Hymie L. Nossel

Measurement of Fibrinopeptide A in Human Blood

Since thrombin cleaves fibrinopeptides A (FPA) and B from the NH(2)-terminal end of the fibrinogen molecule, measurement of fibrinopeptide levels in plasma may provide a direct index of thrombin action. Recently a radioimmunoassay for FPA has been developed, and in the present paper, we describe the application of this assay to the measurement of FPA levels in clinical blood samples. Since fibrinogen cross-reacts with antibodies to FPA, dialysis was used to extract the peptide from plasma. In vitro generation of FPA was prevented by removing the fibrinogen from the plasma by precipitation with ethanol before dialysis. The processing technique permitted recovery of 75% of FPA added to blood in vitro. Evidence that the immunoreactivity measured in plasma is due to FPA was provided by the results of experiments in which two antisera to FPA with different specificities showed comparable results and addition of thrombin caused no change in immunoreactivity. In contrast, extracts of streptokinasetreated plasma showed a five-fold increase in activity when treated with thrombin and markedly different immunoreactivity with the two antisera. Plasma FPA levels in 30 normal men were below 2 ng/ml, with a mean of 0.5 ng/ml. FPA levels in 12 patients with reduced fibrinogen levels or reduced platelet counts or both ranged between 4 and 289 ng/ml. FPA levels in 13 patients with normal or elevated fibrinogen levels, including 6 patients with clinical evidence of venous thrombosis or pulmonary embolism or both, ranged between 5 and 23 ng/ml. FPA and fibrinogen degradation product levels did not correlate, and in several patients, elevated FPA levels were found in the presence of normal fibrinogen degradation product levels. After infusion of FPA-containing solutions in four normal individuals, FPA showed a disappearance rate from the plasma consistent with a t((1/2)) of 3-5 min. Heparin infusions in six patients with venous thrombosis or pulmonary embolism or both and elevated FPA levels were followed by a prompt decline in FPA level at a mean rate equivalent to a 3-5 min t((1/2)).

Studies of the Release from Human Platelets of the Growth Factor for Cultured Human Arterial Smooth Muscle Cells

Platelets contain a growth-promoting factor for arterial smooth muscle cells (SMC) that may play a major role in atberogenesis. We have studied some of the effects of the platelet-derived growth factor (PDGF) on human arterial SMC in culture and the release of PDGF from human platelets in relationship to other released substances. Material released from platelets was highly potent in stimulating human SMC to proliferate. A substantial portion of the growth-promoting activity of human serum could be attributed to a factor(s) released from platelets. Similar dose-response patterns to PDGF were observed with human SMC and with mouse 3T3 cells. The time-course of release of PDGF and its concentration dependence on human thrombin were determined in comparison with serotonin, ADP, ATP, an acid bydrolase, platelet factor 4 (PF4), and β-thromboglobulln (βJTG). PDGF activity was assayed by stimulation of the incorporation of +-H-thymidine into DNA of 3T3 cells; PF4 and βJTG were measured by newly developed radioimmunoassays. PDGF, PF4, and βJTG were released from platelets by lower concentrations of thrombin than those required for release of the other components. The results suggest that PDGF, PF4, and βTG are localized in the platelet in granules different from either the dense bodies (that contain serotonin, ADP, ATP) or the acid hydrolase-containing granules, possibly in α-granules. The contents of these PDGF- containlng a-granules are actively released during the release reaction and are particularly sensitive to release by low doses of thrombin.

Radioimmunoassay of Platelet Factor 4 and β-Thromboglobulin: Development and Application to Studies of Platelet Release in Relation to Fibrinopeptide A Generation

Summary. Platelet and fibrinogen survival and turnover studies have shown that platelet activation and fibrin formation may occur to different degrees in different thrombotic disorders. More direct evidence of differential involvement of platelet activation and fibrin formation should be provided by specifically measuring the products of these reactions, i.e. released platelet proteins and fibrinopeptide A. Two platelet proteins, platelet factor 4 (PF4) and β‐thromboglobulin (βTG), were isolated and characterized, and sensitive and specific radioimmunoassays were developed to measure them. These assays were employed, along with the radioimmunoassay for fibrinopeptide A (FPA), to study the release of PF4 and βTG in relation to FPA cleavage. PF4 and βTTG were released by ADP and collagen with time course and concentration dependence similar to that of [14C]serotonin release. FPA was not cleaved from fibrinogen during ADP or collagen‐induced platelet release. Thrombin caused release of PF4 and βTTG as well as cleavage of FPA. Cleavage of FPA occurred with concentrations of thrombin about 100 times less than did release of PF4 and βTG, and release of [14C]serotinin required still higher thrombin concentrations. Release of [14C]serotonin and platelet proteins was similar as a function of time. Sodium citrate was found to inhibit platelet release induced by thrombin.

