Reevaluation of total, free, and bound protein S and C4b-binding protein levels in plasma anticoagulated with citrate or hirudin.

The levels of total, free, and bound protein S and C4BP were determined using enzyme-linked immunosorbent assays (ELISAs) in plasma samples (8 males and 8 females) that were individually subjected to immunoadsorption studies in which "free protein S" was defined as that not adsorbed by anti-C4BP antibody-Sepharose column and "free C4BP" as that not adsorbed by anti-protein S antibody-Sepharose. Bound species were calculated as the difference between total and free species. Free protein S (131 nmol/L) averaged 38% of total protein S (346 nmol/L) and free C4BP (37 nmol/L) averaged 14% of total C4BP (264 nmol/L) in plasma. There was an excellent correlation between bound protein S and bound C4BP with 1:1 molar stoichiometry and a good correlation between free protein S antigen and protein S anticoagulant activity. It appears that free protein S is a necessary consequence of the molar excess of protein S over C4BP. C4BP beta chain antigen levels, measured using a new ELISA, averaged 218 nmol/L, a value indistinguishable from the molar concentrations of bound protein S (215 nmol/L) and bound C4BP (227 nmol/L). The free C4BP beta chain antigen was only 4 nmol/L compared with 131 nmol/L free protein S. These results suggest that free C4BP in plasma predominantly lacks the beta chain, that almost all C4BP capable of binding protein S is associated with protein S, and that the plasma levels of oligomeric forms of C4BP containing a beta chain (alpha 7 beta and alpha 6 beta) that bind protein S directly and stoichiometrically regulate free protein S levels.     

Evaluation of the relationship between protein S and C4b-binding protein isoforms in hereditary protein S deficiency demonstrating type I and type III deficiencies to be phenotypic variants of the same genetic disease

Type III protein S deficiency is characterized by a low plasma level of free protein S, whereas the total concentration of protein S is normal. In contrast, both free and total protein S levels are low in type I deficiency. To elucidate the molecular mechanism behind the selective deficiency of free protein S in type III deficiency, the relationship between the plasma concentrations of beta-chain containing isoforms of C4b-binding protein (C4BP beta+) and different forms of protein S (free, bound, and total) was evaluated in 327 members of 18 protein S- deficient families. In normal relatives (n = 190), protein S correlated well with C4BP beta+, with free protein S (96 +/- 23 nmol/L) being equal to the molar excess of protein S (355 +/- 65 nmol/L) over C4BP beta+ (275 +/- 47 nmol/L). In protein S-deficient family members (n = 117), the equimolar relationship between protein S (215 +/- 50 nmol/L) and C4BP beta+ (228 +/- 51 nmol/L), together with the high affinity of the interaction, resulted in low levels of free protein S (16 +/- 10 nmol/L). Free protein S levels were distinctly low in protein S- deficient members, whereas in 47 of the protein S-deficient individuals, the concentration of total protein S was within the normal range, which fulfils the criteria for type III deficiency. The remaining 70 had low levels of both total and free protein S and, accordingly, would be type I deficient. Coexistence of type I and type III deficiency was found in 14 families, suggesting the two types of protein S deficiency to be phenotypic variants of the same genetic disease. Interestingly, not only protein S but also C4BP beta+ levels were decreased in orally anticoagulated controls and even more so in anticoagulated protein S-deficient members, suggesting that the concentration of C4BP beta+ is influenced by that of protein S. In conclusion, our results indicate that type I and type III deficiencies are phenotypic variants of the same genetic disease and that the low plasma concentrations of free protein S in both types are the result of an equimolar relationship between protein S and C4BP beta+.     

