coagulation, inflammation, vascular remodeling and angiogenesis.2-6 They bear tissue factor-dependent procoagulant activity and regulate procoagulant pathways in monocytes.7 They also carry cytokines important for inflammation8,9 and participate in endothelial dysfunction by decreasing the production of nitric oxide.4 Furthermore, it has been shown that endothelial microparticles have matrix metalloproteinase activity on their surface, suggesting that they could participate in extracellular matrix degradation, vascular remodeling and angiogenesis.3

We previously assigned a hitherto unreported fibrinolytic function to microparticles10 and, more recently, we demonstrated that microparticles participate in a newly identified mechanism of fibrinolytic cross-talk.11 In these in vitro studies, performed with microparticles derived from the human microvascular endothelial cell line, HMEC-1, we demonstrated that these endothelial microparticles constitute a catalytic surface for efficient activation of plasminogen by the urokinase-type plasminogen activator (uPA) anchored to its receptor, uPAR.10 Interestingly, these microparticles may also activate plasminogen bound to fibrin, extracellular matrix proteins or platelets.11 The possibility that circulating microparticles also serve as a template for plasmin formation and fibrinolytic activity in vivo and their cellular origin remain unsolved issues that are the object of the present study.

Design and Methods

Isolation of microparticles from human plasma

Platelet-poor plasma was separated (1500 g, 15 min) from blood collected into 0.119 M sodium citrate from healthy volunteers (n=36) and from patients with systemic lupus erythematosus (n=22), diagnosed according to the American College of Rheumatology criteria,12 or with atherosclerotic complications (n=16) involved in a previous study.13 Citrated plasma was also obtained by plasmapheresis from patients suffering from acute thrombotic thrombocytopenic purpura (TTP, n=10). Informed consent was obtained from all patients according to the Declaration of Helsinki.

Microparticles were isolated by sequential centrifugation of platelet-poor plasma, first at 12000 g for 2 min to remove residual platelets. The platelet-free plasma was then centrifuged at 20000 g for 90 min at 4°C. Centrifugation at 100000 g, used in some studies, was avoided to prevent concomitant sedimentation of exosomes, a different type of membrane vesicles.14,15 Pelleted microparticles were washed twice (20000 g for 90 min at 4°C) and re-suspended in phosphate-buffered saline. In some experiments, circulating microparticles were depleted of erythrocyte and platelet microparticles by magnetic immuno-separation using beads coated with CD41 and CD235a antibodies. Flow cytometry was used to confirm that these two types of microparticles had been removed (with a reduction of least 90%) (Online Supplementary Data, Section I, Figure S1). Control experiments were performed in parallel using beads coated with irrelevant antibodies.

Generation of microparticles from blood cells

To investigate which subtype of circulating microparticles may support plasminogen activation activity, microparticles were generated in vitro from purified blood cell types. For this purpose, whole blood from healthy volunteers or patients, who had not taken anti-platelet medication for at least 2 weeks, was collected into 0.119 sodium citrate tubes.

Human platelets, prepared as described elsewere,16 were incubated with 1 NIH U/mL of thrombin and/or 1 μM of ionophore A23187 (Sigma, St. Louis, MO, USA), and/or 10 μg/mL of collagen (Stago, Asnière, France), for 15 min at 37°C without stirring. Platelets were subsequently pelleted by centrifugation, first at 1500 g for 15 min and then, after the residual platelets had been discarded, by centrifugation at 12000 g for 2 min. The microparticles were then isolated from the supernatant and washed as described above. Flow cytometry, was used to check that the purity was superior to 95%.

Erythrocyte microparticles were generated as previously described by Salzer et al. with minor modifications.17 Red blood cells pelleted at 200 g for 10 min and subsequently washed in sodium chloride 0.9%, were suspended in nine volumes of phosphate-buffered saline containing 1 mM CaCl2 and 5 μM of A23187 and incubated at 37°C for 30 min. Erythrocytes were subsequently separated by centrifugation at 12000 g for 2 min, and the microparticles were isolated and washed as described above. Flow cytometry was used to check that the purity was superior to 95%.

Leukocyte microparticles were prepared as previously described with minor modifications.18 Peripheral blood mononuclear cells were isolated from buffy coats by Ficoll™ (Lymphocyte separation medium 1077). Monocytes were isolated by CD14+ immuno-magnetic separation on magnetic sphere columns (Miltenyi Biotec, Bergish Gladbach, Germany). Flow cytometry was used to check that the purity was superior to 95%. Monocytes were stimulated by lipopolysaccharides (1 μg/mL) overnight. Vesiculation was evaluated by flow cytometry using staining with annexin A5-fluorescein isothyiocyanate (FITC)/CD11b. Neutrophils were purified from buffy coats and were stimulated by N-formylmethionylleucyl-phenylalanine (1 μM) for 2 h at 37°C. Lymphocytes were purified from blood mononuclear cells and were stimulated by platelet-activating factor 500 nM/ phorbol 12-myristate 13-acetate 50 nM for 2 h at 37°C. Microparticles were isolated and washed as described above.

Generation and harvesting of microparticles from endothelial cells

Several subtypes of human endothelial cells originating from distinct vascular beds were purchased from Clonetics (Grand Island, NY, USA) and cultured in 0.2% gelatin-coated flasks in EGM2-MV medium: renal artery endothelial cells were used at passage 8, coronary artery endothelial cells at passage 7 and both dermal human microvascular vein endothelial cells and human pulmonary artery endothelial cells at passage 6. Endothelial microparticles were purified from culture medium conditioned by sub-confluent endothelial cells stimulated or not with 10 ng/mL tumor necrosis factor-α (PeproTech Inc, Rocky Hill, NJ, USA) for 24 h, as previously described with some modifications.19 Culture supernatants were centrifuged at 300 g for 5 min and at 2500 g for 10 min to remove detached cells and debris. The microparticles were isolated as described above, washed twice and re-suspended in HEPES buffer.

