The chemokine receptor CCR8 mediates human endothelial cell chemotaxis induced by I-309 and Kaposi sarcoma herpesvirus-encoded vMIP-I and by lipoprotein(a)-stimulated endothelial cell conditioned medium.

The CC chemokine receptor 8 (CCR8) is expressed on monocytes and type 2 T lymphocytes. CCR8 is the sole receptor for the human CC chemokine I-309, as well as for viral monocyte inflammatory protein-I (vMIP-I), a human chemokine homologue induced in human cells by the Kaposi sarcoma-related human herpesvirus-8. Recently it was found that I-309 messenger RNA and protein are expressed by human umbilical vein endothelial cells (HUVECs) and that the secretion of endothelial I-309 is stimulated by apolipoprotein(a). I-309, vMIP-I, and the conditioned medium from apolipoprotein(a)-stimulated HUVECs induce endothelial chemotaxis. A polyclonal anti-CCR8 antibody and a newly developed murine monoclonal antibody against CCR8 inhibited this activity. The G-protein inhibitor pertussis toxin also inhibited endothelial chemotaxis, providing further evidence for a chemokine receptor-mediated effect. Endothelial cells contain CCR8 mRNA as shown by RNA blot analysis as well by direct sequence analysis. Immunohistochemical studies identified CCR8 and I-309 on the endothelium of human atherosclerotic plaques and in endothelial-derived spindle cells of Kaposi sarcoma. These results indicate that CCR8 is an endothelial receptor that may modulate endothelial function.

CC chemokine I-309 is the principal monocyte chemoattractant induced by apolipoprotein(a) in human vascular endothelial cells.

BACKGROUND: Lipoprotein(a) [Lp(a)] is a risk factor for atherosclerosis; however, the mechanisms are unclear. We previously reported that Lp(a) stimulated human vascular endothelial cells to produce monocyte chemotactic activity. The apolipoprotein(a) [apo(a)] portion of Lp(a) was the active moiety. METHODS AND RESULTS: We now describe the identification of the chemotactic activity as being due to the CC chemokine I-309. The carboxy-terminal domain of apo(a) containing 6 type-4 kringles (types 5 to 10), kringle V, and the protease domain was demonstrated to contain the I-309-inducing portion. Polyclonal and monoclonal anti-I-309 antibodies as well as an antibody against a portion of the extracellular domain of CCR8, the I-309 receptor, inhibited the increase in monocyte chemotactic activity induced by apo(a). I-309 antisense oligonucleotides also inhibited the induction of endothelial monocyte chemotactic activity by apo(a). I-309 mRNA was identified in human umbilical vein endothelial cells. Apo(a) induced an increase in I-309 protein in the endothelial cytoplasm and in the conditioned medium. Immunohistochemical studies have identified I-309 in endothelium, macrophages, and extracellular areas of human atherosclerotic plaques and have found that I-309 colocalized with apo(a). CONCLUSIONS: These data establish that I-309 is responsible for the monocyte chemotactic activity induced in human umbilical vein endothelial cells by Lp(a). The identification of the endothelial cell as a source for I-309 suggests that this chemokine may participate in vessel wall biology. Our data also suggest that I-309 may play a role in mediating the effects of Lp(a) in atherosclerosis.

Dose response of intravenous heparin on markers of thrombosis during primary total hip replacement.

BACKGROUND: Thrombogenesis in total hip replacement (THR) begins during surgery on the femur. This study assesses the effect of two doses of unfractionated intravenous heparin administered before femoral preparation during THR on circulating markers of thrombosis. METHODS: Seventy-five patients undergoing hybrid primary THR were randomly assigned to receive blinded intravenous injection of either saline or 10 or 20 U/kg of unfractionated heparin after insertion of the acetabular component. Central venous blood samples were assayed for prothrombin F1+2 (F1+2), thrombin-antithrombin complexes (TAT), fibrinopeptide A (FPA), and D-dimer. RESULTS: No changes in the markers of thrombosis were noted after insertion of the acetabular component. During surgery on the femur, significant increases in all markers were noted in the saline group (P < 0.0001). Heparin did not affect D-dimer or TAT. Twenty units per kilogram of heparin significantly reduced the increase of F1+2 after relocation of the hip joint (P < 0.001). Administration of both 10 and 20 U/kg significantly reduced the increase in FPA during implantation of the femoral component (P < 0.0001). A fourfold increase in FPA was noted in 6 of 25 patients receiving 10 U/kg of heparin but in none receiving 20 U/kg (P = 0.03). Intraoperative heparin did not affect intra- or postoperative blood loss, postoperative hematocrit, or surgeon's subjective assessments of bleeding. No bleeding complications were noted. CONCLUSIONS: This study demonstrates that 20 U/kg of heparin administered before surgery on the femur suppresses fibrin formation during primary THR. This finding provides the pathophysiologic basis for the clinical use of intraoperative heparin during THR.

