Vitamin D Inhibits IL-6 Pro-Atherothrombotic Effects in Human Endothelial Cells: A Potential Mechanism for Protection against COVID-19 Infection?

Background: Thrombosis with cardiovascular involvement is a crucial complication in COVID-19 infection. COVID-19 infects the host by the angiotensin converting enzyme-2 receptor (ACE2r), which is expressed in endothelial cells too. Thus, COVID-related thrombotic events might be due to endothelial dysfunction. IL-6 is one of the main cytokines involved in the COVID-19 inflammatory storm. Some evidence indicates that Vitamin D (VitD) has a protective role in COVID-19 patients, but the molecular mechanisms involved are still debated. Thus, we investigated the effect of VitD on Tissue Factor and adhesion molecules (CAMs) in IL-6-stimulated endothelial cells (HUVEC). Moreover, we evaluated levels of the ACE2r gene and proteins. Finally, we studied the modulation of NF-kB and STAT3 pathways. Methods: HUVEC cultivated in VitD-enriched medium were stimulated with IL-6 (0.5 ng/mL). The TF gene (RT-PCR), protein (Western blot), surface expression (FACS) and procoagulant activity (FXa generation assay) were measured. Similarly, CAMs soluble values (ELISA) and ACE2r (RT-PCR and Western blot) levels were assessed. NF-kB and STAT3 modulation (Western blot) were also investigated. Results: VitD significantly reduced TF expression at both gene and protein levels as well as TF-procoagulant activity in IL-6-treated HUVEC. Similar effects were observed for CAMs and ACE2r expression. IL-6 modulates these effects by regulating NF-κB and STAT3 pathways. Conclusions: IL-6 induces endothelial dysfunction with TF and CAMs expression via upregulation of ACE2r. VitD prevented these IL-6 deleterious effects. Thus, it might be speculated that this is one of the hypothetical mechanism(s) by which VitD exerts its beneficial effects in COVID-19 infection.

Mitochondrial ATP generation in stimulated platelets is essential for granule secretion but dispensable for aggregation and procoagulant activity

Not available.

300 PCSK9 induces a prothrombotic response by activation of NFKB signalling pathway in mononuclear cells

Aims Strong evidence both experimental and clinical studies point out to an involvement of proprotein convertase subtilisin/kexin 9 (PCSK9), as an important player in hypercholesterolemia and atherosclerosis pathophysiology, identifying it, as a key molecule in the development of new cholesterol-lowering drugs and therapeutic target for atherosclerosis and related diseases. Emerging evidence shown that PCSK9 is straight implicated in inflammatory process where it may directly influence the activity of various cell types through NFkB activation, a key transcription factor involved in the induction of both pro-inflammatory cytokines and Tissue Factor (TF) expression, a major regulator of haemostasis and thrombosis in monocytes. Deductive reasoning makes therefore plausible to investigate a mechanistic link between circulation PCSK9 levels and TF expression, both in monocytes as well as on the surface of microparticles (MPs) generated from the same cells, with NFkB acting as the chain in the link. To investigate the involvement of NFkB signalling pathway in PCSK9-induced TF expression. Methods THP-1 cell line were stimulated with human (h) PCSK9 (5 μg/mL) or pre-incubated with BAY-117082 (BAY, 10−5M) an NFκB inhibitor, CLI-095 (3 × 10−6M), a highly TLR-4 signalling specific inhibitor and LPS-RS(5 μg/mL) a TLR-4 antagonist. TF procoagulant activity (PCA) was assessed by one-stage clotting assay using a STart Max semi-automated coagulation analyser. Concentration of TF-bearing MPs was determined using the Zymuphen MP-activity kit. Results hPCSK9 stimulated TF activity in THP-1 (PCA: from 50 ± 20 to 120 ± 20 ρg/mL, n = 10, P < 0.01). BAY, an NFkB inhibitor (PCA: −71 ± 23%, n = 5, P < 0.01) and CLI-095, a TLR-4 signalling inhibitor, (PCA: −86 ± 26%, n = 3, P < 0.05) and LPS-RS (PCA: −71 ± 23%, n = 5, P < 0.01) down-regulated PCSK9-induced TF activity completely. Furthermore THP-1stimulation with hPCSK9 causes the release of prothrombotic MPs-TF+ (MPs release from: 0.13 ± 0.07 to 0.42 ± 0.1 nM PS, n = 7, P < 0.05; PCA-MP+ from: 14 ± 3 to 44 ± 28 ρg/mL, n = 5, P < 0.05). Conclusions These data confirm the pivotal role of monocytes in the response PCSK9-induced TF-expression as well as the involvement of PCSK9 in inflammatory-thrombotic diseases through a direct stimulation of TF procoagulant activity and by the release of TF-bearing MPs. The possible mechanism of action involves recognition of PCSK9 by TLRs 2 and/or 4, on monocytes membrane surface, leading to activation of the transcription factor NFκB via an intracellular signalling cascade. Further studies will be needed to better understand the regulatory mechanisms underlying this complex set of biological responses that bind PCSK9, and coagulation events.