Characterization of microparticles by flow cytometry and enzyme-linked immunosorbent assays

Aliquots (10 μL) of microparticle suspensions, diluted 1/10, were labeled using FITC-conjugated annexin A5 (Abcys, Paris, France) or specific monoclonal antibodies. Phycoerythrin (PE)-labeled anti-CD41, FITC anti-CD31, PE anti-CD11b and PE anti-CD235a were from Beckman Coulter (Marseille, France). Flow cytometry analysis (Online Supplementary Data Section II, Figure S2) was performed on a Cytomics FC500® instrument (Beckman Coulter, Miami, FL, USA). Microparticles were analyzed as previously described.20,21

The presence of uPA, uPAR and tissue plasminogen activator (tPA) was evaluated by flow cytometry using FITC-labeled antibodies on microparticles gated according to positivity for CD146-PE (endothelial microparticles), CD59-PE (endothelial, erythrocyte and leukocyte microparticles) or CD41-PE (platelet microparticles) (Online Supplementary Figure S3). Antibodies matched for protein concentration and fluorescence/protein ratio were used as controls.

Pelleted microparticles were lysed in 100 mM Tris-HCl buffer pH 8.1, containing 0.5% Triton X-100 and supplemented with a mixture of complete protease inhibitors (Roche Diagnostic GmbH, Mannheim, Germany). Concentrations of uPA and uPAR were assayed by enzyme-linked immunosorbent assay (ELISA) (894 and 893 IMUBIND® ELISA kits, American Diagnostica, Greenwich, CT, USA) according to the manufacturer's instruction. The results are expressed as nanograms of protein per 106 microparticles. The tPA and plasminogen activator inhibitor type-1 (PAI 1) content were measured by ELISA (Asserachrom® tPA and Asserachrom® PAI-1, Diagnostica Stago, Asnière, France). These results are also expressed as nanograms of protein per 106 microparticles.

Determination of plasminogen activators, plasminogen activation and fibrinolytic activity on microparticles

The presence and identity of plasminogen activators and their inhibitors borne by microparticles were analyzed by direct and reverse fibrin autography following sodium dodecylsulphate polyacrylamide gel electrophoresis (SDS-PAGE) performed as described previously.22 Briefly, microparticles were lysed in 100 mM Tris-HCl buffer, pH 8.1, containing 1% Triton X-100. Microparticle lysates (10 μL from 2×105 microparticles) and reference proteins (10 μL of tPA 5 nM, uPA 1 nM and plasmin 500 nM) were electrophoresed in a 7.5% polyacrylamide gel under non-reducing conditions. SDS was then exchanged with 2.5% Triton X-100. After washing off excess Triton X-100 with distilled water, the gel was carefully overlaid on a 1% agarose gel containing 1 mg/mL bovine fibrinogen, 100 nM plasminogen and 0.2 NIH U/mL of bovine thrombin. For reverse fibrin zymography, the fibrin gel was supplemented with 0.05 IU/mL of urokinase. Zymograms were allowed to develop at 37°C for 24 h and photographed at regular intervals using dark-ground illumination. Active proteins in microparticle lysates were identified by reference to the migration of known markers (uPA, tPA, plasmin). When required the fibrin-agarose indicator gel was supplemented with antibodies (10 μg/mL) directed against specific plasminogen activators.

The capacity of microparticles to activate plasminogen was determined by incubating a fixed concentration of plasminogen (1 μM) with the microparticles in the presence of a chromogenic substrate selective for plasmin (CBS 0065, 0.75 mM final concentration), as described previously.10 Plasmin formed from plasminogen bound at the surface of microparticles cleaves the chromogenic substrate and the released p-nitroaniline is detected by measuring A405nm as a function of time. Results are expressed in A405nm×10-3/min. When indicated, the following inhibitors were pre-incubated with the microparticles: 10 μg/mL goat anti-human tPA (Biopool, Uppsala, Sweden), 20 μg/mL mouse anti-human uPA (American Diagnostica 3940), and respective irrelevant control IgGs (Biocytex, Marseille, France); amiloride and ɛ-aminocaproic acid (Sigma-Aldrich) were used at the final concentrations of 100 μM and 0.05 M, respectively.

To scale the degree of plasmin formation by microparticles, standard curves, constructed with reference microparticles (200000 per 50 μL) bearing known molar amounts of uPA or tPA (THP1- or CHO-derived microparticles, respectively), were used (Online Supplementary Data Section III, Figures S4 and S5).

The fibrinolytic activity of microparticle-free plasma from patients and controls was estimated by measuring the amount of plasmin formed on a fibrin surface in contact with the plasma euglobulin fraction in the presence of CBS 0065 (0.75 mM final concentration).23

Statistical analysis

Statistical analysis was performed with KaleidaGraph software (Synergy Software, Reading, PA, USA). Significant differences were determined using the non-parametric Mann-Whitney test. A P value less than 0.05 was considered statistically significant.

Results

In vivo evidence of blood-borne fibrinolytic activity supported by microparticles: identification of plasminogen activators

To investigate the possibility that blood-borne microparticles may be involved in plasmin generation under conditions occurring in vivo, we studied microparticles from healthy controls and patients with pathological states reported to be associated with increased microparticle concentration, namely atherosclerotic vascular disease (n=16) and systemic lupus erythematosus (n=22). Microparticles were isolated by centrifuging platelet-free plasma at 20000 g for 90 min. Thus, none of the experiments presented in this paper included exosomes and all concern exclusively microparticles, as indicated by nanoparticle tracking analysis (Online Supplementary Data Section IV, Figure S6). As illustrated in Figure 1, it was possible to detect varying levels of plasminogen activator activity on microparticles in both controls and patients. Interestingly, the plasminogen activator activity of microparticles was significantly higher in the two groups of patients compared to healthy controls [median (25th-75th percentiles): 1.2 (0.6-1.93) mOD/min and 0.87 (0.61-1.59) mOD/min versus 0.5 (0.4-0.6) mOD/min, P<0.003 and P<0.007, respectively). However, about 50% of patients had a plasminogen activator activity similar to that in healthy controls.

Figure 1.
Figure 1.

Plasmin generated by circulating microparticles from patients with cardiovascular disease (CVD), systemic lupus erythematosus (SLE) and healthy controls (HC). Microparticles (2×105/well) were isolated as indicated in the Design and Methods section and then incubated with plasminogen (1 μM) in the presence of a plasmin-selective chromogenic substrate (CBS 0065, 0.75 mM). Dots represent the amount of plasmin formed (mOD/min). Results represent the median (25th-75th percentile) of a duplicated experiment. The median for each category is represented by the dotted lines. ● CVD 1.2 (0.6-1.93) mOD/min and ■ SLE 0.87 (0.61-1.59) mOD/min versus ✵ HC 0.5 (0.4-0.6) mOD/min, *P<0.01.

