Specific Activities of Bovine Thrombin and Thrombin Components

D. F Waugh; R. D Rosenberg

doi:10.1055/s-0038-1649355

Thrombosis and Haemostasis, Table of Contents

Thromb Haemost 1972; 27(02): 183-195
DOI: 10.1055/s-0038-1649355

Originalarbeiten — Original Articles — Travaux Originaux

Schattauer GmbH

Specific Activities of Bovine Thrombin and Thrombin Components

D. F Waugh

¹Department of Biology, Massachusetts Institute of Technology, Cambridge, Massachusetts, 02139

,

R. D Rosenberg^*

¹Department of Biology, Massachusetts Institute of Technology, Cambridge, Massachusetts, 02139

› Author Affiliations

Abstract

Summary

Bovine thrombins (Gel-T) isolated from bioactivated crude prothrombin, obtained from Holstein, Jersey and Hereford single animal plasmas, occur in two distributions: either T₁, T₂ and T₃ as 1:2:1 (Type I), or T₁ and T₂ as 1:1, with T₃ absent or present to the extent of 5% of total Thrombin (Type II). Since components differentially denature during procedures used to fractionate, examinations of Gel-T were conducted so that statistical procedures could be used to evaluate particular variances. The variance due to the Gel-T preparative procedure and Gel-T intrinsic specific activity yield a coefficient of variance (S_c) of 0.55%. Thus 95% of single animal Gel-T specific activities fall within 1.1% of the average value. There are no significant differences between animals of different breed, or of bloods drawn from the same animal at different times. Evidently, Gel-T represent a reproducible reference standard. Analysis of distributions shows that the intrinsic specific activities of thrombin components are identical to within 1 %, and are approximately 1.0 NIH unit per 6.0 × 10⁻⁴ absorbance unit (3,250 ±450 NIH units per mg). The clotting time (τ) - thrombin concentration (T) relation, log τ = — ã log T + C, is examined. Over the range of τ from 15 to 60 sec it is shown that a T series can be reproduced to within 1 % in thrombin concentration. The variances in the assay system are then due almost entirely to variance in the assay substrate, fibrinogen. These are an S_c of 1.7% for τ̄ between sets of tubes containing dilute fibrinogen (τ-tubes) from one lot of Stock-F, and S_c of 12% between τ̄ for sets of τ-tubes from Stock-F prepared from different lots of Armour Fraction-I, and an S_c of 1.9% for ã̄( =0.679) for sets of T-tubes, obtained either from one Stock-F or Stock-F obtained from different lots of Fraction-I. Errors in several procedures for determining unknown thrombin concentrations are examined.

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References

References
1 Baughman D. J, Waugh D. F. Bovine Thrombin: Purification and Certain Properties. J. biol. Chem 248: 5252 1967;
2 Baughman D. J, Waugh D. F, Juvkam-Wold G. Properties of Thrombin and Fibrinogen: The Comparison of Clotting Time. Thrombos. Diathes. haemorrh. (Stuttg) 20: 477 1968;
3 Bennett G. A, Franklin N. L. Statistical Analysis in Chemistry and the Chemical Industry. John Wiley and Sons; New York: 1954
4 Biggs R, Macfarlane R. G. Human Blood Coagulation. 3rd. edition. F.A. Davis Co; Philadelphia: 1962
5 Ferguson J. H. Thromboplastic Enzymes, Thrombokinase, Thromboplastin and Blood Clotting: A critical Review. Hematol. Rev 01: 69 1968;
6 Ganguli M. Sank. Hyà. 05: 499 1941; See also W.T. Federer, Experimental Design. Macmillan Co., New York 1955.
7 Kezdy F. J, Lorand L, Miller K. D. Titration of Active Centers in Thrombin Solutions. Standardization of the Enzyme. Biochemistry 04: 2302 1965;
8 Lanchantin G. G, Plesset M. L, Friedman J. A, Hart D. W. Dissociation of Esterolytic and Clotting Activities of Thrombin by Trypsin-binding Macroglobulin. Proc. Soc. exp. Biol. (N. Y) 121: 444 1966;
9 Lanchantin G. F, Presant G. A, Hart D. W, Friedman J. A. A Comparison of the Esterase (TAME) and Clotting Activities of Human and Bovine Thrombin Preparations. Thrombos. Diathes. haemorrh. (Stuttg) 14: 159 1965;
10 Landaburu R, Seegers W. H. The acétylation of Thrombin. Canad. J. Biochem 37: 1361 1959;
11 Margolis J, Bruce S. An experimental Approach to the Kinetics of Blood Coagulation. Brit. J. Haemat 10: 513 1964;
12 Minimum Requirements of Dried Thrombin, second Revision. Division of Biological Control, National Institutes of Health; Bethesda, Maryland: 1946
13 Rosenberg R. D, Waugh D. F. Multiple Bovine Thrombin Components. J. biol. Chem 245: 5049 1970;
14 Seegers W. H. (editor): Blood Clotting Enzymology. Academic Press; New York: 1967
15 Sherry S, Troll W. The Action of Thrombin on Synthetic Substrates. J. biol. Chem 208: 95 1954;
16 Shinowara G. Y. Human Thrombin and Fibrinogen: The Kinetics of Their Interaction and the Preparation of the Enzyme. Biochim. biophys. Acta (Amst) 113: 359 1966; See also ref. 7.
17 Ware A. G, Seegers W. H. Two Stage Procedure for the Quantitative Determination of Prothrombin Concentration. Amer. J. clin. Path 19: 471 1949;
18 Waugh D. F, Baughman D. J, Juvkam-Wold G. Thrombin-Fibrinogen Clotting Times: Instability and Assay Variance. Thrombos. Diathes. haemorrh. (Stuttg) 20: 497 1968;
19 Waugh D. F, Baughman D. J, Miller K. D. Ch. 10 in The Enzymes,. Boyer P. P, Lardy H, Myrback K. (editors). Vol. 4, 2nd edition. Academic Press; New York: 1961
20 Winzor D. J, Scheraga H. A. Studies of Chemically Reacting Systems on Sephadex. II. Molecular Weights of Monomers in Rapid Association Equilibrium. J. Phys. Chem 68: 338 1964;