Plasma concentrations of C4b-binding protein and vitamin K-dependent protein S in term and preterm infants: low levels of protein S-C4b-binding protein complexes

We have determined the plasma concentrations of protein S and C4BP in 25 term and 26 preterm infants by radioimmunoassay. Both the total concentration and the concentration of free protein S were quantified. The concentration of C4BP was very low in preterm infants (mean 6% of the adult level). In term infants, the level had increased to a mean of 18%. Total protein S was decreased both in preterm and term infants, 4.0 mg/l and 6.8 mg/l respectively, as compared to the mean adult concentration, 20.6 mg/l. In preterm infant plasma, free protein S was the predominant (85%) form, probably due to the very low C4BP level. In plasma from term infants, free protein S represented 68% of the total protein S, the corresponding value in adult controls being 37%. The plasma concentration of free protein S in preterm and term infants was 3.3 mg/l and 4.6 mg/l, respectively (mean adult value 7.6 mg/l). These results demonstrate that, while the total protein S concentration in preterm and term infants was very low in comparison to the adult level, the difference in the concentration of the anticoagulant, active, free form of protein S between infants and adults was less pronounced.     

Low levels of activated protein C in patients with systemic lupus erythematosus do not relate to lupus anticoagulants but to low levels of factor II

The presence of lupus anticoagulants (LAC) in plasma is a major risk factor for thrombosis. An attractive hypothesis to explain a LAC-mediated thrombotic tendency is that LAC interfere with activation of protein C, a natural antithrombotic in plasma. We investigated the relationship between LAC and protein C activation in vivo. We selected 20 patients with systemic lupus erythematosus (SLE) with LAC (and not using oral anticoagulants), 36 patients with SLE without LAC and 25 healthy volunteers. In these, we measured circulating levels of activated protein C (APC), prothrombin (FII), free protein S, C4BP, protein C, and antibodies to protein C, protein S, FII and beta2-glycoprotein I (beta2GPI). In SLE patients (n = 56), mean levels of APC, FII and free protein S were significantly (P < 0.001) lower than those in healthy volunteers (respectively 13%, 17% and 14%). Mean protein C levels and C4BP levels were similar for SLE patients and healthy volunteers. In contrast to the above hypothesis, the decreased levels of APC could not be attributed to the presence of LAC. Levels of APC were correlated with both FII levels and protein C levels. Decreased levels of APC, FII, protein C and free protein S were related to the presence of anti-FII antibodies. None of the patients had antibodies against protein C or protein S. In conclusion, although the mean levels of APC, FII and free protein S were significantly decreased in SLE patients, no correlation with LAC was found. However, anti-FII antibodies were related to decreased levels of APC, FII, protein C, free protein S and C4BP. As FII levels, and not protein C levels, were decreased in SLE patients and correlated with APC levels, we conclude that the decreased FII levels are responsible for the low levels of APC.     

A new case of ''type II'' inherited protein S deficiency

Protein S inherited deficiency is associated with high risk of recurrent venous thrombotic disease (Broekmans et al, 1985a, b). Protein S exists as two forms in plasma, either free and functionally active or complexed with C4b-binding protein (C4b BP) and inactive (Dahibäck & Stenflo, 1981). We report here the case of a 26-year-old woman and her brother, 28 years old, both suffering from recurrent venous thrombosis since the age of 20, diagnosed as severe protein S deficiency according to the following data: free protein S: 2.5–3% by ELISA, undetectable by electroimmunodiffusion (BID); total protein S: 13–16% by ELISA, 21–18% by EID, C4b BP: normal levels. Crossed immunoelectrophoresis using anti-protein S antibodies revealed only traces of protein S associated with C4b BP and no free protein S. All these assays were performed in the absence of any anticoagulant therapy. Among the investigated relatives, less severe protein S deficiency was observed in three children of the propositus: total protein S levels ranging from 41% to 50% (EID), 40–53% (ELISA); free protein S levels ranging from 16% to 18% (EID), 10–12% (ELISA); normal C4b BP levels. Crossed immunoelectrophoresis revealed traces of free protein S but a significant amount of protein S associated with C4b BP. From these results, we consider, according to Comp's classification (Comp et al, 1986a), that the propositus and her brother are the second case of protein S deficiency type II to be reported in the literature while her children belong to the type I category.     