The nature of plasminogen activators involved in the fibrinolytic activity was analyzed using samples obtained by plasmapheresis from patients with acute TTP, a pathological situation in which there is increased vesiculation.24,25 Plasmapheresis has the advantage over classical blood sampling of providing sufficient amounts of plasma for microparticle isolation and extensive characterization. All isolated microparticle samples (n=10) generated plasmin activity upon incubation with 1 μM plasminogen. Figure 2A shows plasmin generation (0.7-5.9 mOD/min) in TTP samples (2×105 microparticles/well) which display variable plasminogen activator activity (control in the absence of microparticles: 0.015 mOD/min). The inhibition of plasminogen binding and plasmin generation by ɛ-aminocaproic acid was consistent with a lysine-dependent mechanism for plasminogen binding and activation at the surface of the microparticles (Figure 2B). The plasminogen activator activity in distinct samples (Figure 2C upper panel) was identified as uPA (TTP 6) or tPA (TTP 7) in fibrin-agarose gels, as indicated by the position of their fibrinolytic bands relative to known markers. For instance, the single fibrinolytic band visible in sample TTP 6 and the corresponding uPA standard were absent in a fibrin-agarose gel containing anti-uPA antibodies (Figure 2C, lower panel). This antibody also inhibited plasmin formation by microparticles from TTP 4 in a chromogenic assay (Figure 2B). The microparticle sample TTP 7 in Figure 2C produced fibrinolytic bands of increased intensity corresponding to the position of uPA, tPA and tPA in complex with its inhibitor. The uPA fibrinolytic band did not appear in the presence of anti-uPA antibodies whereas tPA and its complexes retained their activity (Figure 2C, lower panel). In two additional TTP samples it was possible to quantify the molar activity of plasminogen activators on 2×105 microparticles/50 μL (tPA: 1.93 and 0.84 pM; uPA 1.5 and 0.83 pM). For this purpose we used reference microparticles bearing known molar concentrations of either tPA or uPA and amiloride to resolve tPA activity (Online Supplementary Data Section III). Free tPA and tPA in complex with its inhibitor were also identified in samples from patients with systemic lupus erythrematosus (Online Supplementary Data Section V, Figure S7). These results provide the first evidence that human circulating microparticles carry plasminogen activators and activate membrane-bound plasminogen. These ex vivo data suggest that blood-borne microparticles may generate and disseminate plasmin activity in vivo.

Figure 2.
Figure 2.

Plasmin generation and fibrinolytic activity of microparticles isolated from patients with thrombotic thrombocytopenic purpura (TTP). (A) Plasmin generation by ten samples of microparticles from patients with TTP. Experiments were performed as indicated in Figure 1. Results are given in mOD/min (mean±SD). (B) Effect of inhibitors (100 mM ɛ-aminocaproic acid, ɛ-ACA and 20 μg/mL anti-uPA antibody, α-uPA) and IgG, a control immunoglobulin, on plasmin generation by four samples of microparticles from patients with TPP. Experiments performed as indicated in Figure 1. Results are given in mOD/min (mean±SD). (C) Fibrin-zymography analysis of microparticles from patients with TTP Proteins in microparticle lysates were separated by SDS-PAGE and their fibrinolytic activity revealed on fibrin-agarose gels. Reference standards are: purified tPA, plasmin (Pn) and uPA. The fibrinolytic activity was tested in the absence (-, upper panel) or presence (+, lower panel) of 10 μg/mL of a polyclonal antibody against uPA. The high molecular weight fibrinolytic band observed in the purified tPA standard lane corresponds to tPA dimers.50

The fibrinolytic activity in circulating blood is borne by leukocyte- and endothelium-derived microparticles

To explore the fibrinolytic activity of microparticles further, we determined the cellular origin of the microparticles with plasminogen activator activity. We first performed experiments using specific antibodies coated on magnetic beads to deplete platelet and erythrocyte microparticles, the major subpopulations of circulating microparticles, from the samples. After this procedure, the residual platelet and erythrocyte microparticles constituted only about 10% of the microparticles in the depleted samples (Figures 3A, 3B). The predominant subpopulations of endothelial and leukocyte microparticles in the depleted sample generated significantly more plasmin formation compared to the non-depleted sample (Figure 3C). These data suggest that: (i) endothelial and leukocyte microparticles provide the real support to plasminogen activator activity, and (ii) platelet and erythrocyte microparticles do not contribute to the fibrinolytic activity of microparticles isolated from circulating blood. Of note, platelets and platelet microparticles bear active PAI-1 (Figure 3D). Thus, the unexpected increase in plasmin formation observed in the depleted samples was probably related to the absence of platelet microparticles bearing active PAI-1.

Figure 3.
Figure 3.

Platelet- and erythrocyte-derived microparticles do not exhibit fibrinolytic activity. (A) Immuno-phenotyping monitoring of platelet microparticles (annexin A5-FITC+/CD41-PE+) and erythrocyte microparticles (annexin A5-FITC+/CD235a-PE+) before and after immuno-magnetic depletion (representative experiment). Left panels show microparticle content after non-specific immuno-magnetic separation (immunomagnetic separated control). Right panels show microparticle content after anti-CD41/CD235a immunomagnetic separation. (B) Efficiency of the immunomagnetic depletion in microparticles of platelet and erythrocyte origin (right panel, n=3, 11.9±1.43%, P<0.05) expressed as a percentage of the non-depleted samples (left panel). (C) Plasmin generation by microparticles in depleted and non-depleted samples. Left bar shows activity of the non-depleted sample compared to the activity, right bar, of the sample depleted of erythrocyte and platelet microparticles (145±11%, P<0.05). An equal volume of 25 μL of depleted and non-depleted microparticle samples was tested. (D) Reverse fibrin-zymography analysis of platelet microparticles. Proteins in platelet microparticle lysates (20 μg) and non-activated platelets (80 μg) were separated by SDS-PAGE and their plasminogen activator inhibitory activity was revealed on a fibrin-agarose gel containing urokinase (0.025 IU/mL). The reference standard is purified recombinant PAI-1 (80 ng). Representative samples are shown.

To identify which plasminogen activators are borne specifically by microparticles of endothelial and leukocyte origin, we studied the fibrinolytic activity of isolated microparticles (2×105/well) derived from distinct purified blood cell subpopulations and from primary human endothelial cells.

