Rienk Nieuwland

Vesiclepedia: A Compendium for Extracellular Vesicles with Continuous Community Annotation

Vesiclepedia is a community-annotated compendium of molecular data on extracellular vesicles.

Measuring circulating cell-derived microparticles

Cell-derived microparticles (MPs) are receiving increasing attention in recent years, both as a diagnostic aid and investigative tool [1–4]. Because they carry markers of the parent cell, including those induced by activation or apoptosis, endothelial MPs (EMPs) can provide valuable information on the status of the parent cell, obtainable in no other way. In addition, there is a growing belief that MPs can function as important diffusible vectors of specific adhesins and cytokines promoting cellular interactions and signal transmission [2]. ThusMP analysis constitutes a new avenue for investigation of pathologies in various diseases. Although still considered investigational [1–4], recent results from several laboratories suggest that MP analysis may be poised to enter the mainstream of clinical testing. However, a major impediment to that end is the wide variety ofmethodologies used by different laboratories in this field, few of which can be directly compared to the others, and results from which are sometimes inconsistent or conflicting. As a first step in addressing that problem, the Editor has organized this Forum article, consisting of a brief description of the preferred methods and rationality from each of six active laboratories in the field, including our own [5–10]. Table 1 lists some key features of the six methodological approaches. It is seen that major differences exist in the preparation of the MP samples (such as centrifugation), whether or not they are first sedimented and resuspended, means of generic MP detection (4 of 6 use annexin V), and cell lineage-specific antigenic markers. These differences probably account for some of the different findings among the groups.

Elevated Numbers of Tissue-Factor Exposing Microparticles Correlate With Components of the Metabolic Syndrome in Uncomplicated Type 2 Diabetes Mellitus

Background—Type 2 diabetes is associated with accelerated atherosclerosis. Because cell-derived microparticles support coagulation and inflammation, they may be involved in atherogenesis. We characterized circulating microparticles both in patients with uncomplicated, well-regulated type 2 diabetes and in healthy subjects, as well as their relationship with coagulation and metabolic control. Methods and Results—Microparticles were isolated from plasma, stained with annexin V, cell-specific monoclonal antibodies (MoAbs) and a MoAb directed against tissue factor (TF), and analyzed by flow cytometry. Microparticle numbers and origin were comparable in the two groups, but the median number of TF-positive microparticles was twice as high in patients than in controls (P =0.018). Patients had higher percentages of TF-positive microparticles from T-helper cells (P =0.045), granulocytes (P =0.004), and platelets (P =0.002). Subpopulations of TF-positive microparticles from platelets and T-helper cells exposed granulocytic markers. Correlations were found between the numbers of various TF-positive microparticle subpopulations and body mass index, fasting plasma glucose and insulin, or tumor necrosis factor-&agr; and serum HDL cholesterol. Microparticles from patients generated less thrombin in vitro (P =0.007). Microparticle numbers did not correlate with in vivo coagulation markers prothrombin fragment F1+2 and thrombin-antithrombin complexes. Conclusions—TF, possibly of granulocytic origin, is exposed on microparticle subpopulations in asymptomatic patients with well-regulated type 2 diabetes. TF-positive microparticles are associated with components of the metabolic syndrome but not with coagulation. Thus, TF on microparticles may be involved in processes other than coagulation, including transcellular signaling or angiogenesis.

Cell-Derived Microparticles Generated in Patients During Cardiopulmonary Bypass Are Highly Procoagulant

BACKGROUND Microparticles from platelets and other cells have been extensively studied and characterized in vitro. Although the level of platelet-derived microparticles is elevated in a variety of diseases, including cardiac surgery, virtually nothing is known about their functions in vivo. The aim of the present study was to investigate the procoagulant properties of microparticles generated in vivo. METHODS AND RESULTS In 6 patients at the end of cardiopulmonary bypass, 14.8 x 10(9)/L (median; range, 9.7 to 27.4 x 10(9)/L) platelet-derived microparticles were present in pericardial blood, whereas blood obtained from the systemic circulation contained 1.6 x 10(9)/L (median; range, 0.4 to 8.9 x 10(9)/L) of such microparticles, as determined by flow cytometry. Microparticles stained positively for phosphatidylserine as determined with labeled annexin V. In contrast to systemic blood, pericardial blood contained not only microparticles of platelet origin but also microparticles that originated from erythrocytes, monocytes, or granulocytes, and other hitherto unknown cellular sources. Plasma prepared from pericardial blood and to a lesser extent plasma from systemic blood obtained at the same time, stimulated formation of thrombin in vitro. This activity of pericardial plasma was lost after removal of its microparticles by high-speed centrifugation, whereas the corresponding microparticle pellet was strongly procoagulant. The generation of thrombin in vitro involved a tissue factor/factor VII-dependent and factor XII-independent pathway. CONCLUSIONS This study is the first to demonstrate that microparticles generated in vivo can stimulate coagulation.

Direct binding of C1q to apoptotic cells and cell blebs induces complement activation

Deficiency of early components of the classical pathway of complement, particularly C1q, predisposes to the development of systemic lupus erythematosus. Several studies have suggested an association between the classical complement pathway and the clearance of apoptotic cells. Mice with a targeted deletion of the C1q gene develop a lupus‐like renal disease, which is associated with the presence of multiple apoptotic bodies in the kidney. In the present study we demonstrate that highly purified C1q binds to apoptotic cells and isolated blebs derived from these apoptotic cells. Binding of C1q to apoptotic cells occurs via the globular heads of C1q and induces activation of the classical complement pathway, as shown by the deposition of C4 and C3 on the surface of these cells and on cell‐derived blebs. In addition, for the first time, we demonstrate that surface‐bound C1q is present on a subpopulation of microparticles isolated from human plasma. Taken together, these observations demonstrate that C1q binds directly to apoptotic cells and blebs derived therefrom and support a role for C1q, possibly in concert with C4 and C3, in the clearance of apoptotic cells and blebs by the phagocytic system.