The Ser 460 to Pro substitution of the protein S alpha (PROS1) gene is a frequent mutation associated with free protein S (type IIa) deficiency

A Ser 460 to Pro mutation of protein S (PS), involving a T to C transition in exon XIII of the protein S alpha (PROS1) gene and known as the Heerlen polymorphism, was found in 16 of 85 symptomatic patients with PS deficiency (18.8%) and only 1 of 113 healthy subjects (0.8%). Another frequent polymorphism was described in exon XV of the PROS1 gene, in the codon for Pro 626 (CCA/CCG). We found that Heerlen polymorphism was associated with allele CCA and not with allele CCG, suggesting a probable transmission by a common ancestor. Most subjects bearing the Ser 460 to Pro mutation were deficient in free PS, but had normal total PS levels. Normal levels of the C4b-binding protein (C4b- BP) isoform containing a beta chain (C4b-BP beta +) ruled out increased C4b-BP beta + as a cause of the free-PS deficiency. The binding curves of the mutated (Heerlen) PS on C4b-BP immobilized on microplates were biphasic, suggesting that one molecule of C4b-BP can bind two molecules of Heerlen PS. Because normal PS binds to C4b-BP with 1:1 stoichiometry, this may explain the free-PS deficiency observed in patients carrying the Ser 460 to Pro mutation.     

Free protein S levels are elevated in familial C4b-binding protein deficiency

In plasma, 40% of the protein S is free and functions as a cofactor for the anticoagulant effects of activated protein C. The remaining 60% of protein S is complexed to C4b-binding protein and is functionally inactive. A family with hereditary C4b binding protein deficiency has been identified with C4b-binding protein levels in an affected father and daughter of 37 micrograms/mL and 23 micrograms/mL, respectively; these values are significantly below the normal range for this protein of 180 micrograms/mL +/- 44 micrograms/mL (mean +/- 2 SD). The total protein S (free + bound) is normal in these individuals (23.2 micrograms/mL and 17.8 micrograms/mL, respectively; normal 19.1 micrograms/mL +/- 6.0 micrograms/mL). The free protein S levels are markedly increased at 22.5 micrograms/mL and 17.4 micrograms/mL, respectively (normal 5.9 micrograms/mL +/- 2.4 micrograms/mL). This experiment of nature shows that total protein S levels in plasma are not affected by the absence of C4b-binding protein and that chronic elevation of free protein S is not associated with increased hemorrhagic tendencies.     

Expression of the peptide C4b-binding protein beta in the arthritic joint

BACKGROUND: C4b-binding protein (C4BP) is a plasma oligomeric glycoprotein that participates in the regulation of complement and haemostasis. Complement-regulatory activity depends on the C4BPalpha-polypeptide, whereas the C4BPbeta-polypeptide inactivates protein S, interfering with the anti-coagulatory protein C-dependent pathway. OBJECTIVE: To investigate the expression of C4BPbeta in the rheumatoid joint. METHODS: Expression of C4BP was studied in synovial explants from patients with rheumatoid arthritis, osteoarthritis and healthy controls, using immunohistochemistry and in situ hybridisation. C4BP isoforms and free C4BPbeta were studied in synovial effusions from patients with rheumatoid arthritis, osteoarthritis and microcrystalline arthritis (MCA) by immunoblotting; total and free protein S levels were studied by enzyme immunoassay. RESULTS: C4BPbeta was overexpressed in the synovial membranes of patients with rheumatoid arthritis, in close association with the severity of synovitis and the extension of interstitial fibrin deposits. As many as 85% fluids from patients with rheumatoid arthritis contained free C4BPbeta, whereas this unusual polypeptide was present in 50% fluids from patients with MCA and 40% fluids from patients with osteoarthritis. Free protein S at the effusions was pathologically reduced in patients with rheumatoid arthritis and MCA, and remained normal in patients with osteoarthritis. CONCLUSION: C4BPbeta is expressed by the inflamed synovial tissue, where it can participate in processes of tissue remodelling associated with invasive growth.     