The generation of fibrinopeptide A in clinical blood samples: evidence for thrombin activity.

Plasma fibrinopeptide A (FPA) concentrations were measured in clinical blood samples incubated in the collecting syringe for different time periods before addition to heparin and Trasylol, and the rate of in vitro generation of FPA was calculated as the mean increment in FPA concentration per minute over the linear portion of the generation curve. 36 normal individuals had a mean plasma FPA level of 0.64 +/- 0.56 pmol/ml and an FPA generation rate of less than 0.5 pmol/ml per min. Clinical samples with elevated plasma FPA levels manifested slow (less than 1 pmol/ml per min) (28 patients) or rapid FPA generation (greater than 1 pmol/ml per min) (33 patients). Slow FPA generation was found in 10/10 patients with venous thrombosis, in 4/4 with aortic aneurysm, and in several patients with acquired hypofibrinogenemia. In one such patient, addition of fibrinogen resulted in rapid FPA generation whereas thrombin addition was without effect. Rapid FPA generation was generally linear, was usually associated with slower fibrinopeptide B generation and was inhibited by parenteral or in vitro heparin. It is thought to reflect increased thrombin activity and was seen in patients with pulmonary embolism, active systemic lupus erythematosus, renal transplant rejection, and after infusion of prothrombin concentrates. The initial rate of FPA cleavage by thrombin at fibrinogen concentrations from 0.05 to 4 mg/ml showed little change between 2 and 4 mg/ml with a Km of 2.99 muM. At a fibrinogen concentration of 2.5 mg/ml the FPA cleavage rate was 49.2 +/- 1.6 nmol/ml per min per U of thrombin. Exogenous thrombin added to normal blood generated 21.7 nmol/ml per U of thrombin FPA in the first minute with a nonlinear pattern reflecting inactivation of thrombin and the presence of alternative substrates. Hence, the thrombin concentration in the blood cannot be calculated from the FPA generation rate. The FPA generation rates in clinical samples with rapid generation (1-28 pmol/ml per min) could be produced by 2 X 10(-5) to 5.6 X 10(-4) thrombin U/ml acting on purified fibrinogen at physiological conditions of pH, ionic strength, and temperature.

Sequence of Fibrinogen Proteolysis and Platelet Release after Intrauterine Infusion of Hypertonic Saline

Plasma fibrinopeptide B (Bbeta1-14 or FPB) immunoreactivity was studied by radioimmunoassay in patients who received intrauterine infusion of hypertonic saline to terminate pregnancy. FPB immunoreactivity increased with thrombin treatment (TIFPB) suggesting the presence of a larger FPB-containing peptide, since purified FPB is not altered by thrombin, whereas thrombin increases the immunoreactivity of Bbeta1-42 (which includes FPB) 10-fold. TIFPB immunoreactivity in plasma, drawn 4 h after hypertonic saline infusion eluted from Sephadex G-50 similarly to isolated Bbeta1-42. Streptokinase, incubated with normal plasma progressively generated TIFPB immunoreactivity, which showed a major component which eluted from Sephadex G-50 similarly to Bbeta1-42. Streptokinase generated TIFPB much more rapidly in reptilase-treated plasma that contains fibrin I, (which still includes FPB), indicating that fibrin I is preferred over fibrinogen as a substrate for plasmin cleavage of arginine (Bbeta42)-alanine (Bbeta43). Serial studies were then made in 10 patients receiving intrauterine hypertonic saline. Fibrinopeptide A (FPA) levels rose immediately, reached a peak between 1 and 2 h, were declining at 4 h, and were normal at 24 and 48 h. TIFPB levels rose slightly in the 1st h, reached a peak at 4 h, and had returned to base-line values at 24 h. Serum fibrinogen degradation product levels were unchanged at 1 h, reached their highest level at 4 h, and were still markedly elevated at 24 and 48 h. Fibrinogen levels dropped slightly being lowest at 4 and 24 h. Platelet counts declined in parallel with the fibrinogen levels over the first 4 h, but continued to decrease through 48 h. Beta thromboglobulin (betaTG) levels generally paralleled FPA levels whereas platelet factor 4 (PF4) levels showed only slight changes. The data indicate that immediately after intrauterine hypertonic saline infusion thrombin is formed that cleaves FPA from fibrinogen to produce fibrin I and releases betaTG and PF4 from platelets. Later plasmin cleaves Bbeta1-42 from fibrin I to produce fragment X, which is further degraded to form serum fibrinogen degradation products. This sequence of proteolysis indicates that plasmin action on fibrin I serves as a mechanism that regulates fibrin II formation by removing the Bbeta chain cleavage site, which is required for thrombin action in converting fibrin I to fibrin II.

