The multiple complexes formed by the interaction of platelet factor 4 with heparin

Characterization of complexes of PF4 and heparins by size-exclusion chromatography coupled with multi-angle light scattering detector

Heparin-induced thrombocytopenia (HIT) is an immune complication of heparin therapy. Antibodies binding to complexes of platelet factor 4 (PF4) and heparin is the trigger of HIT. A method using size exclusion chromatography with multi-angle laser light scattering detector (SEC-MALS) was developed in this work. The soluble ultra-large complex (ULC) was separated from the small complex (SC) and their molecular weights (MWs) were firstly measured. The complexes of PF4 and three heparins with different MW, including unfractionated heparin (UFH), dalteparin (Daltep) and enoxaparin (Eno) were characterized using this method. The contents and the sizes of ULC increased gradually when heparins were added to PF4 to certain amounts. While, they reduced after more heparins were added. It is the first time to measure the MWs of the biggest ULC of PF4-heparins as millions of Dalton. at the proper ratios of PF4 to heparin (PHR). Meanwhile, those mixtures at those certain PHRs induced the higher expression of CD83 and CD14 markers on dendritic cells (DCs) suggesting that they had stronger immunogenicity and is critical for HIT.

Heparin-induced thrombocytopenia: An illustrated review

Heparin-induced thrombocytopenia (HIT) is an immune-mediated adverse drug effect from unfractionated or low-molecular-weight heparin that results in thrombocytopenia and potentially catastrophic thrombosis. HIT occurs due to the development of platelet-activating antibodies against multimolecular complexes of platelet factor 4 and heparin. Given the frequency of thrombocytopenia and heparin use among hospitalized patients, calculation of the 4Ts Score is recommended to identify patients at increased likelihood of HIT and direct further evaluation. In patients with an intermediate or high probability 4Ts Score, an immunoassay and functional assay are recommended to confirm or refute the diagnosis of HIT. Heparin avoidance and initiation of nonheparin anticoagulation are the mainstays of acute HIT management. In this illustrated review, we provide visual summaries of the diagnosis and management of HIT, highlighting connections between pathophysiology and clinical care as well as summarizing efforts in quality improvement in the field. We further emphasize common pitfalls and pearls in diagnosis and management to encourage evidence-based care. We include graphical representation of the unique challenges of HIT with cardiopulmonary bypass and also delineate autoimmune HIT and its subtypes.

COVID-19 vaccine-induced immune thrombotic thrombocytopenia: A review

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is a highly transmissible and pathogenic coronavirus responsible for the pandemic coronavirus disease 19 (COVID-19). It has significant impact on human health and public safety along with negative social and economic consequences. Vaccination against SARS-CoV-2 is likely the most effective approach to sustainably control the global COVID-19 pandemic. Vaccination is highly effective in reducing the risk of severe COVID-19 disease. Mass-scale vaccination will help us in attaining herd immunity and will lessen the negative impact of the disease on public health, social and economic conditions. The present pandemic stimulated the development of several effective vaccines based on different platforms. Although the vaccine is safe and efficacious, rare cases of thrombosis and thrombocytopenia following the use of vaccination with the ChAdOx1 CoV-19 vaccine (AstraZeneca, University of Oxford, and Serum Institute of India) or the Ad26.COV2.S vaccine (Janssen/Johnson & Johnson) have been reported globally. This review focussed on the definition, epidemiology, pathogenesis, clinical features, diagnosis, and management of vaccine associated thrombosis.

Low ADAMTS-13 predicts adverse outcomes in hospitalized patients with suspected heparin-induced thrombocytopenia

BACKGROUND

Heparin-induced thrombocytopenia (HIT) is a life-threatening thrombotic complication after heparin exposure. However, the role of ADAMTS-13 and von Willebrand factor (VWF) in the disease process and outcomes of HIT is not known.

OBJECTIVE

To determine the potential role of ADAMTS-13 and VWF in hospitalized patients suspected with HIT.

METHODS

Associations of the HIT tests, ADAMTS-13 activity, and VWF antigen or activity with other clinical parameters and outcomes in the patients suspected with HIT were determined.

RESULTS

Of 261 patients, 87 (33.3%) were positive and 174 (66.7%) were negative for a HIT antibody determined by an enzyme immunoassay (EIA). Of these 87 EIA+ patients, 31 (35.6%) were also positive but 56 (64.4%) were negative for serotonin-releasing assay (SRA). There was no statistically significant difference among all three groups (i.e., EIA-, EIA+/SRA+, and EIA+/SRA-) as to their demographic features, reasons for admission to the hospital, type of procedures performed, and in-hospital mortality. Compared to those in the healthy controls, plasma ADAMTS-13 activity in patients suspected with HIT was significantly lower but plasma VWF antigen (VWFAg) and activity (VWFAc) in these patients were significantly higher. While there was no statistically significant difference among all three groups regarding plasma levels of ADAMTS-13 activity, VWFAg, and VWFAc, plasma levels of ADAMTS-13 activity <50% or the low ratios of ADAMTS-13 activity to VWFAg (or VWFAc) are highly predictive for a 90-day mortality rate, particularly in the EIA+SRA+ group.

CONCLUSIONS

These results demonstrate that relative deficiency of plasma ADAMTS-13 activity in hospitalized patients suspected with HIT is common, which may contribute at least in part to the adverse outcomes in this patient population, particularly in those with true HIT.

Platelet Factor 4 Interactions with Short Heparin Oligomers: Implications for Folding and Assembly

Association of platelet factor 4 (PF4) with heparin is a first step in formation of aggregates implicated in the development of heparin-induced thrombocytopenia (HIT), a potentially fatal immune disorder affecting 1-5% of patients receiving heparin. Despite being a critically important element in HIT etiology, relatively little is known about the specific molecular mechanism of PF4-heparin interactions. This work uses native mass spectrometry to investigate PF4 interactions with relatively short heparin chains (up to decasaccharides). The protein is shown to be remarkably unstable at physiological ionic strength in the absence of polyanions; only monomeric species are observed, and the extent of multiple charging of corresponding ions indicates a partial loss of conformational integrity. The tetramer signal remains at or below the detection threshold in the mass spectra until the solution's ionic strength is elevated well above the physiological level, highlighting the destabilizing role played by electrostatic interactions vis-à-vis quaternary structure of this high-pI protein. The tetramer assembly is dramatically facilitated by relatively short polyanions (synthetic heparin-mimetic pentasaccharide), with the majority of the protein molecules existing in the tetrameric state even at physiological ionic strength. Each tetramer accommodates up to six pentasaccharides, with at least three such ligands required to guarantee the higher-order structure integrity. Similar results are obtained for PF4 association with longer and structurally heterogeneous heparin oligomers (decamers). These longer polyanions can also induce PF4 dimer assembly when bound to the protein in relatively low numbers, lending support to a model of PF4/heparin interaction in which the latter wraps around the protein, making contacts with multiple subunits. Taken together, these results provide a more nuanced picture of PF4-glycosaminoglycan interactions leading to complex formation. This work also advocates for a greater utilization of native mass spectrometry in elucidating molecular mechanisms underlying HIT, as well as other physiological processes driven by electrostatic interactions.