Lipoprotein(a) and inflammation in human coronary atheroma: association with the severity of clinical presentation.

OBJECTIVES: The purpose of this study was the investigation of the in vivo role of lipoprotein(a) [Lp(a)] and inflammatory infiltrates in the human coronary atherosclerotic plaque and their correlation with the clinical syndrome of presentation. BACKGROUND: Lipoprotein(a) is an atherogenic and thrombogenic lipoprotein, and has been implicated in the pathogenesis of acute coronary syndromes. Lipoprotein(a) induces monocyte chemoattraction and smooth muscle cell activation in vitro. Macrophage infiltration is considered one of the mechanisms of plaque rupture. METHODS: This study of atherectomy specimens investigated the in vivo role of Lp(a) at different stages of the atherogenic process, and its relationship with macrophage infiltration. We examined coronary atheroma removed from 72 patients with stable or unstable angina. Specimens were stained with antibodies specific for Lp(a), macrophages (KP-1), and smooth muscle cells (alpha-actin). Morphometric analysis was used to quantify the plaque areas occupied by each of the three antigens, and their colocalization. RESULTS: All specimens had localized Lp(a) staining; the mean fractional area was 58.2%. Ninety percent of the macrophage areas colocalized with Lp(a) positive areas, whereas 31.3% of the smooth muscle cell areas colocalized with Lp(a) positive areas. Patients with unstable angina (n = 46) had specimens with larger mean plaque Lp(a) areas than specimens from stable angina patients (n = 26): 64.4% versus 47.7% (p = 0.004). Unstable angina patients with rest pain (n = 28) had greater mean plaque Lp(a) area than unstable angina patients with crescendo exertional pain (n = 18): 71.1% versus 52.4% (p < 0.001). Mean KP-1 area was 31.2% in unstable rest angina versus 18.3% in stable angina (p = 0.05); alpha-actin area was greater in stable (48.5%) and crescendo exertional angina (48.8%) than in rest angina (30.4%). The strongest correlation between plaque KP-1 and Lp(a) area was in unstable rest angina (r = 0.88, p < 0.001), and between alpha-actin and Lp(a) areas in the crescendo exertional angina (r = 0.62, p < 0.01). CONCLUSIONS: Lipoprotein(a) is ubiquitous in human coronary atheroma. It is detected in larger amounts in tissue from culprit lesions in patients with unstable compared to stable syndromes, and has significant colocalization with plaque macrophages. A correlation of plaque alpha-actin and Lp(a) area suggests a role of Lp(a) in plaque growth.

Antiphospholipid antibodies accelerate plasma coagulation by inhibiting annexin-V binding to phospholipids: a "lupus procoagulant" phenomenon.

The antiphospholipid syndrome is a thrombophilic condition marked by antibodies that recognize anionic phospholipid-protein cofactor complexes. We recently reported that exposure to IgG fractions from antiphospholipid patients reduces the level of annexin-V, a phospholipid-binding anticoagulant protein, on cultured trophoblasts and endothelial cells and accelerates coagulation of plasma exposed to these cells. Therefore, we asked whether antiphospholipid antibodies might directly reduce annexin-V binding to noncellular phospholipid substrates. Using ellipsometry, we found that antiphospholipid IgGs reduce the quantity of annexin-V bound to phospholipid bilayers; this reduction is dependent on the presence of beta2-glycoprotein I. Also, exposure to plasmas containing antiphospholipid antibodies reduces annexin-V binding to phosphatidyl serine-coated microtiter plates, frozen thawed washed platelets, activated partial thromboplastin time (aPTT) reagent and prothrombin time reagent and reduces the anticoagulant effect of the protein. These studies show that antiphospholipid antibodies interfere with the binding of annexin-V to anionic phospholipid and with its anticoagulant activity. This acceleration of coagulation, due to reduced binding of annexin V, stands in marked contrast to the "lupus anticoagulant effect" previously described in these patients. These results are the first direct demonstration of the displacement of annexin-V and the consequent acceleration of coagulation on noncellular phospholipid surfaces by antiphospholipid antibodies.