Endothelial-derived microparticles

Plasmin generation was detected on endothelial microparticles with variations according to their anatomical origin (Figure 4A). The greatest and least fibrinolytic activities were displayed by endothelial microparticles of renal artery (1.2±0.2 mOD/min) and dermal microvascular origin (0.03±0.01 mOD/min), respectively. By zymography, two fibrinolytic bands resistant to anti-uPA antibodies were observed in endothelial microparticle lysates (Figure 4B). The lower band corresponded to the migration of purified tPA whereas the top band, of higher molecular weight, corresponded to the migration of tPA in complex with its inhibitor (Cs in Figure 4B), in agreement with previous findings.22 Consistent with this observation, significant levels of PAI-1 antigen were detected in lysates of endothelial microparticles with a specific ELISA (Figure 4C). The presence of tPA was further confirmed by ELISA (Figure 4D) and by flow cytometry (Online Supplementary Figure S3), whereas uPA activity and antigen were undetectable. The molarity of active tPA borne by endothelial microparticles was determined by reference to standard microparticles bearing known molar amounts of tPA (Table 1).

Figure 4.
Figure 4.

Plasminogen activators and fibrinolytic activity of human circulating blood cell- and primary endothelial cell-derived microparticles. Microparticles derived from circulating human platelets, leukocytes and erythrocytes, and from primary cultures of human endothelial cells were prepared and isolated as indicated in the Design and Methods section. Endothelial microparticles were obtained from primary cultures of coronary artery (CA), pulmonary artery (PA), renal artery (RA) and dermal microvascular (DMV) endothelial cells. Circulating blood cell-derived microparticles were obtained from isolated polymorphonuclear cells (PMN), monocytes (MC), lymphocytes (LC), red cells (RC) and platelets (PLA). (A) Plasmin generation by microparticles (2×105/well) was tested as indicated in Figure 1. Bars represent the amount of plasmin formed (mOD/min). Results are the mean±SD of duplicate experiments (n=3). (B) Fibrin-zymography analysis of endothelial and circulating microparticles. Zymography was performed as indicated in the Design and Methods section. Reference standards were purified tPA, plasmin (Pn), uPA and tPA in complex with PAI-1 (Cs). Representative samples are shown. (C) Concentration of PAI-1 as determined by ELISA in cell-derived microparticle lysates (106 endothelial microparticles per well). Results are the mean±SD of duplicate experiments. (D) Concentration of uPAR and tPA determined by ELISA in cell-derived microparticle lysates (106 endothelial microparticles per well). Results are the mean±SD of duplicate experiments.

View this table:
Table 1.

tPA activity on endothelial cell-derived microparticles.

Leukocyte-derived microparticles

Plasminogen activator activity was also detected on leukocyte microparticles of monocyte, lymphocyte and neutrophil origin (Figure 4A). The presence of such activity on leukocyte microparticles was further confirmed by a lytic band on zymography corresponding to the position of uPA (Figure 4B), which was absent in the presence of antibodies to uPA (data not shown). Flow cytometry (Online Supplementary Figure S3) and ELISA (Figure 4D) allowed detection of uPA and its receptor uPAR on the surface of leukocyte microparticles. In a parallel experiment, tPA antigen was undetectable on leukocyte microparticles (Online Supplementary Figure S3). The molarity of uPA borne by leukocyte microparticles was calculated using reference standard microparticles bearing known molar amounts of uPA (Table 2).

View this table:
Table 2.

uPA activity on leukocyte-derived microparticles.

Platelet- and erythrocyte-derived microparticles

Both platelet microparticles and erythrocyte microparticles (up to 5×106 microparticles/well) failed to generated plasmin (Figure 4A) or fibrinolytic bands (Figure 4B). Accordingly, depletion of erythrocyte- and platelet-derived microparticles did not decrease the fibrinolytic activity of microparticles isolated from plasma (Figure 3C). Similar negative results regarding plasminogen activator activity were obtained when platelet microparticles were generated using different platelet agonist combinations (collagen, thrombin and A23187; data not shown). Flow cytometry experiments also failed to detect uPA or tPA antigens on platelet- or erythrocyte- derived microparticles (Online Supplementary Figure S3).

Collectively, these results indicate that active plasminogen activators expressed by endothelial cells and leukocytes (tPA and uPA, respectively) are conveyed in circulating blood by endothelial and leukocyte microparticles.

Discussion

Using the human microvascular endothelial cell line HMEC-1,26 we previously reported that endothelial microparticles have fibrinolytic activity in vitro and participate in a fibrinolytic crosstalk.10,11 However, the relevance of this model to fibrinolysis in vivo and whether microparticles derived from all circulating cell types support plasminogen activation remained unsolved questions that were addressed in the present study. First, we provided the proof of concept that microparticles produced in vivo support fibrinolysis as indicated by the formation of active plasmin on microparticles isolated from the blood of healthy subjects and patients with vascular diseases. Secondly, we showed that specific plasminogen activators on endothelial and leukocyte microparticles generate this fibrinolytic activity, whereas erythrocyte and platelet vesicles do not have this property. Thirdly, the plasminogen activators were identified as uPAR-bound uPA, on leukocyte microparticles, and tPA on endothelial microparticles. This study has, therefore, contributed to identifying new partners of blood-borne fibrinolytic activity.

We also provided evidence that microparticles with fibrinolytic activity are found at very low concentrations in healthy subjects whereas various levels of plasmin formation were found in different pathological situations (atherosclerosis, systemic lupus erythematosus and TTP). This varying level of ex vivo fibrinolytic activity reflects different amounts of active plasminogen activator borne by microparticles whereas the plasminogen activator activity of microparticle-free plasma was negligible, as reported previously.23 The significance of these findings with regard to clinical status remains to be established in future studies. Nevertheless, we have revealed the existence of a microparticle-dependent profibrinolytic compensatory mechanism that may counterbalance the procoagulant phenotype and reduce the thrombotic risk in these patients.24,27-29 These interesting features lay the basis for a potential new biomarker.