Heparin-induced Thrombocytopenia: Pathophysiology, Diagnosis and Management

Heparin-induced thrombocytopenia (HIT), even rare, is a life-threatening, immune-mediated complication of heparin exposure. It is considered the most severe non-bleeding adverse reaction of heparin treatment and one of the most important adverse drug reactions. The pathophysiological basis of HIT results from the formation of an immunocomplex consisting of an auto-antibody against platelet factor 4 (PF4) - heparin complex, which binds to the surface of platelets and monocytes, provoking their activation by cross-linking FcgIIA receptors. Platelets and monocyte activation, leads to the generation of catastrophic arterial and venous thrombosis, with a mortality rate of 20%, without early recognition. The definitive diagnosis of HIT i.e., clinical and laboratory evidence, can not be done at the onset of symptoms because laboratory results may not be available for several days. Thus, the initial approach is to predict the likelihood of HIT, because in highly suspected patients immediate heparin cessation and initiation of alternative anticoagulation treatment are crucial for the prevention of the devastating thrombotic sequelae. Herein, we describe the pathophysiology, the clinical manifestations, the diagnostic approach, and the management of patients with HIT.

Biophysical tools to assess the interaction of PF4 with polyanions

The antigen in heparin-induced thrombocytopenia (HIT) is expressed on platelet factor 4 (PF4) when PF4 complexes with polyanions. In recent years, biophysical tools (e. g. circular dichroism spectroscopy, atomic force microscopy, isothermal titration calorimetry, x-ray crystallography, electron microscopy) have gained an important role to complement immunological and functional assays for better understanding the interaction of heparin with PF4. This allowed identification of those features that make PF4 immunogenic (e. g. a certain conformational change induced by the polyanion, a threshold energy of the complexes, the existence of multimeric complexes, a certain number of bonds formed by PF4 with the polyanion) and to characterize the morphology and thermal stability of complexes formed by the protein with polyanions. These findings and methods can now be applied to test new drugs for their potential to induce the HIT-like adverse drug effect by preclinical in vitro testing. The methods and techniques applied to characterize the antigen in HIT may also be helpful to better understand the mechanisms underlying other antibody-mediated disorders in thrombosis and hemostasis (e. g. acquired hemophilia, thrombotic thrombocytopenic purpura). Furthermore, understanding the mechanisms making the endogenous protein PF4 immunogenic may help to understand the mechanisms underlying other autoimmune disorders.

Heparin: new life for an old drug

Heparin is one of the oldest drugs, which nevertheless remains in widespread clinical use as an inhibitor of blood coagulation. The history of its identification a century ago unfolded amid one of the most fascinating scientific controversies turning around the distribution of credit for its discovery. The composition, purification and structure-function relationship of this naturally occurring glycosaminoglycan regarding its classical role as anticoagulant will be dealt with before proceeding to discuss its therapeutic potential in, among other, inflammatory and infectious disease, cancer treatment, cystic fibrosis and Alzheimer's disease. The first bibliographic reference hit using the words 'nanomedicine' and 'heparin' is as recent as 2008. Since then, nanomedical applications of heparin have experienced an exponential growth that will be discussed in detail, with particular emphasis on its antimalarial activity. Some of the most intriguing potential applications of heparin nanomedicines will be exposed, such as those contemplating the delivery of drugs to the mosquito stages of malaria parasites.

Heparin-induced thrombocytopenia. Blood. 2017;129:2864-2872. [PMID: 28416511 DOI: 10.1182/blood-2016-11-709873]

Heparin-induced thrombocytopenia (HIT) is an immune complication of heparin therapy caused by antibodies to complexes of platelet factor 4 (PF4) and heparin. Pathogenic antibodies to PF4/heparin bind and activate cellular FcγRIIA on platelets and monocytes to propagate a hypercoagulable state culminating in life-threatening thrombosis. It is now recognized that anti-PF4/heparin antibodies develop commonly after heparin exposure, but only a subset of sensitized patients progress to life-threatening complications of thrombocytopenia and thrombosis. Recent scientific developments have clarified mechanisms underlying PF4/heparin immunogenicity, disease susceptibility, and clinical manifestations of disease. Insights from clinical and laboratory findings have also been recently harnessed for disease prevention. This review will summarize our current understanding of HIT by reviewing pathogenesis, essential clinical and laboratory features, and management.

The antigenic complex in HIT binds to B cells via complement and complement receptor 2 (CD21)

Heparin-induced thrombocytopenia is a prothrombotic disorder caused by antibodies to platelet factor 4 (PF4)/heparin complexes. The mechanism that incites such prevalent anti-PF4/heparin antibody production in more than 50% of patients exposed to heparin in some clinical settings is poorly understood. To investigate early events associated with antigen exposure, we first examined the interaction of PF4/heparin complexes with cells circulating in whole blood. In healthy donors, PF4/heparin complexes bind preferentially to B cells (>90% of B cells bind to PF4/heparin in vitro) relative to neutrophils, monocytes, or T cells. Binding of PF4 to B cells is heparin dependent, and PF4/heparin complexes are found on circulating B cells from some, but not all, patients receiving heparin. Given the high proportion of B cells that bind PF4/heparin, we investigated complement as a mechanism for noncognate antigen recognition. Complement is activated by PF4/heparin complexes, co-localizes with antigen on B cells from healthy donors, and is present on antigen-positive B cells in patients receiving heparin. Binding of PF4/heparin complexes to B cells is mediated through the interaction between complement and complement receptor 2 (CR2 [CD21]). To the best of our knowledge, these are the first studies to demonstrate complement activation by PF4/heparin complexes, opsonization of PF4/heparin to B cells via CD21, and the presence of complement activation fragments on circulating B cells in some patients receiving heparin. Given the critical contribution of complement to humoral immunity, our observations provide new mechanistic insights into the immunogenicity of PF4/heparin complexes.

Non-anticoagulant derivatives of heparin for the management of asthma: distant dream or close reality?

INTRODUCTION

Approximately 300 million people worldwide are currently affected by asthma. Improvements in the understanding of the mechanisms involved in such inflammatory airway disorders has led to the recognition of new therapeutic approaches. Heparin, a widely used anticoagulant, has been shown to be beneficial in the management of asthma. It belongs to the family of highly sulphated polysaccharides referred to as glycosaminoglycans, containing a heterogeneous mixture of both anticoagulant and non-anticoagulant polysaccharides. Experimental findings have suggested that heparin has potential anti-asthmatic properties owing to the ability of its non-anticoagulant oligosaccharides to bind and modulate the activity of a wide range of biological molecules involved in the inflammatory process.

AREAS COVERED

This review focuses on the potential mechanisms of action and clinical application of heparin as an anti-inflammatory agent for the management of asthma.

EXPERT OPINION

Heparin may play a significant role in the management of asthma. However, these properties are often hindered by the presence of anticoagulant oligosaccharides, which possess a significant risk of bleeding. Therefore, its therapeutic potential must be explored using well-designed clinical studies that focus on identifying and isolating the anti-inflammatory oligosaccharides of heparin and further elucidating the structure and mechanisms of actions of these non-anticoagulant oligosaccharides.