Changes in the plasma levels of vitamin K-dependent proteins C and S and of C4b-binding protein during pregnancy and oral contraception

The plasma concentrations of protein S, protein C and C4b-binding protein (C4BP) were analysed during pregnancy, in the postpartum period and in women using oral contraceptives. Free protein S, measured after precipitation of the C4BP-protein S complexes with 5% PEG 6000, was found to be 8.3 mg/l in the control group, which represents 36.3% of the total plasma protein S content (average 23.5 mg/l). The concentration of protein S was significantly decreased during pregnancy, the lowest levels occurring in the second trimester (14.8 mg/l). The values returned to normal within a few days after delivery. The concentration of free protein S was also decreased, down to an average of 3.7 mg/l at delivery, and did not return to normal within the first week postpartum. The mean concentration of protein S in women using oral contraceptives decreased to 17.7 mg/l and the free fraction went down to 6.6 mg/l. Unlike that of protein S, the plasma concentration of protein C increased during pregnancy, reaching a maximum of 135% in the second trimester. Also, it was significantly higher in the postpartum period and in women using oral contraceptives, than in controls. The level of C4BP was increased throughout pregnancy, with a maximum of 143.4% at delivery. These changes in the plasma levels of proteins C and S during pregnancy indicate that the two proteins differ in the regulation of their synthesis. The major decrease in the level of free protein S may predispose to thrombotic episodes during pregnancy, whereas the increased level of protein C may have the reverse effect. These results indicate the importance of taking into account the normal changes in the plasma levels of protein C and S during pregnancy and the use of oral contraceptives, when evaluating patients with increased risk of thromboembolic disease.     

C4b-binding protein: a forgotten factor in thrombosis and hemostasis

Blood coagulation and complement pathways are two important natural defense systems. The high affinity interaction between the anticoagulant vitamin K-dependent protein S and the complement regulator C4b-binding protein (C4BP) is a direct physical link between the two systems. In human plasma, ~70% of total protein S circulates in complex with C4BP; the remaining is free. The anticoagulant activity of protein S is mainly expressed by the free form, although the protein S-C4BP complex has recently been shown to have some anticoagulant activity. The high affinity binding of protein S to C4BP provides C4BP with the ability to bind to negatively charged phospholipid membranes, which serves the purpose of localizing complement regulatory activity close to the membrane. Even though C4BP does not directly affect the coagulation system, it still influences the regulation of blood coagulation through its interaction with protein S. This is particularly important in states of inherited deficiency of protein S where the tight binding of protein S to C4BP results in a pronounced and selective drop in concentration of free protein S, whereas the concentration of protein S in complex with C4BP remains relatively unchanged. This review summarizes the current knowledge on C4BP with respect to its association with thrombosis and hemostasis.     

Increased activation of protein C, but lower plasma levels of free, activated protein C in uraemic patients: relationship with systemic inflammation and haemostatic activation

Chronic renal failure (CRF) courses with both systemic inflammatory reaction and haemostatic activation. We explored the relationship of these processes with plasma levels of free, activated protein C (APC) and complexes of APC with its inhibitors in patients with CRF under conservative treatment. Plasma concentrations of inflammatory cytokines [tumour necrosis factor alpha (TNFalpha) and interleukin 8], acute-phase proteins (C-reactive protein, fibrinogen, alpha1-anti-trypsin and von Willebrand factor), and markers of haemostatic activation (thrombin-anti-thrombin complexes, plasmin-anti-plasmin complexes, and fibrin and fibrinogen degradation products) were higher in patients than in controls. Inflammatory and haemostatic markers were significantly and positively correlated. Total plasma APC and APC:alpha1-anti-trypsin (alpha1AT) complexes were 44% and 75% higher in patients than in controls (P = 0.0001), whereas free APC was 20% lower (P < 0.015). No significant difference was observed in APC:protein C inhibitor (PCI) complexes between both groups. The free/total APC ratio was significantly lower in patients than in controls (P < 0.0001). Total plasma APC and APC:alpha1AT were positively correlated with activation markers of haemostasis and acute-phase proteins, whereas free APC was inversely correlated with plasma levels of creatinine, acute-phase proteins and fibrin degradation products (FnDP). Systemic inflammation and activation of haemostasis are interrelated processes in CRF. APC generation was increased in response to elevated thrombin production, but the inflammatory reaction, associated with increased synthesis of alpha1AT, reduced its anticoagulant effect. Lower free plasma APC in CRF may be pathogenically associated with atherothrombosis, a major cause of death in this disease.     