Radioimmunoassay of human fibrinopeptide B and kinetics of fibrinopeptide cleavage by different enzymes.

Thrombin converts fibrinogen to fibrin monomer by cleaving fibrinopeptides A and B (FPA and FPB) from the amino terminal ends of the A (alpha) and B (beta) chains. A radioimmunoassay capable of measuring the A peptide in human blood as an index of thrombin action in vivo has been described previously. This paper describes the development of a radioimmunoassay for FPB and the use of both assays in the demonstration of distinctive patterns of cleavage of the amino terminal ends of the A (alha) and B (beta) chains of fibrinogen by various enzymes. Antisera were raised in rabbits to a synthetic analogue of FPB coupled to bovine serum albumin. FPB analogue was couple to desaminotyrosine and radiolabeled with 125I by the chloramine-T technique. The radiolabeled peptide was bound by the antiserum, and binding was inhibited by synthetic or native FPB. Unbound tracer was separated from bound tracer by charcoal adsorption. The senistivity of the assay was such that 50% inhibition of binding of the tracer was caused by 1.25 ng of the native FPB. Fibrinogen was treated with thrombin, plasmin, trypsin, Reptilase, and an extract of the venom from Ancistrodon contortrix contortrix (ACC). After ethanol precipitation and centrifugation, dialysates of enzymatically altered fibrinogen were assayed for FPA and FPB. The action of thrombin on fibrinogen resulted in a rapid release of FPA and a slower release of FPB. Plasmin cleaved a segment(s) of the B (beta) chain which included FPB but cleaved no detectable FPA-containing material for the first 2 h of incubation. In the case of plasmin-treated fibrinogen, the dialysates had been further treated with thrombin before being assayed for FPA and FPB. Trypsin rapidly cleaved both peptides, the B before the A. Reptilase cleaved only FPA in 24 h. ACC cleaved FPB at a rapid rate, with a slowere cleavage of FPA. The distinctive cleavage patterns produced by the serine proteases may be useful in interpreting the levels of FPA and FPB measured in human blood and in studying the generation of FPA and FPB in clinical blood samples.

Acquired Antibody to Factor XI in a Patient with Congenital Factor XI Deficiency

The results of studies in a patient with congenital deficiency of Factor XI who developed an inhibitor are presented. The patient presented with a severe, apparently spontaneous bleed into the thigh, which progressed despite infusion of fresh frozen plasma, but which responded promptly to activated prothrombin complex. During therapy with plasma his clotting time and Factor XI level were unresponsive and a Factor XI inhibitor titer of 6,000 U/ml was attained. The inhibitor was isolated and found to be polyclonal immunoglobulin G (IgG), predominantly of subclass 4. The specificity of the antibodies for Factor XI was shown by the ability of isolated inhibitor bound to polyacrylamide beads to remove Factor XI selectively from normal plasma. The binding of (125)I-labeled factor XI to the inhibitor was studied and an affinity constant of 1.65 x 10(10) liter/mol was found. Complexing of the antibodies with Factor XI was shown to block multiple activities of the clotting factor. Factor XI complexed with antibody did not bind to high molecular weight kininogen or undergo activation and cleavage by two-chain Factor XII. The complex of activated Factor XI with inhibitor prevented the cleavage and activation of Factor IX. Hence the inhibitor appears to act by binding to multiple sites on the Factor XI molecule and preventing its interaction with other molecules. Clinically these interactions of the inhibitor with Factor XI result in a state of severe Factor XI deficiency. The clinical circumstances of the case, with severe hemorrhage refractory to plasma infusion but readily responsive to an alternate clot-promoting agent, suggest that a defect of intrinsic system activation was critical, supporting the inference that Factor XI does participate in normal hemostasis. The clinical course of this patient, who has only had two documented hemorrhages in the presence of the inhibitor, is not as severe as that of patients with severe Factor VIII or IX deficiency. This suggests that physiologic activation of Factors XI and IX does not occur exclusively in series because deficiency of factors XII, XI, VIII, and IX should then have similar hemostatic consequences. We propose that independent mechanisms for bypass of Factors XII and XI are important in physiologic activation of coagulation.