Emphasis on the Role of PF4 in the Incidence, Pathophysiology and Treatment of Heparin Induced Thrombocytopenia

Heparin Induced Thrombocytopenia (HIT) is caused by antibodies that recognize platelet factor 4 (PF4) associated with polyanionic glycosaminoglycan drugs or displayed on vascular cell membranes. These antibodies are elicited by multimolecular complexes that can occur when heparin is administered in clinical settings associated with abundant PF4. Heparin binding alters native PF4 and elicits immune recognition and response. While the presence of heparin is integral to immunogenesis, the HIT antibody binding site is within PF4. Thus HIT antibodies develop and function to cause thrombocytopenia and/or thrombosis only in the presence of PF4. Future emphasis on understanding the biology, turnover and regulation of PF4 may lead to insights into the prevention and treatment of HIT.

Antigen and substrate withdrawal in the management of autoimmune thrombotic disorders

Prevailing approaches to manage autoimmune thrombotic disorders, such as heparin-induced thrombocytopenia, antiphospholipid syndrome and thrombotic thrombocytopenic purpura, include immunosuppression and systemic anticoagulation, though neither provides optimal outcome for many patients. A different approach is suggested by the concurrence of autoantibodies and their antigenic targets in the absence of clinical disease, such as platelet factor 4 in heparin-induced thrombocytopenia and β(2)-glycoprotein-I (β(2)GPI) in antiphospholipid syndrome. The presence of autoantibodies in the absence of disease suggests that conformational changes or other alterations in endogenous protein autoantigens are required for recognition by pathogenic autoantibodies. In thrombotic thrombocytopenic purpura, the clinical impact of ADAMTS13 deficiency caused by autoantibodies likely depends on the balance between residual antigen, that is, enzyme activity, and demand imposed by local genesis of ultralarge multimers of von Willebrand factor. A corollary of these concepts is that disrupting platelet factor 4 and β(2)GPI conformation (or ultralarge multimer of von Willebrand factor oligomerization or function) might provide a disease-targeted approach to prevent thrombosis without systemic anticoagulation or immunosuppression. Validation of this approach requires a deeper understanding of how seemingly normal host proteins become antigenic or undergo changes that increase antibody avidity, and how they can be altered to retain adaptive functions while shedding epitopes prone to elicit harmful autoimmunity.

Dynamic antibody-binding properties in the pathogenesis of HIT

Rapid laboratory assessment of heparin-induced thrombocytopenia (HIT) is important for disease recognition and management. The utility of contemporary immunoassays to detect antiplatelet factor 4 (PF4)/heparin antibodies is hindered by detection of antibodies unassociated with disease. To begin to distinguish properties of pathogenic anti-PF4/heparin antibodies, we compared isotype-matched monoclonal antibodies that bind to different epitopes: KKO causes thrombocytopenia in an in vivo model of HIT, whereas RTO does not. KKO binding to PF4 and heparin is specifically inhibited by human HIT antibodies that activate platelets, whereas inhibition of RTO binding is not differentially affected. Heparin increased the avidity of KKO binding to PF4 without affecting RTO, but it did not increase total binding or binding to nontetrameric PF4(K50E). Single-molecule forced unbinding demonstrated KKO was 8-fold more reactive toward PF4 tetramers and formed stronger complexes than RTO, but not to PF4(K50E) dimers. KKO, but not RTO, promoted oligomerization of PF4 but not PF4(K50E). This study reveals differences in the properties of anti-PF4 antibodies that cause thrombocytopenia not revealed by ELISA that correlate with oligomerization of PF4 and sustained high-avidity interactions that may simulate transient antibody-antigen interactions in vivo. These differences suggest the potential importance of epitope specificity in the pathogenesis of HIT.

Rational design and characterization of platelet factor 4 antagonists for the study of heparin-induced thrombocytopenia

Patients with heparin-induced thrombocytopenia (HIT) remain at risk for recurrent thromboembolic complications despite improvements in management. HIT is caused by antibodies that preferentially recognize ultralarge complexes (ULCs) of heparin and platelet factor 4 (PF4) tetramers. We demonstrated previously that a variant PF4(K50E) forms dimers but does not tetramerize or form ULCs. Here, we identified small molecules predicted to bind PF4 near the dimer-dimer interface and that interfere with PF4 tetramerization. Screening a library of small molecules in silico for binding at this site, we identified 4 compounds that inhibited tetramerization at micromolar concentrations, designated PF4 antagonists (PF4As). PF4As also inhibited formation of pathogenic ULCs, and 3 of these PF4As promoted the breakdown of preformed ULCs. To characterize the ability of PF4As to inhibit cellular activation, we developed a robust and reproducible assay that measures cellular activation by HIT antibodies via FcγRIIA using DT40 cells. PF4As inhibit FcγRIIA-dependent activation of DT40 cells by HIT antibodies as well as platelet activation, as measured by serotonin release. PF4As provide new tools to probe the pathophysiology of HIT. They also may provide insight into the development of novel, disease-specific therapeutics for the treatment of thromboembolic complications in HIT.

Platelet factor 4 inhibits thrombomodulin-dependent activation of thrombin-activatable fibrinolysis inhibitor (TAFI) by thrombin

Thrombomodulin (TM) is a cofactor for thrombin-mediated activation of protein C and thrombin-activatable fibrinolysis inhibitor (TAFI) and thereby helps coordinate coagulation, anticoagulation, fibrinolysis, and inflammation. Platelet factor 4 (PF4), a platelet α-granule protein and a soluble cofactor for TM-dependent protein C activation, stimulates protein C activation in vitro and in vivo. In contrast to stimulation of protein C activation, PF4 is shown here to inhibit activation of TAFI by thrombin-TM. Consequences of inhibition of TAFI activation by PF4 included loss of TM-dependent prolongation of clot lysis times in hemophilia A plasma and loss of TM-stimulated conversion of bradykinin (BK) to des-Arg(9)-BK by TAFIa in normal plasma. Thus, PF4 modulates the substrate specificity of the thrombin-TM complex by selectively enhancing protein C activation while inhibiting TAFI activation, thereby preventing the generation of the antifibrinolytic and anti-inflammatory activities of TAFIa. To block the inhibitory effects of PF4 on TAFI activation, heparin derivatives were tested for their ability to retain high affinity binding to PF4 despite having greatly diminished anticoagulant activity. N-acetylated heparin (NAc-Hep) lacked detectable anticoagulant activity in activated partial thromboplastin time clotting assays but retained high affinity binding to PF4 and effectively reversed PF4 binding to immobilized TM. NAc-Hep permitted BK conversion to des-Arg(9)-BK by TAFIa in the presence of PF4. In a clot lysis assay on TM-expressing cells using hemophilia A plasma, NAc-Hep prevented PF4-mediated inhibition of TAFI activation and the antifibrinolytic functions of TAFIa. Accordingly, NAc-Hep or similar heparin derivatives might provide therapeutic benefits by diminishing bleeding complications in hemophilia A via restoration of TAFIa-mediated protection of clots against premature lysis.