Protein C and S levels in acute leukemia.

Patients with acute leukemia undergoing remission induction chemotherapy occasionally develop venous thrombosis despite severe thrombocytopenia and in the absence of disseminated intravascular coagulation. This observation prompted us to study the levels of the naturally occurring anticoagulant proteins C and S prospectively in patients undergoing remission induction chemotherapy for acute leukemia. Plasma samples from 50 adult patients with acute leukemia (34 AML, 16 ALL) were analyzed for protein C antigen, functional protein C, immunologic total and free protein S as well as levels of C4b binding protein (C4bBP). Plasma levels of immunologic protein C were significantly lower in patients with active acute myelocytic leukemia (mean = 77.9) than in controls (mean = 123.6) or patients in remission (mean = 132). Functional protein C levels were also significantly lower in AML patients with active disease (mean = 58.5) than controls (mean = 95.5) or patients in remission (mean = 98.5). Patients with acute lymphocytic leukemia (ALL) had normal levels of immunologic and functional protein C. Although total protein S levels were normal in all patients studied, levels of free protein S were significantly decreased in patients with active AML (mean = 29.3) compared with patients in remission (mean = 42.0) or controls (mean = 42.4). In contrast, patients with ALL, both with active disease and in remission had normal free protein S levels. This decrease in free protein S seen in active AML was not associated with liver disease, white cell count or an increase in C4bBP. These findings provide a possible explanation for the occasional occurrence of venous thrombosis in patients with acute myelocytic leukemia.     

Functional assay of protein S in 70 patients with congenital and acquired disorders.

A functional assay for the selective measurement of the active form of protein S in plasma, based on the prolongation of an APTT, was previously developed. This assay is sensitive, reproducible and specific, not affected by other clotting factors including FVIII. This method was applied to the measurement of protein S activity in congenital and acquired disorders. Results of protein S activity were compared to those of total and free antigen measured by ELISA. In 30 controls, there was an excellent correlation between protein S activity and free antigen. In patients with inflammatory disease, protein S activity and free antigen were normal, despite high levels of both C4b-binding protein and total protein S antigen. In dicoumarol-treated patients, protein S activity was lower than free antigen due to the presence of acarboxylated forms. Surprisingly, in liver cirrhosis, free antigen was only slightly decreased whereas protein S activity was significantly reduced. In 23 patients with congenital deficiency, protein S activity was consistently decreased, from less than 5% to 60% and showed good correlation with the free antigen. This functional assay allows the rapid diagnosis of congenital or acquired deficiency of protein S.     

Functional and immunologic protein S levels are decreased during pregnancy

Protein S, is a natural anticoagulant protein which serves as a cofactor for activated protein C. During pregnancy and in the postpartum period, functional protein S levels are significantly reduced (38% +/- 17.3%, mean +/- 1 SD) when compared to nonpregnant females (97% +/- 31.6%) (P less than 0.001). In plasma an equilibrium exists between functionally active free protein S and protein S complexed with C4b-binding protein, which is functionally inactive. As a result of this equilibrium either a decreased level of total protein S antigen or an elevation of C4b-binding protein could lead to reduced protein S activity. C4b-binding protein levels measured by enzyme- linked immunoassay are not significantly different in pregnant women versus nonpregnant controls (103.5% +/- 21.2% v 100% +/- 16.9%). However, during pregnancy and in the postpartum period, total protein S levels are reduced (68% +/- 10.7%) compared to nonpregnant controls (100% +/- 17.0%). This difference is significant at P less than 0.001. These data demonstrated that the reduction in protein S activity observed during pregnancy is a result of reduced total protein S antigen.     