To identify microparticles that bear these plasminogen activators, we studied microparticle subpopulations released by primary endothelial cells in culture or by properly stimulated platelets, red cells and leukocytes isolated from circulating human blood. We provide here the first demonstration that plasminogen activators are borne in a selective manner by a minor fraction of microparticles circulating in human blood: endothelial microparticles carry tPA and leukocyte microparticles carry uPA/uPAR. This selectivity contrasts with the well-described procoagulant potential common to all microparticles.30 Interestingly, we found various levels of fibrinolytic microparticles in differents pathological situations (atherosclerosis, systemic lupus erythematosus, TTP) that have been reported to be associated with increased levels of leukocyte and endothelial microparticles.13,19,27,28,31-34 This fibrinolytic activity may reflect pathophysiological leuko-endothelial activation associated with inflammation, which could help to identify patients with a higher individual vascular risk in these clinical situations. Of note, leukocyte and endothelial microparticles are among the circulating subsets least accessible by current methodologies, such as flow cytometry, because of their low proportion, size distribution and limited specific markers. Thus, the measurement of this circulating fibrinolytic activity could provide additional, innovative information compared to that provided simply by the counts of these microparticle subsets.

The study of microparticle samples from patients with TTP demonstrated that plasmin may be generated by either uPA or tPA. By combining a set of tests (chromogenic, zymography, ELISA) and flow cytometry, we demonstrated that this activity was exclusive to microparticle subsets derived from leukocytes (expressing uPA) or endothelial cells (expressing tPA). These distinctive characteristics may be used advantageously to identify the origin of the plasmin generating capacity of circulating microparticles in patients. The presence of uPA on microparticles derived from the human microvascular endothelial cell line HMEC-1 described in our previous report10 was due to the atypical synthesis of this plasminogen activator by the modified cell line, which was used as a model to generate microparticles after tumor necrosis factor-α stimulation.

In contrast to uPA-bearing microparticles derived from circulating leukocytes and tPA-bearing microparticles derived from human primary endothelial cells, we did not detect plasmin generation on erythrocyte or platelet microparticles. Accordingly, plasminogen activators have not been described on red blood cells and their expression by human platelets has not been clearly demonstrated, except for the ectopic production of uPA in the platelet Quebec syndrome.35 It is, however, possible that platelet microparticles may, in some cases, develop plasminogen activator activity. Indeed, since platelets bind plasminogen,36-38 platelet microparticles may be a source of substrate for enhanced fibrinolysis by single-chain uPA39 via a fibrinolytic crosstalk mechanism we demonstrated recently.11 However, active PAI-1/vitronectin complexes present in platelets40 and active PAI-1 detected in platelet microparticles as shown in this study, may modulate this fibrinolytic activity. Given that both platelet and erythrocyte microparticle subpopulations account for the bulk of circulating microparticles,13 it was relevant to demonstrate the effect of their depletion from the pool of microparticles isolated from plasma. The unexpected increased fibrinolytic activity generated by the depleted samples may reflect the absence of platelet microparticles bearing active PAI-1.

Thus, we found that microparticles of endothelial and leukocyte origin are the main sources of the plasmin generating capacity on microparticles in human plasma. However, in pathological settings, it remains possible that microparticles from other origins may have proteolytic activity in plasma. For instance, tumor microparticles were proven to circulate and have been associated with thrombosis due to the tissue factor they convey.41,42 Microparticles from tumor cell lines and from ascites of cancer origin were found to bear vesicle-associated proteolytic activity represented by matrix metalloproteinases 2 and 9 and plasminogen activators.43-47 The discovery of fibrinolytic microparticles that circulate in human plasma raises the possibility of detecting such activity in some patients with cancer, with potential diagnostic relevance or prognostic value in metastatic evolution.

Beyond fibrinolysis, plasmin formation by microparticles bearing the uPA/uPAR system may participate, in concert with matrix metalloproteinases, in other proteolytic functions.48 Thus, the proteolytic activity of uPA-bearing microparticles may be of relevance in cell migration, angiogenesis and outside-in signal transduction. Indeed, we have previously shown that tube formation was stimulated by low concentrations of microparticles,10 an effect that was related to crosstalk activation of plasminogen present in the Matrigel.49 This pro-angiogenic effect is consistent with plasmin-associated proteolytic activity that favors cell migration via extracellular matrix processing. The role of microparticle-bound plasmin in pathological settings involving inflammation, atherosclerosis and angiogenesis remains to be investigated. The high concentration of microparticles reported in atherosclerotic plaques suggests that plasmin generation on microparticles could participate in the modulation of the cell apoptosis/angiogenesis balance influencing plaque vulnerability.

In summary, our study indicates that: (i) circulating human microparticles display a range of plasmin generation in various pathological conditions, (ii) this activity is specifically generated by tPA on endothelial microparticles and by uPA on leukocyte microparticles, and (iii) these microparticles support blood fibrinolytic activity. We have provided the first evidence that surface plasminogen activation is a functional feature of plasma microparticles and differs significantly differ between healthy subjects and subjects with various diseases. Collectively, these results suggest that the presence of profibrinolytic microparticles during clot formation anticipates their potential for clot lysis.

The existence of profibrinolytic microparticles in the circulation raises the question about the physiological relevance of this activity. Our data suggest that pro-fibrinolytic microparticles may compensate the effect of procoagulant microparticles. Further studies will be necessary to correlate the procoagulant versus the fibrinolytic effects of microparticles with the clinical status of patients. Awareness of this microparticle blood-borne fibrinolytic activity not only provides a more comprehensive view of the role of these microparticles in the hemostatic equilibrium but also lays the basis for a potential new biomarker.

Acknowledgments

the authors would like to thank Philippe Poncelet and Tarik Bouriche, BioCytex company, Marseille, France for immuno-magnetic separation experiments, Dr. Christophe Dubois for his help with the isolation of human platelets and Dr. Laurent Chiche, Department of Internal Medecine, CHU Conception, Marseille, France as a clinical advisor.

Funding: Pr. Denis Vivien (Director U919) and F Dignat George provided financial support from Inserm and Aix Marseille University (FDG). EAC is the recipient of a “Contrat d'interface” Inserm- Caen University Hospital.

Footnotes

  • ** FD-G and EA-C are corresponding authors and share senior authorship.

  • Eduardo Anglés-Cano, Inserm U765, Faculté de Sciences Pharmaceutiques et Biologiques, 4, Avenue de l'Observatoire, 75270-cdx 06, Paris, France. Phone : international +33.1.53739636 Fax : international +33.1.44071772 E-mail: Eduardo.Angles-Cano{at}inserm.fr

  • The online version of this article has a Supplementary Appendix.

