Anti-apolipoprotein A-1 IgG in patients with myocardial infarction promotes inflammation through TLR2/CD14 complex.

OBJECTIVES: Toll-like receptor (TLR)-mediated vascular inflammation, inducible by - amongst other factors - auto-antibodies, is increasingly recognized as a potential mediator of cardiovascular disease. We investigated whether anti-apolipoprotein (Apo)A-1 IgG was associated with a pro-inflammatory cytokine profile in myocardial infarction (MI) patients and whether anti-ApoA-1 IgG elicited a pro-inflammatory response by activating TLRs. METHODS: As surrogate markers of atherosclerotic plaque vulnerability, interleukin (IL)-6, tumour necrosis factor (TNF)-α, matrix metalloproteinase (MMP)-9 and MMP-3 levels were assessed in 221 consecutive MI patients. Using human monocyte-derived macrophages (HMDMs) we investigated (i) the anti-ApoA-1 IgG interaction with TLRs using proximity ligation assay and (ii) anti-ApoA-1 IgG-dependent IL-6/TNF-α production. TLR involvement was further confirmed using HEK293-Blue TLR-2/-4 cells and by computational docking simulations. RESULTS: In MI patients, anti-ApoA-1 IgG positivity was associated with higher levels of IL-6, TNF-α and MMP-9, but lower MMP-3 levels. In in vitro experiments, anti-ApoA-1 antibodies bound to HDMDs in a TLR2-dependent manner, resulting in nuclear translocation of NFκB and a significant increase in TNF-α and IL-6 production. Subsequent functional studies highlighted the importance of CD14 as co-receptor in the anti-ApoA-1 IgG-TLR2-induced cytokine production. Additional bioinformatic studies identified structural homologies between TLR2 and ApoA-1, which may explain the observed cross-reactivity between antibodies against these two molecules. CONCLUSIONS: Anti-ApoA-1 IgG positivity in MI is associated with a high-risk cytokine profile. These auto-antibodies promote inflammation by stimulating the TLR2/CD14 receptor complex, probably because of molecular mimicry, which may contribute to atherosclerosis-related complications in patients.

A resistively-heated dynamic diamond anvil cell (RHdDAC) for fast compression x-ray diffraction experiments at high temperatures.

A resistively-heated dynamic diamond anvil cell (RHdDAC) setup is presented. The setup enables the dynamic compression of samples at high temperatures by employing a piezoelectric actuator for pressure control and internal heaters for high temperature. The RHdDAC facilitates the precise control of compression rates and was tested in compression experiments at temperatures up to 1400 K and pressures of ∼130 GPa. The mechanical stability of metallic glass gaskets composed of a FeSiB alloy was examined under simultaneous high-pressure/high-temperature conditions. High-temperature dynamic compression experiments on H2O ice and (Mg, Fe)O ferropericlase were performed in combination with time-resolved x-ray diffraction measurements to characterize crystal structures and compression behaviors. The employment of high brilliance synchrotron radiation combined with two fast GaAs LAMBDA detectors available at the Extreme Conditions Beamline (P02.2) at PETRA III (DESY) facilitates the collection of data with excellent pressure resolution. The pressure-temperature conditions achievable with the RHdDAC combined with its ability to cover a wide range of compression rates and perform tailored compression paths offers perspectives for a variety of future experiments under extreme conditions.

The influence exerted by a restricted phospholipid microenvironment on the expression of tissue factor activity at the cell plasma membrane surface.

Phosphatidylserine (PhtdSer) is an anionic aminophospholipid necessary for the development of optimal tissue factor (TF) activity at the cell surface. This study investigates the implication of a restricted lipid environment with respect to PhtdSer availability on TF expression and activity. K562 cells, showing a reduced ability to externalize PhtdSer, were transfected with human TF cDNA. PhtdSer exposure and TF activity were examined in transfected cells and compared to monocytic THP-1 cells expressing constitutive and inducible TF or megakaryocytic HEL cells showing a high PhtdSer externalization potency. TF expression was evidenced by flow cytometry and its activity measured using functional assays. PhtdSer exposure was monitored by enzymatic prothrombinase assay. One clone (DC9) expressed a stable amount of TF antigen without global modification of its membrane status. Despite a noticeable TF expression level, clone DC9 presented only a weak TF activity even after ionophore stimulation. The apparent Km, relative to factor X (FX) activation by TF-factor VIIa (FVIIa) complex, was 335 nM versus 70 nM for THP-1 cells. The velocity of the reaction was found 3-fold slower in DC9 than THP-1 cells. Ionophore treatment resulting in slightly enhanced amounts of available PhtdSer abolished this difference. The DC9 clone appears suitable for further investigations on the biology of TF expressed at the surface of cells where the contribution of PhtdSer is significantly attenuated. Such cells should enable further assessment of the role of TF as a receptor coupled to intracellular signaling pathways and its fate during apoptotic cell death.