Protein S and C4b-binding protein in fetal and neonatal blood

The levels of protein C, free protein S, C4b-binding protein and the distribution of total protein S between a free form and a conjugated form with C4b-binding protein, were measured in fetuses between 15 and 35 weeks of gestation, in newborns and in maternal blood throughout pregnancy. Fetal and newborn umbilical blood samples were obtained by cordocentesis; in the case of newborns, immediately after delivery. C4b-binding protein was detected in five out of seven newborns and in only three out of 20 fetuses. The fetuses (21, 24, 29 weeks, respectively) whose blood contained C4b-binding protein (10%, 29%, 12% of adult level, respectively), did not survive: the possible cause of death for one was given as viral infection; all three were severely deformed. Only free protein S was detected in fetal blood and the mean value was 40%. By contrast, the mean levels of protein C in the fetuses increased from 11% to 15.5% of adult levels with advancing gestation. We conclude that the relatively high levels of free protein S in fetal blood may contribute to its non-coagulability and compensate for the low protein C levels.     

Case report: a novel form of free protein S deficiency in an HIV-positive patient on hemodialysis.

Investigation of repetitive thrombotic episodes in an HIV-positive patient on maintenance hemodialysis revealed extraordinarily high levels of total (free plus protein bound) protein S antigen but severe reductions in free (interactive) protein S antigen. Patients with the nephrotic syndrome or chronic renal failure have shown elevations of total protein S antigen, associated with increased levels of the specific C4b-binding protein, yet have had normal free protein S antigen levels. Based on the fall in total and free protein S levels during hemodialysis treatments, the presence of normal levels of C4b-binding protein, and the coexistence of a polyclonal gammopathy, the authors infer the presence of a unique protein that binds protein S in this patient and that is not apparent in normal plasma. The anomalous association of protein S with this binding protein resulted in levels of free protein S antigen in the range of those reported in hereditary deficiencies of the anticoagulant.     

An abnormal plasma distribution of protein S occurs in functional protein S deficiency

Protein S is a natural anticoagulant present in the plasma that serves as a cofactor for activated protein C. Patients deficient in protein S are subject to recurrent venous thrombotic disease. Protein S deficiency differs from other plasma protein deficiencies in that deficient patients often have normal or only mildly reduced levels of protein S in their plasma as detected by conventional immunologic methods but have markedly reduced functional protein S levels. This apparent discrepancy is due to the presence of two forms of protein S in plasma. The protein S is present free and in a complex with C4b-binding protein. The free form is functionally active, whereas the bound form is not. Examination by crossed immunoelectrophoresis of 31 functionally protein S-deficient individuals from seven families reveals that 29 of the 31 have all or most of their protein S complexed to C4b-binding protein with little or no free protein and have correspondingly low levels of protein S functional activity (type I deficiency). Two related protein S-deficient individuals show a different type of distribution with little or no protein S, either bound or free (type II deficiency). The detection and classification of protein S-deficient individuals requires the application of both a functional assay and an assessment of protein S distribution between bound and free forms.     

Septic shock, multiple organ failure, and disseminated intravascular coagulation. Compared patterns of antithrombin III, protein C, and protein S deficiencies.