Demonstration of covalent binding of lipoprotein(a) [Lp(a)] to fibrin and endothelial cells.

It has been well documented that Lp(a) binds noncovalently to fibrin or human umbilical vein endothelial cells. This binding is to lysines and is inhibited by lysine analogues such as epsilon-aminocaproic acid (EACA). In the present study, Lp(a) (0.006-0.6 microM) binding to immobilized fibrin and endothelial cells was evaluated by ELISA with an anti-Lp(a) antibody. A significant portion (approximately 65%) of the Lp(a) was found to resist dissociation by EACA (0.2 M). The EACA resistant binding of Lp(a) was time and concentration dependent. The addition of EDTA to the incubation mixture had no effect, thereby excluding cross-linking by transglutaminase as a mechanism. This portion of Lp(a) was also resistant to dissociation by acid (0.1 N HCl), 0.1% SDS, 1 M benzamidine, Tris-HCl (1 M, pH 12), or DTT (5 mM), but it was washed off by 0.1 N NaOH (which did not remove the immobilized fibrin). This suggested that the Lp(a) was covalently linked by an ester bond. Covalent binding was inhibited when Lp(a) was mildly oxidized by BioRad Enzymobeads, which may explain why it escaped recognition in experiments with radiolabeled Lp(a). Covalent binding was attenuated when Lp(a) was pretreated with DFP suggesting that the serine residue in the pseudo active site of Lp(a) was involved. Lp(a) also bound covalently to immobilized BSA, indicating some nonspecificity. However, binding to BSA was almost 3-fold less than to fibrin, suggesting that lysine binding may facilitate covalent binding. A similar proportion of EACA resistant binding of Lp(a) was found with endothelial cells. In conclusion, the findings demonstrate a novel, covalent binding by Lp(a) which is kringle independent and is postulated to involve the pseudo protease domain of Lp(a). This property may contribute to the deposition of Lp(a) on endothelial surfaces and its colocalization with fibrin in atheromas.

The atherogenic lipoprotein Lp(a) is internalized and degraded in a process mediated by the VLDL receptor.

Lp(a) is a major inherited risk factor associated with premature heart disease and stroke. The mechanism of Lp(a) atherogenicity has not been elucidated, but likely involves both its ability to influence plasminogen activation as well as its atherogenic potential as a lipoprotein particle after receptor-mediated uptake. We demonstrate that fibroblasts expressing the human VLDL receptor can mediate endocytosis of Lp(a), leading to its degradation within lysosomes. In contrast, fibroblasts deficient in this receptor are not effective in catabolizing Lp(a). Lp(a) degradation was prevented by antibodies against the VLDL receptor, and by RAP, an antagonist of ligand binding to the VLDL receptor. Catabolism of Lp(a) was inhibited by apolipoprotein(a), but not by LDL or by monoclonal antibodies against apoB100 that block LDL binding to the LDL receptor, indicating that apolipoprotein(a) mediates Lp(a) binding to this receptor. Removal of Lp(a) antigen from the mouse circulation was delayed in mice deficient in the VLDL receptor when compared with control mice, indicating that the VLDL receptor may play an important role in Lp(a) catabolism in vivo. We also demonstrate the expression of the VLDL receptor in macrophages present in human atherosclerotic lesions. The ability of the VLDL receptor to mediate endocytosis of Lp(a) could lead to cellular accumulation of lipid within macrophages, and may represent a molecular basis for the atherogenic effects of Lp(a).

Apolipoprotein(a) induces monocyte chemotactic activity in human vascular endothelial cells.