SARS-CoV-2 Ion Channel ORF3a Enables TMEM16F-Dependent Phosphatidylserine Externalization to Augment Procoagulant Activity of the Tenase and Prothrombinase Complexes

Severe SARS-CoV-2 infection is complicated by dysregulation of the blood coagulation system and high rates of thrombosis, but virus-intrinsic mechanisms underlying this phenomenon are poorly understood. Increased intracellular calcium concentrations promote externalization of phosphatidylserine (PS), the membrane anionic phospholipid required for assembly and activation of the tenase and prothrombinase complexes to drive blood coagulation. TMEM16F is a ubiquitous phospholipid scramblase that mediates externalization of PS in a calcium-dependent manner. As SARS-CoV-2 ORF3a encodes a presumed cation channel with the ability to transport calcium, we hypothesized that ORF3a expression by infected host cells perturbs the cellular calcium rheostat, driving TMEM16F-dependent externalization of PS and enhancing procoagulant activity. Using a doxycycline-inducible system, synchronized expression of ORF3a in A549 pulmonary epithelial cells resulted in a time-dependent augmentation of tissue factor (TF) procoagulant activity exceeding 9-fold by 48 hours (p < 0.0001), with no change in TF cell-surface expression. This enhancement was dependent upon PS as determined by inhibition with the PS-binding protein lactadherin. Over 2-fold enhancement of prothrombinase activity (p < 0.0001) was also observed by 48 hours. ORF3a increased intracellular calcium levels by 18-fold at 48 hours (p < 0.0001), as determined by the intracellular calcium indicator fluo-4. After 16 hours of ORF3a expression, more than 60% of cells had externalized PS (p < 0.001) without increased cell death, as quantified by flow cytometry following annexin V binding. Immunofluorescence microscopy staining for ORF3a, annexin V, and nuclei confirmed ORF3a expression within internal and cell surface membranes and increased PS externalization. PS externalization was insensitive to the pan-caspase inhibitor z-VAD-FMK, and there was no evidence of apoptotic activation as determined by caspase-3 cleavage. By contrast, ORF3a expression did not augment coagulation in cells deficient in the calcium-dependent phospholipid scramblase TMEM16F. Similarly, ORF3a-enhanced TF procoagulant activity (p < 0.01) and prothrombinase activity (p<0.05) was completely abrogated using TMEM16 inhibitors, including the uricosuric agent benzbromarone that has been registered for human use in over 20 countries. Live SARS-CoV-2 infection of A549-ACE2 cells increased cell surface factor Xa generation at MOI 0.1 (p < 0.01) but not MOI 0.01 or following heat inactivation of the virus, and RNA sequencing confirmed ORF3a induction without increased F3 expression. RNA sequencing of human SARS-CoV-2 infected lung autopsy and control tissue (n= 53) confirmed these findings in vivo. Immunofluorescence staining for ORF3a and KRT8/18 and CD31 in SARS-CoV-2 infected human lung autopsy specimens demonstrated ORF3a expression in pulmonary epithelium and endothelial cells, highlighting the potential pathologic relevance of this mechanism. Here we demonstrate that expression of the SARS-CoV-2 accessory protein ORF3a increases the intracellular calcium concentration and TMEM16F-dependent PS scrambling to augment procoagulant activity of the tenase and prothrombinase complexes. Our studies of human cells and tissues infected with SARS-CoV-2 support the pathologic relevance of this mechanism. We highlight the therapeutic potential to target the ORF3a-TMEM16F axis as with benzbromarone to mitigate dysregulation of coagulation and thrombosis during severe SARS-CoV-2 infection. Disclosures Schwartz: Miromatrix Inc: Membership on an entity's Board of Directors or advisory committees; Alnylam Inc.: Consultancy, Speakers Bureau. Schulman: CSL Behring: Consultancy, Research Funding.