Particle size distribution of exosomes and microvesicles determined by transmission electron microscopy, flow cytometry, nanoparticle tracking analysis, and resistive pulse sensing

Enumeration of extracellular vesicles has clinical potential as a biomarker for disease. In biological samples, the smallest and largest vesicles typically differ 25‐fold in size, 300 000‐fold in concentration, 20 000‐fold in volume, and 10 000 000‐fold in scattered light. Because of this heterogeneity, the currently employed techniques detect concentrations ranging from 104 to 1012 vesicles mL–1.

Optical and non-optical methods for detection and characterization of microparticles and exosomes

Summary.  Microparticles and exosomes are cell‐derived microvesicles present in body fluids that play a role in coagulation, inflammation, cellular homeostasis and survival, intercellular communication, and transport. Despite increasing scientific and clinical interest, no standard procedures are available for the isolation, detection and characterization of microparticles and exosomes, because their size is below the reach of conventional detection methods. Our objective is to give an overview of currently available and potentially applicable methods for optical and non‐optical determination of the size, concentration, morphology, biochemical composition and cellular origin of microparticles and exosomes. The working principle of all methods is briefly discussed, as well as their applications and limitations based on the underlying physical parameters of the technique. For most methods, the expected size distribution for a given microvesicle population is determined. The explanations of the physical background and the outcomes of our calculations provide insights into the capabilities of each method and make a comparison possible between the discussed methods. In conclusion, several (combinations of) methods can detect clinically relevant properties of microparticles and exosomes. These methods should be further explored and validated by comparing measurement results so that accurate, reliable and fast solutions come within reach.

Human cell-derived microparticles promote thrombus formation in vivo in a tissue factor-dependent manner

Summary.  Background: Circulating microparticles of various cell types are present in healthy individuals and, in varying numbers and antigenic composition, in various disease states. To what extent these microparticles contribute to coagulation in vivo is unknown. Objectives: To examine the in vivo thrombogenicity of human microparticles. Methods: Microparticles were isolated from pericardial blood of cardiac surgery patients and venous blood of healthy individuals. Their numbers, cellular source, and tissue factor (TF) exposure were determined using flow cytometry. Their in vitro procoagulant properties were studied in a fibrin generation test, and their in vivo thrombogenicity in a rat model. Results: The total number of microparticles did not differ between pericardial samples and samples from healthy individuals (P = 0.786). In both groups, microparticles from platelets, erythrocytes, and granulocytes exposed TF. Microparticle‐exposed TF antigen levels were higher in pericardial compared with healthy individual samples (P = 0.036). Pericardial microparticles were strongly procoagulant in vitro and highly thrombogenic in a venous stasis thrombosis model in rats, whereas microparticles from healthy individuals were not [thrombus weights 24.8 (12.2–41.3) mg vs. 0 (0–24.3) mg median and range; P < 0.001]. Preincubation of pericardial microparticles with an inhibitory antibody against human TF abolished their thrombogenicity [0 (0–4.4) mg; P < 0.01], while a control antibody had no effect [19.6 (12.6–53.7) mg; P > 0.05]. The thrombogenicity of the microparticles correlated strongly with their TF exposure (r = 0.9524, P = 0.001). Conclusions: Human cell‐derived microparticles promote thrombus formation in vivo in a TF‐dependent manner. They might be the direct cause of an increased thromboembolic tendency in various patient groups.

Single vs. swarm detection of microparticles and exosomes by flow cytometry.

See also Harrison P, Gardiner C. Invisible vesicles swarm within the iceberg. This issue, pp 916‐8.

Circulating erythrocyte-derived microparticles are associated with coagulation activation in sickle cell disease

It has long been known that patients with sickle cell disease have ongoing activation of their coagulation system, which is exacerbated during painful occlusive crises. In this paper, the authors explore the role of the increased numbers of erythrocyte derived microparticles in this phenomenon and suggest that a surprisingly large proportion of this is dependent on Factor XI. See related perspective article on page 1481. Background Sickle cell disease is characterized by a hypercoagulable state as a result of multiple factors, including chronic hemolysis and circulating cell-derived microparticles. There is still no consensus on the cellular origin of such microparticles and the exact mechanism by which they may enhance coagulation activation in sickle cell disease. Design and Methods In the present study, we analyzed the origin of circulating microparticles and their procoagulant phenotype during painful crises and steady state in 25 consecutive patients with sickle cell disease. Results The majority of microparticles originated from platelets (GPIIIa,CD61) and erythrocytes (glycophorin A,CD235), and their numbers did not differ significantly between crisis and steady state. Erythrocyte-derived microparticles strongly correlated with plasma levels of markers of hemolysis, i.e. hemoglobin (r=−0.58, p<0.001) and lactate dehydrogenase (r=0.59, p<0.001), von Willebrand factor as a marker of platelet/endothelial activation (r=0.44, p<0.001), and D-dimer and prothrombin fragment F1+2 (r=0.52, p<0.001 and r=0.59, p<0.001, respectively) as markers of fibrinolysis and coagulation activation. Thrombin generation depended on the total number of microparticles (r=0.63, p<0.001). Anti-human factor XI inhibited thrombin generation by about 50% (p<0.001), whereas anti-human factor VII was ineffective (p>0.05). The extent of factor XI inhibition was associated with erythrocyte-derived microparticles (r=0.50, p=0.023). Conclusions We conclude that the procoagulant state in sickle cell disease is partially explained by the factor XI-dependent procoagulant properties of circulating erythrocyte-derived microparticles.