BACKGROUND: Elevated levels of lipoprotein(a) [Lp(a)] are associated with premature atherosclerosis; however, the mechanisms are not known. Recruitment of monocytes to the blood vessel wall is an early event in atherogenesis. METHODS AND RESULTS: This study has found that unoxidized Lp(a) induced human umbilical vein endothelial cells (HUVECs) to secrete monocyte chemotactic activity (MCA), whereas LDL under the same conditions did not. In the absence of HUVECs, Lp(a) had no direct MCA. Endotoxin was shown not to be responsible for the induction of MCA. Actinomycin D and cycloheximide inhibited the HUVEC response to Lp(a), indicating that protein and RNA synthesis were required. The apolipoprotein(a) [apo(a)] portion of Lp(a) was identified as the structural component of Lp(a) responsible for inducing MCA. Lp(a) and apo(a) also stimulated human coronary artery endothelial cells to produce MCA. Granulocyte-monocyte colony-stimulating factor (GM-CSF) antigen was not detected in the Lp(a)-conditioned medium, nor was monocyte chemoattractant protein-1 mRNA induced in HUVECs by Lp(a). CONCLUSIONS: These findings suggest that Lp(a) may be involved in the recruitment of monocytes to the vessel wall and provide a novel mechanism for the participation of Lp(a) in the atherogenic process.

Pregnancy loss in the antiphospholipid-antibody syndrome--a possible thrombogenic mechanism.

BACKGROUND: The mechanisms of vascular thrombosis and pregnancy loss in the antiphospholipid-antibody syndrome are unknown. Levels of annexin V, a phospholipid-binding protein with potent anticoagulant activity, are markedly reduced on placental villi from women with this syndrome. Hypercoagulability in such women may therefore be due to the reduction of surface-bound annexin V by antiphospholipid antibodies. To test this idea, we studied how antiphospholipid antibodies affect levels of annexin V on cultured trophoblasts and human umbilical-vein endothelial cells and how they affect the procoagulant activity of these cells. METHODS: We isolated IgG fractions from three patients with the antiphospholipid-antibody syndrome and from normal controls. These antibodies were incubated with cultured BeWo cells (a placental-trophoblast cell line), primary cultured trophoblasts, and human umbilical-vein endothelial cells. Annexin V on the cell surfaces was measured by an enzyme-linked immunosorbent assay. The coagulation times of plasma overlaid on the cells were also determined. RESULTS: Trophoblasts and endothelial cells exposed to antiphospholipid-antibody IgG as compared with control IgG had reduced levels of annexin V (trophoblasts, 0.37 +/- 0.02 vs. 0.85 +/- 0.12 ng per well, P=0.02; endothelial cells, 1.6 +/- 0.04 vs. 2.1 +/- 0.05 ng per well, P=0.001). Also, trophoblasts and endothelial cells exposed to antiphospholipid-antibody IgG had faster mean (+/- SE) plasma coagulation times than cells exposed to control IgG (trophoblasts, 8.7 +/- 2.0 vs. 21.3 +/- 2.9 minutes, P=0.02; endothelial cells, 9.8 +/- 0.8 vs. 14.2 +/- 1.2 minutes, P=0.04). CONCLUSIONS: Antiphospholipid antibodies reduce the levels of annexin V and accelerate the coagulation of plasma on cultured trophoblasts and endothelial cells. The reduction of annexin V levels on vascular cells may be an important mechanism of thrombosis and pregnancy loss in the antiphospholipid-antibody syndrome.

Comparison of extradural and general anaesthesia on the fibrinolytic response to total knee arthroplasty.

Extradural anaesthesia is associated with lower incidences of deep vein thrombosis after total knee arthroplasty. It is not known if the type of anaesthesia influences thrombogenesis or fibrinolysis during knee surgery performed under tourniquet. We studied 31 patients allocated randomly to receive either extradural or general anaesthesia for primary unilateral total knee arthroplasty performed under tourniquet. Radial artery blood samples were obtained before surgery, during surgery with the tourniquet inflated and on deflation of the tourniquet. Plasma samples were assayed for markers of thrombin generation and fibrinolysis. Two of the circulating indices of thrombin generation, fibrinopeptide A and thrombin-antithrombin complexes, increased to a similar degree in the perioperative period in both groups. Fibrinolytic activity was similar in both groups, as measured by tissue plasminogen activator (t-PA) antigen, t-PA activity, t-PA-plasminogen activator inhibitor complexes, alpha 2-plasmin inhibitor-plasmin complexes and D-dimer. Extradural and general anaesthesia did not result in significant differences in either thrombin generation or fibrinolytic activity during total knee arthroplasty performed under tourniquet.