  • Authorship and Disclosures: The information provided by the authors about contributions from persons listed as authors and in acknowledgments is available with the full text of this paper at www.haematologica.org.

  • Financial and other disclosures provided by the authors using the ICMJE (www.icmje.org) Uniform Format for Disclosure of Competing Interests are also available at www.haematologica.org.

  • Received March 14, 2012.
  • Revision received May 17, 2012.
  • Accepted June 13, 2012.

References

  1. 1.
    1. Piccin A,
    2. Murphy WG,
    3. Smith OP
    . Circulating microparticles: pathophysiology and clinical implications. Blood Rev. 2007; 21(3):157-71.
    OpenUrlCrossRefPubMedWeb of Science
  2. 2.
    1. Sabatier F,
    2. Darmon P,
    3. Hugel B,
    4. Combes V,
    5. Sanmarco M,
    6. Velut JG,
    7. et al
    . Type 1 and type 2 diabetic patients display different patterns of cellular microparticles. Diabetes. 2002;51(9):2840-5.
    OpenUrlAbstract/FREE Full Text
  3. 3.
    1. Taraboletti G,
    2. D'Ascenzo S,
    3. Borsotti P,
    4. Giavazzi R,
    5. Pavan A,
    6. Dolo V
    . Shedding of the matrix metalloproteinases MMP-2, MMP-9, and MT1-MMP as membrane vesicle-associated components by endothelial cells. Am J Pathol. 2002;160(2):673-80.
    OpenUrlCrossRefPubMedWeb of Science
  4. 4.
    1. Boulanger CM,
    2. Scoazec A,
    3. Ebrahimian T,
    4. Henry P,
    5. Mathieu E,
    6. Tedgui A,
    7. et al
    . Circulating microparticles from patients with myocardial infarction cause endothelial dysfunction. Circulation. 2001;104(22):2649-52.
    OpenUrlAbstract/FREE Full Text
  5. 5.
    1. MacKenzie A,
    2. Wilson HL,
    3. Kiss-Toth E,
    4. Dower SK,
    5. North RA,
    6. Surprenant A
    . Rapid secretion of interleukin-1beta by microvesicle shedding. Immunity. 2001;15(5):825-35.
    OpenUrlCrossRefPubMedWeb of Science
  6. 6.
    1. Mause SF,
    2. von Hundelshausen P,
    3. Zernecke A,
    4. Koenen RR,
    5. Weber C
    . Platelet microparticles: a transcellular delivery system for RANTES promoting monocyte recruitment on endothelium. Arterioscler Thromb Vasc Biol. 2005;25(7):1512-8.
    OpenUrlAbstract/FREE Full Text
  7. 7.
    1. Sabatier F,
    2. Roux V,
    3. Anfosso F,
    4. Camoin L,
    5. Sampol J,
    6. Dignat-George F
    . Interaction of endothelial microparticles with monocytic cells in vitro induces tissue factor-dependent procoagulant activity. Blood. 2002;99(11):3962-70.
    OpenUrlAbstract/FREE Full Text
  8. 8.
    1. Distler JH,
    2. Distler O
    . Inflammation: microparticles and their roles in inflammatory arthritides. Nat Rev Rheumatol. 2010;6(7):385-6.
    OpenUrlCrossRefPubMed
  9. 9.
    1. Morel O,
    2. Morel N,
    3. Jesel L,
    4. Freyssinet JM,
    5. Toti F
    . Microparticles: a critical component in the nexus between inflammation, immunity, and thrombosis. Semin Immunopathol. 2011;33(5):469-86.
    OpenUrlCrossRefPubMed
  10. 10.
    1. Lacroix R,
    2. Sabatier F,
    3. Mialhe A,
    4. Basire A,
    5. Pannell R,
    6. Borghi H,
    7. et al
    . Activation of plasminogen into plasmin at the surface of endothelial microparticles: a mechanism that modulates angiogenic properties of endothelial progenitor cells in vitro. Blood. 2007;110(7):2432-9.
    OpenUrlAbstract/FREE Full Text
  11. 11.
    1. Dejouvencel T,
    2. Doeuvre L,
    3. Lacroix R,
    4. Plawinski L,
    5. Dignat-George F,
    6. Lijnen HR,
    7. et al
    . Fibrinolytic cross-talk: a new mechanism for plasmin formation. Blood. 2010;115(10):2048-56.
    OpenUrlAbstract/FREE Full Text
  12. 12.
    1. Hochberg MC
    . Updating the American College of Rheumatology revised criteria for the classification of systemic lupus erythematosus. Arthritis Rheum. 1997;40(9):1725.
    OpenUrlCrossRefPubMedWeb of Science
  13. 13.
    1. Leroyer AS,
    2. Isobe H,
    3. Leseche G,
    4. Castier Y,
    5. Wassef M,
    6. Mallat Z,
    7. et al
    . Cellular origins and thrombogenic activity of microparticles isolated from human atherosclerotic plaques. J Am Coll Cardiol. 2007;49(7):772-7.
    OpenUrlCrossRefPubMedWeb of Science
  14. 14.
    1. Dignat-George F,
    2. Freyssinet JM,
    3. Key NS
    . Centrifugation is a crucial step impacting microparticle measurement. Platelets. 2009; 20(3):225-6; author reply 7-8.
    OpenUrlCrossRefPubMedWeb of Science
  15. 15.
    1. Thery C,
    2. Amigorena S,
    3. Raposo G,
    4. Clayton A
    . Isolation and characterization of exosomes from cell culture supernatants and biological fluids. Curr Protoc Cell Biol. 2006;Chapter 3: Unit 3.22.
  16. 16.
    1. Dubois C,
    2. Steiner B,
    3. Kieffer N,
    4. Reigner SC
    . Thrombin binding to GPIbalpha induces platelet aggregation and fibrin clot retraction supported by resting alphaIIbbeta3 interaction with polymerized fibrin. Thromb Haemost. 2003;89(5):853-65.
    OpenUrlPubMed
  17. 17.
    1. Salzer U,
    2. Hinterdorfer P,
    3. Hunger U,
    4. Borken C,
    5. Prohaska R
    . Ca(++)-dependent vesicle release from erythrocytes involves stomatin-specific lipid rafts, synexin (annexin VII), and sorcin. Blood. 2002;99(7):2569-77.