Auto-antibodies as emergent prognostic markers and possible mediators of ischemic cardiovascular diseases.

During the last 15 years, a growing body of evidence supported the fact that auto-antibodies represent not only emergent markers but also active mediators of cardiovascular disease (CVD), clinically represented mostly by acute coronary syndrome (ACS) and stroke. There is a contrasted relationship between auto-antibodies and CVD, some being protective, while others acting as potential risk factors. Therefore, we performed a review of the literature on the respective cardiovascular prognostic value of the most relevant auto-antibodies in ACS and stroke, and their putative pathophysiological properties in atherogenesis. This review highlights auto-antibodies as active modulators of the innate immune system in atherogenesis (either toward a pro- or anti-inflammatory response), or by affecting basal heart rate regulation (anti-apoA-1 IgG). Given their apparent prognostic independency towards traditional cardiovascular risk factors, the data available in the literature indicates that some of those auto-antibodies could be of valuable help for cardiovascular risk stratification in the future, especially because their deleterious effects have been shown to be potentially abrogated in vivo and in vitro by existing therapeutic modalities. Although evidence in humans is currently lacking, these studies may open innovative therapeutic perspectives for CVD in the future.

The significance of human monocyte thrombomodulin during membrane vesiculation and after stimulation by lipopolysaccharide.

Thrombomodulin acts as an essential membrane cofactor of thrombin in the triggering of the natural anticoagulant protein C pathway responsible for the inactivation of procoagulant cofactors VIIIa and Va. Because monocytes play a critical role in the coupling between infection/inflammation and thrombosis, the fate of monocyte thrombomodulin was assessed at the cell plasma membrane and on derived microparticles. A significant basal level of thrombomodulin activity was measured on unstimulated monocytes and microparticles. Lipopolysaccharide treatment resulted in increased thrombomodulin activity on monocytes (approximately 40%) and microparticles (approximately 80%), whereas tissue factor and prothrombinase activities were strongly expressed on both. Flow cytometry detection of thrombomodulin antigen confirmed its presence on unstimulated monocytes and microparticles. A decrease (approximately 30%) in thrombomodulin labelling was noticed on stimulated monocytes. Labelling of microparticles shed from stimulated and unstimulated monocytes remained unchanged, only an increased proportion of microparticles (approximately 20%) was observed. The absence of early down-regulation of thrombomodulin following monocyte stimulation suggests that it fulfils an important regulatory function of membrane-associated procoagulant activities. This would be of particular significance at the surface of microparticles having the ability to diffuse and concentrate by adherence at inflammatory sites.

Oyxsterols induce membrane procoagulant activity in monocytic THP-1 cells.

Oxidized cholesterol compounds or oxysterols are thought to be potent membrane-destabilizing agents. Anionic phospholipids, chiefly phosphatidylserine, have a procoagulant potential due to their ability to favour the membrane assembly of the characteristic clotting enzyme complexes including the tissue factor-dependent initiating complex. However, in resting cells, phosphatidylserine is sequestered in the inner leaflet of the plasma membrane. When THP-1 monocytic cells were cultured in the presence of 7beta-hydroxycholesterol (7beta-OH) or 25-hydroxycholesterol (25-OH), prothrombinase, which reflects anionic phospholipid exposure and tissue factor (TF) procoagulant activities, increased in a time- and dose-dependent manner. 7beta-OH appeared 1.5- to 2-fold more potent than 25-OH. Interestingly, no effect of cholesterol itself could be detected on procoagulant activities. Nevertheless, no difference in TF activity could be detected between oxysterol-treated and control cells after disruption. TF antigen expression was the same in oxysterol-treated and control cells as shown by flow cytometry. In contrast, the use of labelled annexin V, a protein probe of anionic phospholipids, revealed an elevated number of cells with exposed phosphatidylserine. Because the latter also constitutes a signal for phagocyte recognition of apoptotic cells and fragments, and a proportion of cells displayed altered morphology with condensed chromatin and membrane blebs, analysis of DNA was performed and indicated apoptosis in oxysterol-treated cells. Hence, oxysterol-induced phosphatidylserine exposure and enhanced TF activity may results from apoptosis. These results suggest relationships between oxysterol and the amplification of coagulation reactions by monocytic cells resulting from induced phosphatidylserine exposure.

Scott syndrome, characterized by impaired transmembrane migration of procoagulant phosphatidylserine and hemorrhagic complications, is an inherited disorder.