Oxidation of apolipoprotein(a) inhibits kringle-associated lysine binding: the loss of intrinsic protein fluorescence suggests a role for tryptophan residues in the lysine binding site.

Lipoprotein(a) [Lp(a)] is a low-density lipoprotein complex consisting of apolipoprotein(a) [apo(a)] disulfide-linked to apolipoprotein B-100. Lp(a) has been implicated in atherogenesis and thrombosis through the lysine binding site (LBS) affinity of its kringle domains. We have examined the oxidative effect of 2,2'-azobis-(amidinopropane) HCl (AAPH), a mild hydrophilic free radical initiator, upon the ability of Lp(a) and recombinant apo(a), r-apo(a), to bind through their LBS domains. AAPH treatment caused a time-dependent decrease in the number of functional Lp(a) or r-apo(a) molecules capable of binding to fibrin or lysine-Sepharose and in the intrinsic protein fluorescence of both Lp(a) and r-apo(a). The presence of a lysine analogue during the reaction prevented the loss of lysine binding and provided a partial protection from the loss of tryptophan fluorescence. The partial protection of fluorescence by lysine analogues was observed in other kringle-containing proteins, but not in proteins lacking kringles. No significant aggregation, fragmentation, or change in conformation of Lp(a) or r-apo(a) was observed as assessed by native or SDS-PAGE, light scattering, retention of antigenicity, and protein fluorescence emission spectra. Our results suggest that AAPH destroys amino acids in the kringles of apo(a) that are essential for lysine binding, including one or more tryptophan residues. The present study, therefore, raises the possibility that the biological roles of Lp(a) may be mediated by its state of oxidation, especially in light of our previous study showing that the reductive properties of sulfhydryl-containing compounds increase the LBS affinity of Lp(a) for fibrin.

Apolipoprotein(a) is a human vascular endothelial cell agonist: studies on the induction in endothelial cells of monocyte chemotactic factor activity.

Elevated levels of lipoprotein(a), Lp(a), are associated with premature atherosclerosis; however, the mechanisms of its atherogenicity are not known. Recruitment of monocytes to the blood vessel wall is an early event in atherogenesis. Since Lp(a) is associated with macrophages in the plaque, we have examined the effect of Lp(a) on inducing monocyte chemotactic activity (MCA) in vascular endothelial cells. We report that Lp(a) and apo(a) induced human umbilical vein (HUVEC) and coronary artery endothelial cells to secrete monocyte chemotactic activity as early as 30 min of incubation. In the absence of cells, Lp(a) had no direct monocyte chemotactic activity. Actinomycin D and cycloheximide inhibited the HUVEC response, indicating that protein and RNA synthesis were required. Endotoxin was shown not to be responsible for the induction of monocyte chemotactic activity. Granulocyte monocyte-colony stimulating factor antigen was not detected in the Lp(a)-conditioned medium, nor was monocyte chemoattractant protein-1 mRNA induced by Lp(a). These results suggest that Lp(a) may be involved in the recruitment of monocytes to the vessel wall, thus providing a novel mechanism for the participation of Lp(a) in the atherogenic process.

Homocysteine and hemostasis: pathogenic mechanisms predisposing to thrombosis.

Growing evidence suggests that moderately elevated levels of homocysteine are associated not only with arterial thrombosis and atherosclerosis but also with venous thrombosis as well. We have reviewed recent studies that indicate that homocysteine inhibits several different anticoagulant mechanisms that are mediated by the vascular endothelium. The protein C enzyme system appears to be one of the most important anticoagulant pathways in the blood. Homocysteine inhibits the expression and activity of endothelial cell surface thrombomodulin, the thrombin cofactor responsible for protein C activation. Homocysteine inhibits the antithrombin III binding activity of endothelial heparan sulfate proteoglycan, thereby suppressing the anticoagulant effect of antithrombin III. Homocysteine also inhibits the ecto-ADPase activity of human umbilical vein endothelial cells (HUVECS). Because ADP is a potent platelet aggregatory agent, this action of homocysteine is prothrombotic. Homocysteine also interferes with the fibrinolytic properties of the endothelial surface because it inhibits the binding of tissue plasminogen activator. Homocysteine stimulates HUVEC tissue factor activity. We have found that lipoprotein(a) [Lp(a)] also stimulates HUVEC tissue factor activity. The combination of Lp(a) plus homocysteine induced more tissue factor activity than either agent alone. These disruptions in several different vessel wall-related anticoagulant functions provide plausable mechanisms for the occurrence of thrombosis in hyperhomocysteinemia.