STUDY OBJECTIVE: Our aim was to document the following in patients with septic shock and disseminated intravascular coagulation (DIC): (1) the influence of DIC in the mortality rate and the occurrence of organ failure; (2) the comparative prognostic value of initial antithrombin III (ATIII), protein C (PC), and protein S (PS) levels; and (3) the compared pattern of sequential ATIII, PC, and PS levels according to clinical outcome. DESIGN: Demographic data, criteria of severity, mortality in ICU, frequency of organ failure, hemodynamic and oxygenation parameters, and laboratory findings were compared in patients with septic shock according to the occurrence of DIC. Initial and sequential levels of ATIII (activity), PC (antigen and activity), PS (total and free), and C4b binding protein (C4bBP) were compared according to the outcome in patients with DIC. PATIENTS: Sixty patients with septic shock were studied. Forty-four entered the group DIC+; 16 entered the group DIC-. RESULTS: Simplified acute physiologic score (SAPS), frequency of acquired organ failure, blood lactate, and transaminase values were significantly higher in the group DIC+. The mortality rate reached 77 percent in group DIC+ vs 32 percent in DIC- (p less than 0.001). In patients with DIC, a fatal outcome was associated with higher bilirubin and transaminase levels, lower PaO2/FIo2 ratio, Vo2, Do2 and O2 extraction. In the group DIC+, all patients but two had severe deficiencies in ATIII and PC levels. Significant correlations were found between initial ATIII and PC levels, PC and free PS levels, and free PS and C4bBP levels. Initial ATIII levels had the best prognostic value for prediction of subsequent death. Serial measurements were consistent with a prolonged ATIII and PC deficiency with significantly different levels between survivors and nonsurvivors. CONCLUSIONS: DIC is a strong predictor of death and multiple organ failure in patients with septic shock. Sequential ATIII, PC, and PS measurements were consistent with prolonged consumption or inhibition that might account for a sustained procoagulant state and inhibition of fibrinolysis. The initial ATIII level was the best laboratory predictor of death in these patients.     

Lack of Correlation Between Activation of Hemostatic Mechanism and Inflammation in Unstable Angina Pectoris

In the acute phase of unstable angina, activation of the hemostatic mechanism is demonstrated by an increase in the plasma levels of markers of thrombin generation (prothrombin fragment 1+2) and thrombin activity (fibrinopeptide A). Increased concentrations of plasma C-reactive protein, an acute-phase reactant, have also been reported in patients with unstable angina. However, whether there is a correlation between the activation of the hemostatic mechanism and the acute-phase reaction of inflammation remains unclear. We measured the plasma levels of prothrombin fragment 1+2, fibrinopeptide A, and C-reactive protein in 91 patients consecutively hospitalized with recent-onset rest angina (Class IIIB Braunwald's classification), finding that they were above the normal limits in 48 (53%), 45 (49%), and 30 (33%) patients, respectively. There was no correlation between prothrombin fragment 1+2 and fibrinopeptide A (P = 0.34), prothrombin fragment 1+2 and C-reactive protein (P = 0.10), or fibrinopeptide A and C-reactive protein (P = 0.75). Plasma levels of prothrombin fragment 1+2 and fibrinopeptide A were both above normal levels in 32% of patients; 19% had both prothrombin fragment 1+2 and C-reactive protein, and 18% both fibrinopeptide A and C-reactive protein levels above the upper normal limits. All three markers were abnormally high in 11% of patients. According to the kappa cofficient test, the agreement between the elevation of the plasma concentrations of the markers was "random." In approximately half of the patients with acute unstable angina, there was an increase in the markers of the activation of the hemostatic mechanism and, in a smaller proportion, an increase in plasma C-reactive protein levels. The activation of the coagulation cascade and the acute-phase reaction of inflammation were infrequently associated in individual patients.     

Plasma concentrations of total/free and functional protein S are not decreased in systemic lupus erythematosus patients with lupus anticoagulant and/or antiphospholipid antibodies

Summary We conducted an investigation to clarify whether or not the levels of total, free, and functional protein S and C4-binding protein (C4bp) in plasma are decreased in systemic lupus erythematosus (SLE) patients, especially those with antiphospholipid antibody (aPL), which is known to be a causative factor of such complications as habitual abortion and arteriovenous thrombosis. Fifty patients with SLE were recruited as subjects of the study. Serum aPL (anticardiolipin, antiphosphatidyl serine, antiphosphatidyl inositol, and antiphosphatidic acid antibodies) were measured by ELISA. Lupus anticoagulant was determined by aPTT, KCT, and diluted RVVT. Furthermore, plasma concentrations of total, free, and functional protein S and C4bp were measured. There were no significant differences in the mean levels of total, free, or functional protein S and C4bp between aPL-positive, aPL-negative SLE patients, and the healthy controls. From these results, we concluded that the protein S level is not the sole factor causing complications, and that other factor(s) may be involved in the induction of such complications in this clinical setting.