    OpenUrlAbstract/FREE Full Text
  18. 18.
    1. Cerri C,
    2. Chimenti D,
    3. Conti I,
    4. Neri T,
    5. Paggiaro P,
    6. Celi A
    . Monocyte/macrophage-derived microparticles up-regulate inflammatory mediator synthesis by human airway epithelial cells. J Immunol. 2006;177(3):1975-80.
    OpenUrlAbstract/FREE Full Text
  19. 19.
    1. Combes V,
    2. Simon AC,
    3. Grau GE,
    4. Arnoux D,
    5. Camoin L,
    6. Sabatier F,
    7. et al
    . In vitro generation of endothelial microparticles and possible prothrombotic activity in patients with lupus anticoagulant. J Clin Invest. 1999;104(1):93-102.
    OpenUrlCrossRefPubMedWeb of Science
  20. 20.
    1. Zwicker JI,
    2. Lacroix R,
    3. Dignat-George F,
    4. Furie BC,
    5. Furie B
    . Measurement of platelet microparticles. Methods Mol Biol. 2012;788:127-39.
    OpenUrlCrossRefPubMed
  21. 21.
    1. Robert S,
    2. Poncelet P,
    3. Lacroix R,
    4. Arnaud L,
    5. Giraudo L,
    6. Hauchard A,
    7. et al
    . Standardization of platelet-derived microparticle counting using calibrated beads and a Cytomics FC500 routine flow cytometer: a first step towards multicenter studies? J Thromb Haemost. 2009;7(1):190-7.
    OpenUrlCrossRefPubMedWeb of Science
  22. 22.
    1. Gaussem P,
    2. Grailhe P,
    3. Angles-Cano E
    . Sodium dodecyl sulfate-induced dissociation of complexes between human tissue plasminogen activator and its specific inhibitor. J Biol Chem. 1993;268(16):12150-5.
    OpenUrlAbstract/FREE Full Text
  23. 23.
    1. Angles-Cano E
    . A spectrophotometric solidphase fibrin-tissue plasminogen activator activity assay (SOFIA-tPA) for high-fibrin-affinity tissue plasminogen activators. Anal Biochem. 1986;153(2):201-10.
    OpenUrlCrossRefPubMedWeb of Science
  24. 24.
    1. Jimenez JJ,
    2. Jy W,
    3. Mauro LM,
    4. Horstman LL,
    5. Ahn YS
    . Elevated endothelial microparticles in thrombotic thrombocytopenic purpura: findings from brain and renal microvascular cell culture and patients with active disease. Br J Haematol. 2001;112(1):81-90.
    OpenUrlCrossRefPubMedWeb of Science
  25. 25.
    1. Jimenez JJ,
    2. Jy W,
    3. Mauro LM,
    4. Horstman LL,
    5. Soderland C,
    6. Ahn YS
    . Endothelial microparticles released in thrombotic thrombocytopenic purpura express von Willebrand factor and markers of endothelial activation. Br J Haematol. 2003;123(5):896-902.
    OpenUrlCrossRefPubMedWeb of Science
  26. 26.
    1. Ades EW,
    2. Candal FJ,
    3. Swerlick RA,
    4. George VG,
    5. Summers S,
    6. Bosse DC,
    7. et al
    . HMEC-1: establishment of an immortalized human microvascular endothelial cell line. J Invest Dermatol. 1992;99(6):683-90.
    OpenUrlCrossRefPubMedWeb of Science
  27. 27.
    1. Pereira J,
    2. Alfaro G,
    3. Goycoolea M,
    4. Quiroga T,
    5. Ocqueteau M,
    6. Massardo L,
    7. et al
    . Circulating platelet-derived microparticles in systemic lupus erythematosus. Association with increased thrombin generation and procoagulant state. Thromb Haemost. 2006;95(1):94-9.
    OpenUrlCrossRefPubMedWeb of Science
  28. 28.
    1. Dignat-George F,
    2. Camoin-Jau L,
    3. Sabatier F,
    4. Arnoux D,
    5. Anfosso F,
    6. Bardin N,
    7. et al
    . Endothelial microparticles: a potential contribution to the thrombotic complications of the antiphospholipid syndrome. Thromb Haemost. 2004;91(4):667-73.
    OpenUrlPubMedWeb of Science
  29. 29.
    1. Mallat Z,
    2. Hugel B,
    3. Ohan J,
    4. Leseche G,
    5. Freyssinet JM,
    6. Tedgui A
    . Shed membrane microparticles with procoagulant potential in human atherosclerotic plaques: a role for apoptosis in plaque thrombogenicity. Circulation. 1999;99(3):348-53.
    OpenUrlAbstract/FREE Full Text
  30. 30.
    1. Morel O,
    2. Toti F,
    3. Hugel B,
    4. Bakouboula B,
    5. Camoin-Jau L,
    6. Dignat-George F,
    7. et al
    . Procoagulant microparticles: disrupting the vascular homeostasis equation? Arterioscler Thromb Vasc Biol. 2006;26(12):2594-604.
    OpenUrlAbstract/FREE Full Text
  31. 31.
    1. Chironi G,
    2. Simon A,
    3. Hugel B,
    4. Del Pino M,
    5. Gariepy J,
    6. Freyssinet JM,
    7. et al
    . Circulating leukocyte-derived microparticles predict subclinical atherosclerosis burden in asymptomatic subjects. Arterioscler Thromb Vasc Biol. 2006;26(12):2775-80.
    OpenUrlAbstract/FREE Full Text
  32. 32.
    1. Nagahama M,
    2. Nomura S,
    3. Kanazawa S,
    4. Ozaki Y,
    5. Kagawa H,
    6. Fukuhara S
    . Significance of anti-oxidized LDL antibody and monocyte-derived microparticles in anti-phospholipid antibody syndrome. Autoimmunity. 2003;36(3):125-31.
    OpenUrlCrossRefPubMedWeb of Science
  33. 33.
    1. Jy W,
    2. Tiede M,
    3. Bidot CJ,
    4. Horstman LL,
    5. Jimenez JJ,
    6. Chirinos J,
    7. et al
    . Platelet activation rather than endothelial injury identifies risk of thrombosis in subjects positive for antiphospholipid antibodies. Thromb Res. 2007;121(3):319-25.
    OpenUrlCrossRefPubMedWeb of Science
  34. 34.
    1. Duval A,