The John Charnley Award. Thrombogenesis during total hip arthroplasty.

The activation of the clotting cascade leading to deep venous thrombosis begins during total hip arthroplasty, but few studies have assessed changes in coagulation during surgery. A better understanding of thrombogenesis during total hip arthroplasty may provide a more rational basis for treatment. In 3 separate studies, the following observations were made. Circulating indices of thrombosis and fibrinolysis: prothrombin F1.2, thrombin-antithrombin complexes, fibrinopeptide A, and D-dimer, did not increase during osteotomy of the neck of the femur or during insertion of the acetabular component, but rose significantly during insertion of the femoral component. Thrombin-antithrombin complexes, fibrinopeptide A, and D-dimer were higher after insertion of a cemented component than insertion of a noncemented femoral component. A significant decline in central venous oxygen tension was observed after relocation of the hip joint and after insertions of cemented and noncemented femoral components, providing evidence of femoral venous occlusion during insertion of the femoral component. In patients receiving a cemented femoral component, mean pulmonary artery pressure increased after relocation of the hip joint, indicating intraoperative pulmonary embolism. No changes in mean pulmonary artery pressure were noted with noncemented total hip arthroplasty. Administration of 1000 units of unfractionated heparin before insertion of a cemented femoral component blunted the rise of fibrinopeptide A. The results of these studies suggest that (1) the greatest risk of activation of the clotting cascade during total hip arthroplasty occurs during insertion of the femoral component; (2) femoral venous occlusion and use of cemented components are factors in thrombogenesis during total hip arthroplasty; and (3) measures to prevent deep venous thrombosis during total hip arthroplasty (such as intraoperative anticoagulation) should begin during surgery rather than during the postoperative period and be applied during insertion of the femoral component.

Changes in circulatory indices of thrombosis and fibrinolysis during total knee arthroplasty performed under tourniquet.

Deep vein thrombosis may begin during surgery with the tourniquet inflated. Arterial levels of fibrinopeptide A, thrombin-antithrombin complexes, D-dimer, tissue plasminogen activator (t-PA) activity, and t-PA antigen were measured before surgery, during surgery with the tourniquet inflated, and following deflation of the tourniquet in 12 patients undergoing total knee arthroplasty. Minimal increases in fibrinopeptide A, thrombin-antithrombin complexes, and D-dimer were noted during surgery with the tourniquet inflated, but significant increases occurred immediately following deflation of the tourniquet. In 10 patients, intravenous heparin administration significantly suppressed the rise in fibrinopeptide A, but did not significantly alter the increases in either thrombin-antithrombin complexes, D-dimer, t-PA antigen, or t-PA activity. This study provides further evidence that deep vein thrombosis begins during surgery.

Location of the major epsilon-(gamma-glutamyl)lysyl cross-linking site in transglutaminase-modified human plasminogen.

Tissue and plasma transglutaminases cross-link human plasminogen into high molecular weight complexes (Bendixen, E., Borth, W., and Harpel, P. C. (1993) J. Biol. Chem. 268, 21962-21967). A major cross-linking site in plasminogen involved in the tissue transglutaminase-mediated polymerization process has been identified. The epsilon-(gamma-glutamyl)lysyl bridges of the polymer are formed between Lys-298 and Gln-322. Both the acyl donor Gln residue and the acyl acceptor Lys residue are located in the kringle 3 domain of plasminogen, i.e. cross-linking of plasminogen by tissue transglutaminase involves neither the catalytic domain nor the lysine-dependent binding sites of plasminogen. This study documents that kringle 3 contains a novel functional site with the potential to participate in transglutaminase-mediated cross-linking interactions with plasma, cell-surface, and extracellular proteins.

Lipoprotein(a), plasmin modulation, and atherogenesis.