An as yet single family with a bleeding history is shown to present the characteristic lack of membrane expression of procoagulant phospholipids observed in Scott syndrome. Low prothrombin consumption in the serum of the propositus, a 71-year-old woman, and two of her children was the sole abnormal hemostasis parameter. The degree of exposure of procoagulant phospholipids, chiefly phosphatidylserine, was reduced in stimulated platelets, erythrocytes and Epstein-Barr virus-infected B lymphocytes. The data are compatible with homozygous status of the propositus and heterozygous status of her children. Scott syndrome appears to be transmitted as an autosomal recessive trait reflecting the deletion or mutation of a putative outward phosphatidylserine translocase. The detailed knowledge of this transporter could have an impact in membrane physiology.

Scott syndrome: an inherited defect of the procoagulant activity of platelets.

Anionic phospholipids, chiefly phosphatidylserine, are essential for the assembly of the characteristic enzyme complexes of the blood coagulation cascade at the surface of stimulated platelets and derived microparticles. In the resting cell, these phospholipids are sequestered in the inner leaflet of the plasma membrane. Scott syndrome is an extremely rare bleeding disorder that confirms the essential role of these anionic procoagulant phospholipids. In Scott patients, phosphatidylserine externalization and microparticle shedding are dramatically impaired. This functional deficiency is clearly evidenced by the measurement of residual prothrombin in serum. The recent detection of a familial Scott syndrome testifies to the genetic origin of the defect. Symptomatic Scott patients present provoked hemorrhages and are probably homozygous for the disorder whereas asymptomatic children are probably heterozygous. The Scott phenotype can be detected in platelets, red cells and lymphocytes by functional prothrombinase assay and flow cytometry. Intermediate degrees of phosphatidylserine exposure and vesiculation are observed in cells from the asymptomatic heterozygous offspring when compared to those from their homozygous defective parent and healthy subjects. The functional and molecular characterization of mutated element(s) in Scott syndrome should be of valuable help for the understanding of phospholipid transmembrane migration, also termed flip-flop, its possible links with membrane vesiculation, and the eventual implications in thrombotic or apoptotic processes.

Physiopathological significance of catalytic phospholipids in the generation of thrombin.

Thrombin generation is the culminating event of the coagulation cascade. It is initiated after the expression of tissue factor by endothelial cells and monocytes exposed to thrombogenic stimuli. Anionic phospholipids, chiefly phosphatidylserine, are necessary for the optimal activity of tissue factor and completion of the clotting process. They display a catalytic potential by allowing the formation of the characteristic enzyme complexes at the membrane surface. Platelets are viewed as the main source of procoagulant phospholipid referred to as platelet factor 3. The plasma membrane of resting cells presents an asymmetrical distribution of phospholipids, aminophospholipids being sequestered in the inner leaflet. Procoagulant phospholipids become available at the outer surface after cell stimulation. The collapse of the membrane asymmetry is thought to promote a phospholipid scrambling accompanied by the shedding of microparticles. The plasma membranes of such vesicles bear irreversibly externalized procoagulant phosphatidylserine and contain glycoproteins that testify to their tissue origin. Hence, microparticles could disseminate a dual procoagulant and adhesive potential. Thrombin autoamplification is exerted through feedback activation loops involving either coagulation factors or platelets. This article details the mechanisms by which procoagulant phospholipids promote the generation of an excess of thrombin. A new pharmacological approach of thrombosis is presented, based on the control of the exposure of procoagulant phospholipids and membrane microparticle shedding.

Monocyte vesiculation is a possible mechanism for dissemination of membrane-associated procoagulant activities and adhesion molecules after stimulation by lipopolysaccharide.

Endotoxin-stimulated monocytes can elicit a dual procoagulant response. They express tissue factor and expose phosphatidylserine in the outer leaflet of the plasma membrane. Tissue factor, a membrane glycoprotein, is the cellular trigger of blood coagulation reactions. Phosphatidylserine is an essential anionic phospholipid for surface amplification of thrombin generation. In this study the distribution of these two procoagulant entities between activated monocytes and derived microparticles was assessed after stimulation by LPS. The presence of CD14, CD11a, and CD18, and possible associated adhesion potential were examined, particularly on microparticles. Tissue factor was evidenced by using a specific functional assay and flow cytometry. Phosphatidylserine exposure was monitored through its catalytic activity in a thrombin generation assay and by flow cytometry with the use of FITC-conjugated annexin V, a protein probe of anionic phospholipids. CD14, CD11a, and CD18 were detected by flow cytometry. The interaction of microparticle CD11a/CD18 with intracellular adhesion molecule-1 was demonstrated by using immobilized recombinant intracellular adhesion molecule-1 fusion protein. The major part of tissue factor and phosphatidylserine-dependent procoagulant activity was associated with microparticles after LPS stimulation. This was confirmed by flow cytometry. The presence of functional CD11a/CD18, and CD14 on microparticles testifies to an associated adhesion potential. These results show that membrane vesiculation could be responsible for dissemination of inducible monocyte procoagulant activities and suggest that derived microparticles could also participate in endothelium stimulation. This emphasizes the role of monocyte as a central element in the coupling between inflammation/infection and thrombosis.