Heparin modifies the immunogenicity of positively charged proteins

The immune response in heparin-induced thrombocytopenia is initiated by and directed to large multimolecular complexes of platelet factor 4 (PF4) and heparin (H). We have previously shown that PF4:H multimolecular complexes assemble through electrostatic interactions and, once formed, are highly immunogenic in vivo. Based on these observations, we hypothesized that other positively charged proteins would exhibit similar biologic interactions with H. To test this hypothesis, we selected 2 unrelated positively charged proteins, protamine (PRT) and lysozyme, and studied H-dependent interactions using in vitro and in vivo techniques. Our studies indicate that PRT/H and lysozyme/H, like PF4/H, show H-dependent binding over a range of H concentrations and that formation of complexes occurs at distinct stoichiometric ratios. We show that protein/H complexes are capable of eliciting high-titer antigen-specific antibodies in a murine immunization model and that PRT/H antibodies occur in patients undergoing cardiopulmonary bypass surgery. Finally, our studies indicate that protein/H complexes, but not uncomplexed protein, directly activate dendritic cells in vitro leading to interleukin-12 release. Taken together, these studies indicate that H significantly alters the biophysical and biologic properties of positively charged compounds through formation of multimolecular complexes that lead to dendritic cell activation and trigger immune responses in vivo.

Determinants of PF4/heparin immunogenicity

Heparin-induced thrombocytopenia (HIT) is an antibody-mediated disorder that occurs with variable frequency in patients exposed to heparin. HIT antibodies preferentially recognize large macromolecular complexes formed between PF4 and heparin over a narrow range of molar ratios, but the biophysical properties of complexes that initiate antibody production are unknown. To identify structural determinants underlying PF4/heparin immunogenicity, we characterized the in vitro interactions of murine PF4 (mPF4) and heparin with respect to light absorption, size, and surface charge (zeta potential). We show that PF4/heparin macromolecular assembly occurs through colloidal interactions, wherein heparin facilitates the growth of complexes through charge neutralization. The size of PF4/heparin macromolecules is governed by the molar ratios of the reactants. Maximal complex size occurs at molar ratios of PF4/heparin at which surface charge is neutral. When mice are immunized with complexes that differ in size and/or zeta potential, antibody formation varies inversely with heparin concentration and is most robust in animals immunized with complexes displaying a net positive zeta-potential. These studies suggest that the clinical heterogeneity in the HIT immune response may be due in part to requirements for specific biophysical parameters of the PF4/heparin complexes that occur in settings of intense platelet activation and PF4 release.

Influence of sample collection and storage on the detection of platelet factor 4-heparin antibodies

Heparin-induced thrombocytopenia is a life threatening thrombotic disorder caused by antibodies to platelet factor 4 (PF4) and heparin. Commercial immunoassays are frequently used for the detection of PF4-heparin antibodies, and several studies have reported that higher antibody titers are more frequently associated with adverse events. It is not known if conditions involving sample preparation and/or storage affect the operational characteristics of PF4-heparin immunoassays. We compared the detection of PF4-heparin antibodies from 48 patient samples collected concordantly in serum separator tubes or tubes containing EDTA or sodium citrate. We also examined the effects of extended sample storage on whole blood collected in serum separator, EDTA, or citrate tubes at 4 degrees C for up to 96 hours on antibody detection. We noted that serum or plasma anticoagulated with sodium citrate or EDTA yielded comparable results. In addition, we could not demonstrate any significant sample deterioration after storage at 4 degrees C in any medium for up to 4 days. These findings suggest that PF4-heparin antibodies are largely insensitive to the effects of sample preparation and storage.

Roles of platelet factor 4 in hematopoiesis and angiogenesis

Platelet factor 4 (PF4) has been recognized as a physiological inhibitor of megakaryocytopoiesis and angiogenesis for two decades. Structure-function studies have shown that the DLQ determinant in position 54-56 is necessary for megakaryocytic inhibition whereas mutations of these residues into ELR sequence and more importantly, into DLR sequence, induce a stronger inhibitory activity of peptide p47-70 on angiogenesis. The alpha-helix region of peptides may participate in the fixation of the effector to its cellular receptor and the other important structural domains would activate the receptor. In vivo, PF4 and its related peptides can protect hematopoiesis from chemotherapy by enhancing cell viability and suppress tumor growth through anti-angiogenic pathway. Several PF4 fragments and modified molecules exhibit antiangiogenesis properties and may become an alternative for further therapeutic angiogenesis.

Ultralarge complexes of PF4 and heparin are central to the pathogenesis of heparin-induced thrombocytopenia

Heparin-induced thrombocytopenia and thrombosis (HITT) is a severe complication of heparin therapy caused by antibodies to complexes between unfractionated heparin (UFH) and platelet factor 4 (PF4) that form over a narrow molar range of reactants and initiate antibody-induced platelet activation. We observed that UFH and tetrameric PF4 formed ultralarge (> 670 kDa) complexes (ULCs) only over a narrow molar range with an optimal ratio of PF4 to heparin of approximately 1:1. These ULCs were stable and visible by electron microscopy, but they could be dissociated into smaller complexes upon addition of heparin. ULCs formed inefficiently when PF4 was incubated with low-molecular-weight heparin, and none formed with the pentasaccharide fondaparinux sodium. In addition, mutation studies showed that formation of ULCs depended on the presence of PF4 tetramers. The ULCs were more reactive as determined by their capacity to bind to a HITT-like monoclonal antibody and showed greater capacity to promote platelet activation in an antibody- and FcgammaRIIA-dependent manner than were the smaller complexes. The capacity of PF4 to form ULCs composed of multiple PF4 tetramers arrayed in a lattice with several molecules of UFH may play a fundamental role in autoantibody formation, antibody-dependent platelet activation, and the propensity for thrombosis in patients with HITT.

Platelet factor 4 binds to low-density lipoprotein receptors and disrupts the endocytic machinery, resulting in retention of low-density lipoprotein on the cell surface

The influence of platelets on the cellular metabolism of atherogenic lipoproteins has not been characterized in detail. Therefore, we investigated the effect of platelet factor 4 (PF4), a cationic protein released in high concentration by activated platelets, on the uptake and degradation of low-density lipoprotein (LDL) via the LDL receptor (LDL-R). LDL-R-dependent binding, internalization, and degradation of LDL by cultured cells were inhibited 50%, 80%, and 80%, respectively, on addition of PF4. PF4 bound specifically to the ligand-binding domain of recombinant soluble LDL-R (half-maximal binding 0.5 microg/mL PF4) and partially (approximately 50%) inhibited the binding of LDL. Inhibition of internalization and degradation by PF4 required the presence of cell-associated proteoglycans, primarily those rich in chondroitin sulfate. PF4 variants with impaired heparin binding lacked the capacity to inhibit LDL. PF4, soluble LDL-R, and LDL formed ternary complexes with cell-surface proteoglycans. PF4 induced the retention of LDL/LDL-R complexes on the surface of human fibroblasts in multimolecular clusters unassociated with coated pits, as assessed by immuno-electron microscopy. These studies demonstrate that PF4 inhibits the catabolism of LDL in vitro in part by competing for binding to LDL-R, by promoting interactions with cell-associated chondroitin sulfate proteoglycans, and by disrupting the normal endocytic trafficking of LDL/LDL-R complexes. Retention of LDL on cell surfaces may facilitate proatherogenic modifications and support an expanded role for platelets in the pathogenesis of atherosclerosis.