Lipoprotein(a) [Lp(a)] is an atherogenic lipoprotein however the mechanisms by which Lp(a) promote the atherosclerotic process are not clear. The apolipoprotein(a) portion of Lp(a) shares partial homology with plasminogen, a finding that has stimulated numerous studies. Lp(a) binds to fibrin and the affinity between fibrin surfaces and Lp(a) appears to be related to the state of oxidation of the lipoprotein particle. Lp(a) also effects fibrin-dependent plasminogen activation. Recent findings suggest that dependent plasminogen activation. Recent findings suggest that depending upon the in vitro conditions, Lp(a) either promotes or inhibits plasmin formation. Lp(a) also inhibits cell-surface dependent plasmin generation that is associated with an inhibition of transforming growth factor-beta (TGF-beta) production in cell coculture systems. Lp(a) stimulates smooth muscle cell migration and proliferation as a secondary response to this decrease in TGF-beta concentration. Studies in transgenic mice containing the human apolipoprotein(a) gene, document that both plasmin and TGF-beta formation in the media of the aorta is markedly decreased in the presence of apo(a). Thus the atherogenicity of Lp(a) may be mediated, in part, through its modulation of plasmin and TGF-beta production in the blood vessel wall.

Autoantibodies to heparin from patients with antiphospholipid antibody syndrome inhibit formation of antithrombin III-thrombin complexes.

The antiphospholipid antibody syndrome (APS) is characteristically associated with thrombosis. Heparan sulfate (HS) is a physiologic endothelial cell surface modulator of normal anticoagulation, containing a specific oligosaccharide sequence that binds antithrombin III with high affinity and also is present in heparin, a related glycosaminoglycan. We hypothesized that a subset of antiphospholipid antibodies with high affinity for heparan sulfate/heparin epitopes may inhibit the function of HS, promoting a procoagulant state. Purified IgG from all seven patients with APS studied were reactive with heparin by enzyme-linked immunosorbent assay, whereas none of five controls had antiheparin reactivity. IgG antiheparin antibodies were purified from two APS patients by affinity chromatography on heparin-Sepharose. Specificity studies showed that low-affinity electrostatic interactions clearly did not account for the observed reactivity with heparin, and that APS IgG antiheparin antibodies were specifically reactive with a disaccharide present in the heparin pentasaccharide that binds antithrombin III. Furthermore, APS IgG antiheparin antibodies inhibited heparin-accelerated formation of antithrombin III-thrombin complexes. We conclude that antiheparan sulfate/heparin antibodies may be a cause of autoimmune vascular thrombosis in the antiphospholipid antibody syndrome.

Fibrin-bound lipoprotein(a) promotes plasminogen binding but inhibits fibrin degradation by plasmin.

Conflicting results have been obtained from studies of the effects of lipoprotein(a) [Lp(a)] on plasminogen binding to fibrin and fibrin-dependent activation by tissue plasminogen activation (t-PA). We performed binding studies of Glu-plasminogen (0-16 microM) to immobilized D-dimer +/- Lp(a) (0.20 microM). In the absence of Lp(a), Scatchard analysis revealed a binding constant of KD = 1.01 +/- 0.18 microM, with two plasminogen binding sites per D-dimer. In the presence of Lp(a), a lower affinity (KD 3.10 +/- 0.23 microM) was found, but five binding sites were present, suggesting that plasminogen bound to fibrin-bound Lp(a) rather than to D-dimer. Consistent with this explanation was the finding that when D-dimer-coated plates were first precoated with Lp(a) before plasminogen was added, similar lower affinity plasminogen binding was found. This binding to Lp(a) was fibrin-dependent since, in its absence, plasminogen failed to bind to Lp(a). Therefore, a conformational change in Lp(a) appeared to be required for plasminogen binding to occur. This finding of two types of binding sites of different affinities helps to explain why Lp(a) has been reported to inhibit plasminogen binding to fibrin in studies in which only low concentrations of plasminogen (< 0.4 microM) were used. At these concentrations, few of the low-affinity binding sites on fibrin-bound Lp(a) will be occupied by plasminogen, an effect that was found to be exaggerated by the omission of NaCl.(ABSTRACT TRUNCATED AT 250 WORDS)