    2. Helley D,
    3. Capron L,
    4. Youinou P,
    5. Renaudineau Y,
    6. Dubucquoi S,
    7. et al
    . Endothelial dysfunction in systemic lupus patients with low disease activity: evaluation by quantification and characterization of circulating endothelial microparticles, role of anti-endothelial cell antibodies. Rheumatology (Oxford). 2010;49(6):1049-55.
    OpenUrlAbstract/FREE Full Text
  35. 35.
    1. Kahr WH,
    2. Zheng S,
    3. Sheth PM,
    4. Pai M,
    5. Cowie A,
    6. Bouchard M,
    7. et al
    . Platelets from patients with the Quebec platelet disorder contain and secrete abnormal amounts of urokinase-type plasminogen activator. Blood. 2001;98(2):257-65.
    OpenUrlAbstract/FREE Full Text
  36. 36.
    1. Ouimet H,
    2. Freedman JE,
    3. Loscalzo J
    . Kinetics and mechanism of platelet-surface plasminogen activation by tissue-type plasminogen activator. Biochemistry. 1994;33(10):2970-6.
    OpenUrlCrossRefPubMedWeb of Science
  37. 37.
    1. Adelman B,
    2. Rizk A,
    3. Hanners E
    . Plasminogen interactions with platelets in plasma. Blood. 1988;72(5):1530-5.
    OpenUrlAbstract/FREE Full Text
  38. 38.
    1. Miles LA,
    2. Plow EF
    . Binding and activation of plasminogen on the platelet surface. J Biol Chem. 1985;260(7):4303-11.
    OpenUrlAbstract/FREE Full Text
  39. 39.
    1. Baeten KM,
    2. Richard MC,
    3. Kanse SM,
    4. Mutch NJ,
    5. Degen JL,
    6. Booth NA
    . Activation of single-chain urokinase by platelet-associated plasminogen: a mechanism for stimulation of fibrinolysis by platelets. J Thromb Haemost. 2010;8(6):1313-22.
    OpenUrlCrossRefPubMed
  40. 40.
    1. Podor TJ,
    2. Singh D,
    3. Chindemi P,
    4. Foulon DM,
    5. McKelvie R,
    6. Weitz JI,
    7. et al
    . Vimentin exposed on activated platelets and platelet microparticles localizes vitronectin and plasminogen activator inhibitor complexes on their surface. J Biol Chem. 2002;277(9):7529-39.
    OpenUrlAbstract/FREE Full Text
  41. 41.
    1. Zwicker JI,
    2. Liebman HA,
    3. Neuberg D,
    4. Lacroix R,
    5. Bauer KA,
    6. Furie BC,
    7. et al
    . Tumor-derived tissue factor-bearing microparticles are associated with venous thromboembolic events in malignancy. Clin Cancer Res. 2009;15(22):6830-40.
    OpenUrlAbstract/FREE Full Text
  42. 42.
    1. Thomas GM,
    2. Panicot-Dubois L,
    3. Lacroix R,
    4. Dignat-George F,
    5. Lombardo D,
    6. Dubois C
    . Cancer cell-derived microparticles bearing P-selectin glycoprotein ligand 1 accelerate thrombus formation in vivo. J Exp Med. 2009;206(9):1913-27.
    OpenUrlAbstract/FREE Full Text
  43. 43.
    1. Graves LE,
    2. Ariztia EV,
    3. Navari JR,
    4. Matzel HJ,
    5. Stack MS,
    6. Fishman DA
    . Proinvasive properties of ovarian cancer ascites-derived membrane vesicles. Cancer Res. 2004;64(19):7045-9.
    OpenUrlAbstract/FREE Full Text
  44. 44.
    1. Dolo V,
    2. D'Ascenzo S,
    3. Violini S,
    4. Pompucci L,
    5. Festuccia C,
    6. Ginestra A,
    7. et al
    . Matrix-degrading proteinases are shed in membrane vesicles by ovarian cancer cells in vivo and in vitro. Clin Exp Metastasis. 1999;17(2):131-40.
    OpenUrlCrossRefPubMedWeb of Science
  45. 45.
    1. Ginestra A,
    2. Miceli D,
    3. Dolo V,
    4. Romano FM,
    5. Vittorelli ML
    . Membrane vesicles in ovarian cancer fluids: a new potential marker. Anticancer Res. 1999;19(4C):3439-45.
    OpenUrlPubMedWeb of Science
  46. 46.
    1. Ginestra A,
    2. Monea S,
    3. Seghezzi G,
    4. Dolo V,
    5. Nagase H,
    6. Mignatti P,
    7. et al
    . Urokinase plasminogen activator and gelatinases are associated with membrane vesicles shed by human HT1080 fibrosarcoma cells. J Biol Chem. 1997;272(27):17216-22.
    OpenUrlAbstract/FREE Full Text
  47. 47.
    1. Angelucci A,
    2. D'Ascenzo S,
    3. Festuccia C,
    4. Gravina GL,
    5. Bologna M,
    6. Dolo V,
    7. et al
    . Vesicle-associated urokinase plasminogen activator promotes invasion in prostate cancer cell lines. Clin Exp Metastasis. 2000;18(2):163-70.
    OpenUrlCrossRefPubMedWeb of Science
  48. 48.
    1. Doeuvre L,
    2. Plawinski L,
    3. Goux D,
    4. Vivien D,
    5. Angles-Cano E
    . Plasmin on adherent cells: from microvesiculation to apoptosis. Biochem J. 2010;432(2):365-73.
    OpenUrlAbstract/FREE Full Text
  49. 49.
    1. Farina AR,
    2. Tiberio A,
    3. Tacconelli A,
    4. Cappabianca L,
    5. Gulino A,
    6. Mackay AR
    . Identification of plasminogen in Matrigel and its activation by reconstitution of this basement membrane extract. Biotechniques. 1996;21(5):904-9.
    OpenUrlPubMedWeb of Science
  50. 50.
    1. Gaussem P,
    2. Angles-Cano E
    . The formation of complexes between human plasminogen activator inhibitor-1 (PAI-1) and sodium dodecyl sulfate: possible implication in the functional properties of PAI-1. Biochim Biophys Acta. 1991;1079(3):321-9.
    OpenUrlCrossRefPubMedWeb of Science
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Keywords

fibrinolytic microparticles
plasmin
plasminogen
uPA
tPA
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