DNA Mediated Blood Coagulation: Extracellular DNA Accelerates Fibrinogen Polymerization By Thrombin Independent of Contact Pathway

Introduction- Several in vivo studies and clinical studies have demonstrated extracellular DNA as a mediator of coagulation and this effect was reversed by the administration of DNA degrading enzyme DNase I. However, there is no clear understanding of the mechanism by which extracellular DNA activates coagulation in vitro. Conventionally, it was thought to be the activator of the contact pathway. But recent studies have shown that extracellular DNA isolated without contaminants like silica particles is a weak activator of the contact pathway. In this study, we have investigated the mechanism by which extracellular DNA is contributing to coagulation. Corroborating with recent results, we show that extracellular genomic DNA is a weak activator contact pathway. We determined that extracellular DNA accelerate fibrinogen polymerization by thrombin via a possible template mechanism. Our biophysical studies corroborate the interaction of DNA, thrombin, and fibrinogen. Understanding the mechanism of DNA induced blood coagulation will help address the gaps in the literature as well as develop inhibitors against DNA- mediated thrombosis. Methods- Silica-free extracellular DNA was purified with the PAXgene™ Blood DNA Kit. Contact activation in plasma was measured by monitoring the cleavage of the substrate S2302. To study the contact independent activation of plasma clotting by extracellular DNA, 1.5 µM Corn Trypsin Inhibitor (CTI) was applied to the plasma. Next, acceleration of fibrinogen polymerization by thrombin in presence of extracellular DNA was measured by monitoring the absorbance of 350 nm. Interaction of DNA with fibrinogen and thrombin in phosphate buffer was determined by CD spectroscopy. Results- Our results show that silica-free extracellular genomic DNA is a weak activator of the contact pathway of coagulation [Fig-A]. Moreover, genomic DNA accelerated the plasma clotting even when the contact pathway was inhibited with CTI indicating a contact independent mechanism of the procoagulant activity of extracellular DNA. Interestingly, the presence of extracellular DNA accelerated the polymerization of fibrinogen in presence of thrombin [Fig-B]. A bell-shaped dose-response curve for extracellular DNA indicates a likely template mechanism in which both thrombin and fibrinogen could assemble on the DNA molecule. These results are supported by the results from the CD spectroscopy studies where an alteration of the structure of fibrinogen and thrombin can be noticed in presence of extracellular DNA. Confocal studies further corroborate this observation. Our results also show different nucleic acids activate coagulation via different pathways. Significance- Procoagulant activity of extracellular DNA is demonstrated in several mouse models. However, a clear understanding of the mechanism of procoagulant activity of DNA in vitro has been challenging due to the caveats in the isolation of extracellular DNA where it is often contaminated with silica particles. Here we show a novel procoagulant mechanism of cell- free DNA where it augments the polymerization of fibrinogen by thrombin. These results provide insights into the mechanism of procoagulant activity of DNA which is key to develop therapeutics against procoagulant DNA. Figure 1 Figure 1. Disclosures No relevant conflicts of interest to declare.

Skeletal Muscle Myosin Is Procoagulant By Binding Factor XI Via Its A3 Domain and Enhancing Factor XI Activation By Thrombin