Drug-induced and drug-dependent immune thrombocytopenias

Thrombocytopenia is a frequent comorbid condition in many in hospital patients. In some patients, drugs are the cause of low platelet counts. While cytotoxic effects of anti-tumor therapy are the most frequent cause, immune mechanisms should also be considered. This review addresses thrombocytopenias in four groups. Heparin-dependent thrombocytopenia (HIT), by far the most frequent drug-induced immune-mediated type of thrombocytopenia, has a unique pathogenesis and clinical consequences. HIT is a clinicopathological syndrome in which antibodies mostly directed against a multimolecular complex of platelet factor 4 and heparin cause paradoxical thromboembolic complications. The mechanisms through which heparin can enhance thrombin generation are discussed and treatment alternatives for affected patients are presented in detail. It is of primary importance to recognize these patients as early as possible and to substitute heparin with a compatible anticoagulatory drug, such as hirudin, danaparoid or argatroban. Patients seem to benefit from therapeutic doses of alternative treatment rather than from low-dose prophylactic doses. With the increasing use of glycoprotein (GP) IIb/IIIa inhibitors in patients with acute coronary syndromes, thrombocytopenias are increasingly recognized as an adverse effect of these drugs. Up to 4% of treated patients are affected. Most important, pseudothrombocytopenia, a laboratory artefact, is as frequent as real drug-induced thrombocytopenia and must be excluded before changes in treatment are considered. The pathogenesis of these thrombocytopenias is still debated; an immune mechanism involving preformed antibodies is likely. However, since these antibodies are also detectable in a high percentage of normal controls and of patients not developing thrombocytopenia, their impact is still unclear. Patients with real thrombocytopenia are at an increased risk of bleeding; treatment consists of cessation of the GP IIb/IIIa inhibitor and platelet transfusions in cases of severe hemorrhage. Classic immune thrombocytopenia can be induced by some drugs, e.g. gold, which trigger anti-platelet antibodies indistinguishable from platelet autoantibodies found in autoimmune thrombocytopenia. Drug-induced and drug-dependent immune thrombocytopenia is induced by antibodies recognizing an epitope on platelet GP formed after binding of a drug to a platelet glycoprotein. Still unresolved is whether antibody binding is the consequence of a conformational change of the antigen, the antibody, or both. These antibodies typically react with monomorphic epitopes on platelet GP, but only in the presence of the drug or a metabolite. Although several platelet GP have been identified as antibody target (GPIb/IX, GPV, GP IIb/IIIa), antibodies in an individual patient are highly specific for a single GP. Clinically, these patients present with very low platelet counts and acute, sometimes severe, hemorrhage. Treatment is restricted to withdrawal of the drug and symptomatic treatment of bleeding.

Hirudin in Acute Myocardial Infarction

The central role of thrombosis in the pathogenesis of acute myocardial infarction has led to intense interest in developing more effective thrombolytic-antithrombotic regimens. Hirudin is 65 amino acid polypeptide that binds in a 1:1 relationship with thrombin, thereby inhibiting the final step in the coagulation cascade. Hirudin has several potential advantages over the current antithrombin agent heparin: It is a direct inhibitor that does not require a cofactor, it has no known inhibitors that would attentuate its anticoagulant effects, and it can inhibit clot-bound thrombin, thereby achieving an antithrombotic effect at the site of potential rethrombosis. Initial clinical trials have shown promising results: Hirudin, as compared with heparin, provided a more consistent level of anticoagulation, as gauged by the activated partial thromboplastin time. As an adjunct to thrombolytic therapy in acute myocardial infarction, hirudin improved indices of coronary reperfusion and patency. Initial results with clinical end points, including death or myocardial infarction, also have shown favorable results for hirudin compared with heparin. In the first phases of the larger phase III trials, the rate of hemorrhagic events, including intracranial hemorrhage, was higher than expected in both the hirudin and heparin arms, indicating that a safety ceiling had been reached. The TIMI 9B and GUSTO IIb trials are using lower doses of intravenous hirudin and heparin, which should allow testing of the "thrombin hypothesis": that more potent inhibition of thrombin will translate into improved clinical outcome for patients with acute MI.

Platelet Activation Determined by Flow Cytometry Persists Despite Antithrombotic Therapy in Patients with Unstable Angina and Non-Q-Wave Myocardial Infarction

Background: Current strategies in the treatment of patients with acute coronary syndromes include antiplatelet agents and thrombin antagonists, most commonly aspirin and heparin, respectively. Cardiac events, however, occur despite what is considered to be maximal medical treatment. Methods: We determined the percentage of activated platelets in whole blood samples taken from 22 patients with unstable angina and non-Q-wave myocardial infarection participating in the TIMI III B trial. Platelet activation was assessed using a monoclonal antibody to the surface-expressed alpha-granule protein, P-selectin, and flow cytometry. All patients received a full complement of antiischemic medications as well as intravenous heparin and oral aspirin, and were then randomized to tissue plasminogen activator or placebo. Results: Platelet activation prior to randomization was increased threefold to fourfold compared with healthy volunteers (11.4 +/- 11.4% vs. 2.0%; p < 0.01). Serial measurements performed 12, 24, 48, and 96 hours after treatment initiation revealed that platelet activation persisted. No differences in patients experiencing recurrent ischomic events (n = 9) or those randomized to a 90-minute, accelerated infusion of tissue plasminogen activator (n = 12) were observed. Conclusions: A modest degree of platelet activation is seen for at least 96 hours and possibly longer in patients with unstable angina and non-Q-wave myocardial infarction, despite being treated with intravenous heparin and oral aspirin. These findings support current efforts to identify more potent and selective antithrombotic treatment strategies.

Low molecular weight heparin in acute coronary syndromes

Traditionally, unfractionated heparin has played an important role in the treatment of acute coronary syndromes. Low molecular weight heparin (LMWH), is a promising new type of heparin, which is fractionated to include only heparin molecules of lower molecular weight. LMWHs are administered subcutaneously and do not require monitoring of the activated partial thromboplastin time, making them much easier to use. LMWHs are combined inhibitors of both thrombin and Factor Xa inhibitors. Several recent large trials in unstable angina and non-Q wave myocardial infarction have shown that LMWH is effective, and one agent has been shown to be superior to unfractionated heparin in reducing death, myocardial infarction, or recurrent angina. They also are very low cost (approximately $50 per day) and appear to be very cost effective in the treatment of unstable angina. Thus, LMWHs appear to be the new anticoagulant agent in acute coronary syndromes.

Heparin binding to cobra basic phospholipase A2 depends on heparin chain length and amino acid specificity

Heparin is shown to bind specifically to the carboxy-terminal region of toxic type I phospholipase A2 from Naja nigricollis (N-PLA2) by competition assay using synthetic polypeptides and heparin affinity chromatography. The binding strength is seen to depend on heparin chain length and the presence of N-sulfate groups of heparin. It is observed that both electrostatic and non-electrostatic interactions are involved in the specific binding of heparin to the carboxy-terminus. When heparin's size is at least a decasaccharide, about two molecules of N-PLA2 bind to one molecule of heparin, as evidenced by the chemical estimate of protein to carbohydrate ratio in such N-PLA2/heparin complexes. Based on such a stoichiometric measurement and computer modeling of the N-PLA2/heparin complex, it is suggested that the binding sites of the two N-PLA2 molecules on one heparin molecule lie on the opposite sides of the heparin chain.