Fibrin polymerization and release of fibrinopeptide B by thrombin

Abstract Although it is well known that thrombin releases fibrinopeptide A (FPA) more rapidly than fibrinopeptide (FPB) from fibrinogen different opinions have been expressed as to whether fibrin I (FPA release) and II (FPB release) are sequential or simultaneous. Evidence has been presented that FPB release depends on the polymerization of fibrin and the finding that the tetrapeptide gly-pro-arg-pro inhibits fibrin formation provides a new tool to investigate the effect of polymerization. The radioimmunoassay technique which permits the initial rates of the release reactions to be accurately measured at low concentrations of reactants was used to investigate FPB release. In the absence of gly-pro-arg-pro the FPB release pattern showed three phases - an initial slow and a second more rapid phase both of which were at a constant rate and a final phase with decreasing rate as the substrate concentration fell. Gly-pro-arg-pro at appropriate concentrations inhibited fibrin polymerization as indicated by optical density and light scattering techniques as well as by gel filtration on Sephadex G-200. FPA release and the initial rate of FPB release were unaffected. The second phase of rapid FPB release was abolished indicating that this increased rate is entirely dependent on the polymerization of fibrin I. Under one set of specified conditions the initial release rates of FPB by thrombin from different substrates were 15.8 pmol/min (fibrinogen), 14.0 pmol/min (fibrinogen plus gly-pro-arg-pro), 27.4 pmol/min (fibrin I monomer) and 164.4 pmol/min (fibrin I polymer). The data indicate that fibrin I and II formation are not sequential but simultaneous and that it is the more rapid formation of fibrin I which results in the appearance of a sequential reaction. It is suggested that a number of other reactions in the hemostatic system including fibrinolysis which appear to be sequential are also simultaneous.

Measurement of desarginine fibrinopeptide B in human blood.

Thrombin converts fibrinogen to fibrin in two steps. First fibrinopeptide A and fibrin I are formed and then fibrinopeptide B (B beta 1-14) and fibrin II. Since it is postulated that fibrin II is important in the genesis of thrombosis, it is of interest to measure fibrinopeptide B in peripheral blood samples. Previous difficulties in interpreting fibrinopeptide B immunoreactivity in plasma resulted from crossreaction of fibrinogen and of plasmin digest peptides B beta 1-42 and B beta 1-21 and from rapid loss of fibrinopeptide B immunoreactivity resulting from cleavage of arginine 14 by blood carboxypeptidase B. We have obviated these difficulties by removing fibrinogen from plasma by precipitation with ethanol and peptides B beta 1-21 and B beta 1-42 by adsorption on bentonite. Fibrinopeptide B is then converted to a desarginine fibrinopeptide B, which is measured in a new specific assay. Studies of the kinetics of fibrinopeptide cleavage showed that when whole blood was allowed to clot in vitro, fibrinopeptide A was cleaved more rapidly than fibrinopeptide B. In 18 patients on an acute care medical ward, desarginine fibrinopeptide B levels were lower than fibrinopeptide A levels and did not correlate with the levels of fibrinopeptide A or B beta 1-42. Desarginine fibrinopeptide B levels were less than 1 pmol/ml in all but two patients. In six patients receiving intraamniotic infusions of hypertonic saline to induce abortion, desarginine fibrinopeptide B levels increased 10-fold from the preinfusion mean level of 0.4 pmol/ml and then decreased. The pattern of changes resembled that of the fibrinopeptide A levels rather than of the B beta 1-42 levels. On the basis of these data it is suggested that plasma desarginine fibrinopeptide B levels reflect fibrin II formation in vivo.

Fibrinopeptide release from fibrinogen.

Proteolysis of fibrinogen occurs in hemostasis, thrombosis, inflammation and many disease states. Every enzyme that attacks the molecule releases the fibrinopeptides in a distinct pattern. Hence measurement of the released peptides indicates not only formation of particular fibrinogen derivatives but reflects the action and hence formation of specific enzymes. Knowledge of the peptide bonds cleaved by a protease forms an essential basis for analyzing its action. Identification of these peptide bonds has generally been made by identifying newly exposed NH,-terminal amino acids. The released peptides have been quantified by radioimmunoassay or by elution pattern on high performance liquid chromatography (HPLC) . Before discussing thrombin and plasmin action on fibrinogen the action of some other enzymes will first be briefly considered.