Blood coagulation mechanisms play key roles in health and disease. Pilot studies using selected human plasmas showed the potential associations of plasma skeletal muscle myosin (SkM) isoforms and phenotypes with pulmonary embolism and thrombin generation, suggesting SkM may contribute to blood coagulation reactions in plasma. Here we report that ex vivo studies of the coagulability of fresh flowing human blood over SkM-coated surfaces showed that an anti-factor XI (FXI) mAb, but not an anti-tissue factor mAb, inhibited clot formation, indicating that FXI is an essential contributor for the normal observed procoagulant response of blood during its exposure to immobilized SkM. This raised the question of whether procoagulant SkM's requirement for FXI involves direct or indirect effects on FXI. To assess direct interactions between SkM and FXI, Bio-Layer Interferometry (BLI) (Octet Red system) was used to record kinetics for binding of soluble FXI to immobilized SkM. BLI data showed that FXI bound to SkM with a Kd of 0.2 nM (k on= 2.92x10 6 M -1s -1 and k off=9.25x10 -3 s -1) (Fig. 1A). In contrast, prekallikrein (PK) did not bind to the SkM (Fig.1A), indicating the specificity of SkM for binding FXI. The anti-FXI mAb1A6, which recognizes the Apple (A)3 domain of FXI, potently inhibited binding of FXI to immobilized SkM, implying SkM binds the FXI A3 domain. Studies using purified clotting factors were made to identify which FXI-related activities might be affected by SkM. When FXI activation by thrombin was evaluated under conditions where polyphosphate (PolyP) 100-mer and 700-mer enhance FXI activation, SkM concentration-dependently enhanced FXI activation by thrombin (Fig. 1B). Whereas alkaline phosphatase destroyed PolyP's ability to stimulate FXI activation by thrombin, it did not cause a reduction of SkM's ability to enhance FXI activation, indicating SkM's activity is independent of PolyP-like sequences in SkM. Small unilamellar phospholipid vesicles (20% phosphatidylserine (PS) / 80% phosphatidylcholine) did not affect FXI activation by thrombin; furthermore, reagents that neutralize procoagulant PS, i.e., lactadherin, annexin V, and phospholipase A2, did not affect SkM's enhancement of FXI activation by thrombin, indicating that this activity is not due to anionic phospholipids linked to SkM. The effects of SkM on FXI autoactivation and FXI activation by FXIIa were evaluated. As is well known, PolyP and some other anionic reagents, e.g., nucleic acid polymers, enhance not only FXI activation by thrombin but also FXI autoactivation and FXI activation by FXIIa. However, SkM did not significantly affect FXI autoactivation or FXI activation by factor XIIa, further emphasizing that SkM's enhancement of FXI activation by thrombin is not due to any PolyP-like compounds and that it is a unique property of procoagulant SkM. This also suggests that SkM has a unique mechanism for its procoagulant activity on FXI activation which is limited to the thrombin positive feedback loop. To evaluate further the basis for interactions between FXI and SkM, we employed FXI- PK chimeras because BLI binding studies showed that, in contrast to FXI, PK did not bind to SkM. Recombinant FXI proteins in which each of the four A domains of the heavy chain (designated A1 through A4) were individually replaced with the corresponding A domain from PK and were used to identify the site of factor XI to interact with SkM for FXI activation by thrombin. The FXI chimera with the substitution of the PKA1 domain was not activated by thrombin, which is consistent with the fact that the FXI A1 domain is an interactive site for thrombin. Thrombin activation of the two FXI chimeras (FXI/PKA3 and FXI/PKA4) with substitutions of either the A3 or A4 domains was not enhanced by SkM, whereas substitution of the A2 domain (FXI/PKA2) did not reduce the enhancement of activation by thrombin compared to wild type FXI. Furthermore, mAb1A6, which recognizes the A3 domain and which inhibited the prothrombotic activity of fresh blood flowing over a SkM-coated surface, potently inhibited FXI binding to SkM in BLI studies. These data strongly suggest that functional interaction sites on FXI for SkM involve the A3 and A4 domains of FXI. In summary, we found that SkM's ex vivo procoagulant activity requires FXI, that SkM enhances FXI activation by thrombin and this requires FXI's A3 and A4 domains, and that SkM's high affinity binding of FXI requires the FXI A3 domain (Fig. 1C). Figure 1 Figure 1. Disclosures Gruber: Aronora Inc.: Current Employment, Current equity holder in publicly-traded company; Oregon Health and Science University: Current Employment. Gailani: Anthos Therapeutics: Consultancy; Aronora: Membership on an entity's Board of Directors or advisory committees; Bayer Pharma: Consultancy; Bristol Myer Squibb: Consultancy, Membership on an entity's Board of Directors or advisory committees; Ionis: Consultancy; Janssen: Consultancy, Membership on an entity's Board of Directors or advisory committees.

Interferon-γ Produced by EBV-Positive Neoplastic NK-Cells Induces Differentiation into Macrophages and Procoagulant Activity of Monocytes, Which Leads to HLH

Epstein–Barr virus (EBV)-positive T- or NK-cell neoplasms show progressive systemic inflammation and abnormal blood coagulation causing hemophagocytic lymphohistiocytosis (HLH). It was reported that inflammatory cytokines were produced and secreted by EBV-positive neoplastic T- or NK-cells. These cytokines can induce the differentiation of monocytes into macrophages leading to HLH. To clarify which products of EBV-positive neoplastic T- or NK-cells have effects on monocytes, we performed a co-culture assay of monocytes with the supernatants of EBV-positive T- or NK-cell lines. The expression of differentiation markers, the phagocytosis ability, and the mRNA expression of the inflammatory cytokines of THP-1, a monocytic cell line, clearly increased after culturing with the supernatants from EBV-NK-cell lines. Co-culturing with the supernatants promoted the expression of CD80 and CD206 as well as M1 and M2 macrophage markers in human monocytes. Co-culturing with the supernatants of EBV-NK-cell lines significantly enhanced the procoagulant activity and the tissue factor expression of monocytes. Interferon (IFN)-γ was elevated extremely not only in the supernatant of EBV-NK-cell lines but also in the plasma of EBV-positive NK-cell neoplasms patients accompanying HLH. Finally, we confirmed that IFN-γ directly enhanced the differentiation into M1-like macrophages and the procoagulant activity of monocytes. Our findings suggest that IFN-γ may potentially serve as a therapeutic target to regulate HLH in EBV-positive NK-cell neoplasms.