Simultaneous binding of heparin and platelet factor-4 to platelets: further insights into the mechanism of heparin-induced thrombocytopenia

Heparin-induced thrombocytopenia (HIT) is mediated by antibody against complexes of platelet factor-4 (PF4) and heparin. Although it has been assumed that these complexes bind to platelets and provide a target for the antibody, this has never been demonstrated. Furthermore, there is evidence suggesting that heparin-PF4 complexes do not bind to platelets. We have analyzed the effect of each ligand on the platelet binding of the other. We particularly focused on the result when heparin and PF4 are in equimolar concentration because we had previously shown that this was the condition under which HIT-IgG increased on the platelet surface. We found that when the molar concentration of PF4 approximates or exceeds that of heparin, the ligands bind simultaneously to the cells and HIT-IgG binds also. However, when heparin is in molar excess, both PF4 binding and HIT-IgG binding are diminished. Our data are consistent with the hypothesis that heparin-PF4 complexes bind via their heparin component to heparin binding sites on the platelet membrane rather than by their PF4 component to PF4 sites. The conditions promoting the binding of the complexes also lead to binding of HIT-IgG.

Dissolution of mural thrombus by specific thrombin inhibition with r-hirudin: comparison with heparin and aspirin

BACKGROUND

The presence of residual mural thrombus may predispose to recurrent thrombotic events in acute coronary syndromes. The purpose of this study was to evaluate the effects of antithrombotic and antiplatelet agents on a preformed, fresh mural thrombus during growth of thrombus.

METHODS AND RESULTS

A fresh mural thrombus was formed by perfusing severely injured arterial wall with porcine blood for 5 minutes at a shear rate of 1690 s(-1). Thrombus formation was measured by morphometric analysis (mm2/mm). The average size of a mural thrombus formed in 5 minutes was 0.14+/-0.03 mm2/mm. Progression of thrombus growth within 10 minutes triggered by the preformed thrombus was evaluated in pigs treated with r-hirudin (1 mg/kg per hour i.v.) as a probe for thrombin, high-dose heparin (250 IU/kg per hour i.v.), moderate-dose heparin (100 IU/kg per hour), moderate-dose heparin (100 IU/kg per hour) plus aspirin, aspirin alone (5 mg/kg i.v.), and placebo. Hirudin was associated with a significant decrease (48%) of mural thrombus area and significantly reduced growth of thrombus (0.07+/-0.01), even compared with the highest dose of heparin (0.15+/-0.03), although at lower levels of anticoagulation. Inhibition of growth of thrombus with heparin was dose dependent, showing an inverse correlation of thrombus area with mean plasma heparin concentrations (r=.77, P=.0001). Thrombus size was unchanged by aspirin (0.29+/-0.07) compared with controls (0.28+/-0.07).

CONCLUSIONS

Direct inhibition of thrombin activity with r-hirudin completely inhibits growth of thrombus, causes dissolution of a preexisting mural thrombus, and is more effective at lower levels of anticoagulation than the highest dose of heparin at shear rates typical of a moderate coronary stenosis.

Specific binding of the chemokine platelet factor 4 to heparan sulfate

Platelet factor 4 is a tetrameric heparin binding chemokine released from the alpha-granules of activated platelets. In this study we show that platelet factor 4 binds with high affinity and specificity to an approximately 9-kDa sequence in heparan sulfate, which it protects from degradation by heparinase enzymes. This protected fragment is enriched in N-sulfated disaccharides and iduronate 2-O-sulfate residues, the latter being important for binding to platelet factor 4. The major structural motif of the fragment appears to consist of a pair of sulfated domains positioned at both ends separated by a central mainly N-acetylated region. On the basis of these findings, we propose a model in which the heparan sulfate fragment wraps around the ring of positive charges on platelet factor 4 with the iduronate 2-O-sulfates within the sulfated domains binding strongly to lysine clusters on opposite faces of the tetramer.

Heparin and heparan sulfate bind to snake cardiotoxin. Sulfated oligosaccharides as a potential target for cardiotoxin action

Cardiotoxins (CTXs) from cobra venom show cytotoxicity toward several cell types. They cause systolic heart arrest and severe tissue necrosis. Their interaction with phospholipids is established but by itself fails to explain the specificity of these toxins; other component(s) of membrane must, therefore, intervene to direct them toward their target. We herein show, for the first time, that sulfated glycosaminoglycans, heparin, heparan sulfate (HS), chondroitin sulfate (CS), and dermatan sulfate (DS), interact with CTX A3, a major component of Taiwan cobra venom, by use of affinity chromatography, circular dichroism, absorbance, and fluorescence intensity and anisotropy measurements. The relative strength of binding, determined by the NaCl concentration required to dissociate the CTX-glycosaminoglycan complex, varied as follows: heparin > DS > CS > HS. In physiological buffer (8 mM Na2HPO4, 2.7 mM KCl, 1.8 mM KH2PO4, 138 mM NaCl, pH 7.4), however, only heparin and HS bound to CTX, with respective dissociation constants of 1.4 and 16 microM, while CS and DS failed to exhibit well defined binding behavior, as indicated by fluorescence measurements. We estimate that CTX makes 3-4 ionic contacts with heparin based on a salt-dependent binding study and that approximately 40% of binding free energy is derived from purely electrostatic interactions under physiological conditions. Sulfated pentasaccharide may be sufficient to bind to CTX. We also found that heparin accentuates the penetration of CTX into phospholipid membranes as analyzed by Langmuir monolayer measurement. In view of these results we propose that heparin-like moieties of the cell surface may modulate the action of CTX.

Structure and bioactivity of recombinant human CTAP-III and NAP-2

Connective tissue-activating peptide III (CTAP-III) and neutrophil-activating peptide-2 (NAP-2) are both derived from a common precursor, platelet basic protein (PBP), which is stored in the alpha-granules of platelets and released upon their activation. CTAP-III is an 85-residue peptide which is converted to NAP-2 by enzymic removal of the 15 amino-terminal residues. Both peptides play a role in the early stages of wound healing and inflammation through different activities. We have cloned the cDNA for PBP and expressed constructs coding for the CTAP-III and NAP-2 polypeptides in Escherichia coli. We have purified and renatured these recombinant proteins. The integrity of the recombinant proteins has been ascertained by in vitro bioassays. CTAP-III causes 51% histamine release from the basophilic cell lin KU812 at 10(-7) M, whereas NAP-2 only causes 28% release at the same concentration. In assays on human neutrophils, NAP-2 had an EC50 of 2 x 10(-8) M in chemotaxis, an EC50 of 3 x 10(-8) M for shape change, and could displace IL-8 from neutrophils with a Kd of 7.5 x 10(-9) M. CTAP-III had no activity in these assays. The disulfide bonds have been identified by peptide mapping and sequence analysis, and are in the positions predicted by homology to interleukin-8 and platelet factor 4. Measurement of the molecular mass at physiologic concentrations by gel permeation chromatography has shown that CTAP-III forms predominantly tetramers and dimers, whereas NAP-2 is only dimetric. SDS/PAGE analysis of samples cross-linked with disuccinimidyl suberate support these topologies. We postulate a mechanism for tetramer formation based on the interaction of the amino-terminal extension in CTAP-III involving a helix-helix interaction that could stabilize the association of two CTAP-III dimers.

Does antithrombotic therapy influence residual thrombus after thrombolysis of platelet-rich thrombus? Effects of recombinant hirudin, heparin, or aspirin

BACKGROUND

Thrombolysis to normal flow in patients with acute myocardial infarction preserves left ventricular function and decreases mortality. Failure of early reperfusion, reocclusion, or residual thrombus may be due to concurrent activation of the platelet-coagulation system. Thus, we hypothesized that the best concomitant antithrombotic therapy (recombinant [r]-hirudin, heparin, or aspirin) will maximally accelerate thrombolysis by r-tissue-type plasminogen activator (rTPA) and reduce residual thrombus.

METHODS AND RESULTS

Occlusive thrombi were formed in the carotid arteries of 29 pigs (by balloon dilatation followed by endarterectomy at the site of injury-induced vasospasm) and matured for 30 minutes before rTPA was started, with or without antithrombotic therapy. Thrombolysis was assessed with the use of angiography and measurement of residual thrombus. Pigs were allocated to one of five treatments: placebo, rTPA, rTPA plus r-hirudin, rTPA plus heparin, or rTPA plus intravenous aspirin. No placebo-treated pig reperfused. Two of six animals treated with rTPA alone reperfused compared with seven of seven animals treated with rTPA plus r-hirudin (reperfusion time, 33 +/- 10 minutes), six of seven animals treated with rTPA plus heparin (reperfusion time, 110 +/- 31 minutes), and two of six animals with rTPA plus aspirin. The activated partial thromboplastin time was prolonged in only the rTPA plus r-hirudin group (25 +/- 0.1 times baseline) and the rTPA plus heparin group (5.3 +/- 0.2 times baseline). Residual 111In-platelet and 125I-fibrin(ogen) depositions were lower in the heparin-treated group and lowest in the r-hirudin-treated group (heparin versus hirudin, respectively; incidence of residual macroscopic thrombus was six of six animals versus two of seven [P = .01]; 125I-fibrin(ogen), 170 +/- 76 versus 48 +/- 6 x 10(6) molecules/cm2 [P = .02]; 111In-platelets, 47 +/- 15 versus 13 +/- 2 x 10(6)/cm2, P = .10). No pigs developed spontaneous bleeding.

CONCLUSIONS

Thrombin inhibition with heparin or r-hirudin significantly accelerated thrombolysis of occlusive platelet-rich thrombosis, but only the best antithrombotic therapy (r-hirudin) eliminated or nearly eliminated residual thrombus.

Heparin binding to platelet factor-4. An NMR and site-directed mutagenesis study: arginine residues are crucial for binding

Native platelet factor-4 (PF4) is an asymmetrically associated, homo-tetrameric protein (70 residues/subunit) known for binding polysulphated glycosaminoglycans like heparin. PF4 N-terminal chimeric mutant M2 (PF4-M2), on the other hand, forms symmetric tetramers [Mayo, Roongta, Ilyina, Milius, Barker, Quinlan, La Rosa and Daly (1995) Biochemistry 34, 11399-11409] making NMR studies with this 32 kDa protein tractable. PF4-M2, moreover, binds heparin with a similar affinity to that of native PF4. NMR data presented here indicate that heparin (9000 Da cut-off) binding to PF4-M2, while not perturbing the overall structure of the protein, does perturb specific side-chain proton resonances which map to spatially related residues within a ring of positively charged side chains on the surface of tetrameric PF4-M2. Contrary to PF4-heparin binding models which centre around C-terminal alpha-helix lysines, this study indicates that a loop containing Arg-20, Arg-22, His-23 and Thr-25, as well as Lys-46 and Arg-49, are even more affected by heparin binding. Site-directed mutagenesis and heparin binding data support these NMR findings by indicating that arginines more than C-terminal lysines, are crucial to the heparin binding process.

Heparin: pharmacological potentials from atherosclerosis to asthma

1. Heparin belongs to a family of polysaccharide species, whose best known property is, undoubtedly, anticoagulant activity. However, heparin has many other pharmacological effects, particularly on the cardiovascular system. 2. The therapeutic use of chronically inhaled heparin has been suggested as prophylaxis in atherosclerosis. 3. Heparin, physiologically stored in mast cells of the respiratory system, has also been recently studied in the prevention of immunological and non-immunological asthmatic attacks. 4. Experimental findings and new hypotheses of heparin action in asthma and atherosclerosis are discussed.

Hirudin: initial results in acute myocardial infarction, unstable angina and angioplasty

The central role of thrombosis in the pathogenesis of acute myocardial infarction, unstable angina and complications after angioplasty has led to intense interest in developing more effective antithrombotic agents for these disorders. Hirudin, a direct thrombin inhibitor, has undergone extensive testing in experimental models and has recently been evaluated in patients in several pilot trials. Across these three indications, hirudin has been found to achieve a more consistent level of anticoagulation than heparin, as gauged by the activated parital thromboplastin time. Similarly, as an adjunct to thrombolytic therapy in acute myocardial infarction, in the treatment of unstable angina and in support of angioplasty, hirudin appeared to improve indexes of coronary reperfusion and patency. Initial results with clinical end points, including death or myocardial infarction, appeared to favor hirudin over heparin. In several large phase III trials, hirudin is being compared with heparin for all three indications. In the first phases of these trials, the rate of hemorrhagic events, including intracranial hemorrhage, was higher than expected in both the hirudin and heparin arms, which demonstrated that a safety ceiling had been reached. The reformulated Thrombolysis in Myocardial Infarction (TIMI) 9 and Second Global Use of Strategies to Open Occluded Coronary Arteries (GUSTO II) trials are using lower doses of hirudin and heparin, which should allow testing of whether the initial favorable results observed in pilot trials will translate into improved clinical outcome, with an acceptable safety profile, for patients with acute myocardial infarction or unstable angina or those undergoing angioplasty.

Effect of inhaled heparin on methacholine-induced bronchial hyperreactivity

Although heparin is used as an anticoagulant, its biologic function has remained unclear since the 1920s. Glycosaminoglycan heparin possesses multiple noncoagulant properties, including anti-inflammatory actions, and it is possible that heparin may inhibit airway hyperreactivity. Thus, the purpose of the present investigation was to study the effect of inhaled heparin on methacholine-induced bronchoconstriction. Thirteen subjects (7 women, 6 men) with mild asthma were included in the study. Bronchial provocation tests were performed in a single-blind, crossover, randomized order and repeated 45 min after placebo or aerosolized heparin inhalation (1,000 U/kg). The heparin inhibited bronchoconstriction induced by methacholine. In the methacholine challenge test, heparin treatment resulted in an increase in the mean PD20 over placebo: 5.26 +/- 4.80 mg/mL vs 10.57 +/- 5.72 mg/mL (p < 0.0002). These data suggest that inhaled heparin may have an inhibitory role on methacholine bronchial challenge, possibly via a direct effect on smooth muscle.

The crystal structure of recombinant human neutrophil-activating peptide-2 (M6L) at 1.9-A resolution

Neutrophil-activating peptide-2 (NAP-2) is a 70-residue carboxyl-terminal fragment of platelet basic protein, which is found in the alpha-granules of human platelets. NAP-2, which belongs to the CXC family of chemokines that includes interleukin-8 and platelet factor 4, binds to the interleukin-8 type II receptor and induces a rise in cytosolic calcium, chemotaxis of neutrophils, and exocytosis. Crystals of recombinant NAP-2 in which the single methionine at position 6 was replaced by leucine to facilitate expression belong to space group P1 (unit cell parameters a = 40.8, b = 43.8, and c = 44.7 A and alpha = 98.4 degrees, beta = 120.3 degrees, and gamma = 92.8 degrees), with 4 molecules of NAP-2 (Mr = 7600) in the asymmetric unit. The molecular replacement solution calculated with bovine platelet factor 4 as the starting model was refined using rigid body refinement, manual fitting in solvent-leveled electron density maps, simulated annealing, and restrained least squares to an R-factor of 0.188 for 2 sigma data between 7.0- and 1.9-A resolution. The final refined crystal structure includes 265 solvent molecules. The overall tertiary structure, which is similar to that of platelet factor 4 and interleukin-8, includes an extended amino-terminal loop, three strands of antiparallel beta-sheet arranged in a Greek key fold, and one alpha-helix at the carboxyl terminus. The Glu-Leu-Arg sequence that is critical for receptor binding is fully defined by electron density and exhibits multiple conformations.

Use of a direct thrombin inhibitor (argatroban) during pulse-spray thrombolysis in experimental thrombosis

PURPOSE

To evaluate the effectiveness of intravenous and intrathrombic injection of the thrombin inhibitor argatroban during pulse-spray pharmacomechanical thrombolysis (PSPMT) in experimental venous thrombosis.

MATERIALS AND METHODS

Clots were produced in the inferior vena cava in 52 rabbits by placement of steel coils and balloon injury to the vessel wall. Two days later, clots were treated with PSPMT. Several treatment methods were used: intrathrombic saline, intrathrombic tissue plasminogen activator (t-PA), intrathrombic t-PA with intrathrombic and intravenous heparin, intrathrombic t-PA with intravenous argatroban, and intrathrombic t-PA with intrathrombic and intravenous argatroban at two different doses. After treatment, the rabbits were killed and residual clot was weighed. Pretreatment clot weight was estimated and clot lysis was assessed.

RESULTS

PSPMT with t-PA and adjunctive intrathrombic heparin resulted in greater lysis than PSPMT with only t-PA (percentage of residual clot, 59% +/- 14 vs 81% +/- 28; P = .02). Addition of intravenous argatroban did not increase lysis, but adjunctive intrathrombic argatroban significantly increased lysis at low doses (37% +/- 16; P = .02) and high doses (34% +/- 6; P = .006) compared with t-PA and intrathrombic heparin.

CONCLUSION

In a rabbit model of venous thrombosis, the use of intrathrombic argatroban during PSPMT with t-PA significantly improved clot lysis.

Inhibition of factor Xa-induced platelet aggregation by a selective thrombin inhibitor, argatroban

In the present study, a direct selective thrombin inhibitor, argatroban, and an indirect non-selective inhibitor, heparin, were examined for the inhibitory effect on factor Xa-induced platelet aggregation. Platelet aggregation was induced by thrombin or factor Xa+prothrombin in the presence of Ca++ using rabbit gel-filtered platelets. IC50 of argatroban on factor Xa-induced aggregation was 5-7 times higher than that on thrombin-induced aggregation, while IC50 of heparin in the presence of antithrombin III on factor Xa-induced aggregation was 90-200 times higher than that on thrombin-induced aggregation. This finding suggests that argatroban inhibits thrombin generating on the platelet surface more efficiently than heparin, and this may be one of the reasons for the higher efficacy of argatroban in arterial thrombosis as compared with heparin.

Effect of heparin and a low-molecular weight heparinoid on PAF-induced airway responses in neonatally immunized rabbits

1. We have investigated the effect of an unfractionated heparin preparation, a low-molecular weight heparinoid (Org 10172) and the polyanionic molecule polyglutamic acid against PAF-induced airway hyperresponsiveness and pulmonary cell infiltration in neonatally immunized rabbits in vivo. 2. Exposure of neonatally immunized rabbits to aerosolized platelet activating factor (PAF) (80 micrograms ml-1 for 60 min) elicited an increase in airway responsiveness to inhaled histamine 24 h and 72 h following challenge which was associated with an infiltration of inflammatory cells into the airways, as assessed by bronchoalveolar lavage (BAL). 3. A significant increase in the total numbers of cells recovered from BAL fluid was associated with significantly increased cell numbers of neutrophils, eosinophils and mononuclear cells 24 h following PAF exposure. The numbers of eosinophils and neutrophils in the airways remained elevated 72 h after challenge. 4. The intravenous administration of an unfractionated preparation of heparin (100 units kg-1) or Org 10172 (100 micrograms kg-1) 30 min prior to PAF exposure significantly inhibited the airway hyperresponsiveness induced by PAF, 24 h and 72 h following challenge. PAF-induced hyperresponsiveness was not significantly affected by prior intravenous administration of polyglutamic acid (100 micrograms kg-1). 5. The intravenous administration of unfractionated heparin (100 units kg-1), Org 10172 (100 micrograms kg-1) or polyglutamic acid (100 micrograms kg-1) 30 min prior to PAF exposure significantly inhibited the expected increase in total cell infiltration. 6. This study shows that unfractionated heparin and a low-molecular weight heparinoid, Org 10172, are capable of inhibiting both the airway hyperresponsiveness and pulmonary cell infiltration induced by PAF in the rabbit.

Comparative studies of the interaction of human and bovine platelet factor 4 with heparin using histidine NMR resonances as spectroscopic probes

The pKa values of His-38 and His-50 of the heparin-binding protein, bovine platelet factor 4, are 5.6 and 6.5, respectively, as determined by 1H NMR spectroscopy. The 1H NMR resonance of His-38 of bovine platelet factor 4 which exhibits the lower pKa value is perturbed upon heparin binding to a greater degree than the resonance of His-50. Human platelet factor 4 contains the homologous residues His-23 and His-35. The pKa values of the two histidine residues of human platelet factor 4 are 5.3 and 6.4. The 1H NMR resonance of the histidine of human platelet factor 4 exhibiting the lower pKa value also is perturbed upon heparin binding to a greater degree than the histidine resonance exhibiting the higher pKa, thereby suggesting comparable heparin-protein interactions in bovine and human platelet factor 4.

An explanation of the asthma paradox

The morbidity and mortality associated with asthma are rising, despite increased usage of anti-asthma medications. This report attempts to provide a plausible hypothesis for the "asthma paradox." The hypothesis involves the role of mast cell degranulation as an endogenous anti-inflammatory mechanism to prevent antigens from entering the lower airways and to limit the extent of the subsequent repair process. By treating symptoms of asthma with drugs such as beta 2 agonists that inhibit mast cell degranulation, increased inflammation is allowed to occur, which may lead to the chronic appearance of excess repair tissue and the acceleration of the disease process.