Human thrombin: Partial primary structure

Human thrombin, prepared from an extrinsically activated prothrombin, was finally chromatographed on an affinity column of p-chlorobenzylamido-?-aminocaproyl agarose. After reduction and s-pyridylethylation, the A and B chains were separated. The A chain contains 36 residues and no carbohydrate and has a formula weight of 4093. Its sequence corresponds to 14–49 of the bovine A chain sequence with nine replacements. Human B chain contains 264 residues. The carbohydrate content is 3.5% neutral sugar, 2.6% glucosamine, and 1.5% sialic acid. High-speed sedimentation equilibrium in guanidine gave a minimum molecular weight of 33,500. Sequenator analysis yielded the first 50 amino-terminal residues and established the positions of three of the cyanogen bromide fragments. A fourth fragment lacked homoserine and was placed at the carboxyl-terminus. The four remaining fragments, comprising half of the B chain, were tentatively assigned positions by assuming homology with bovine thrombin and with pancreatic serine proteases. Within the B chain, the active site histidine and serine were both in highly conservative regions, and an Arg-Tyr bond has been identified as a biological degradation site. Sixty-nine percent of the primary structure of human thrombin was identified by sequenator analysis. In comparing this sequence with that reported for the bovine molecule, 26 replacements are present.     

The Preparation of Trypsins and Chymotrypsins From Bovine and Porcine Residues After Insulin Extraction

Bovine and porcine pancreatic residue, remaining after the extraction of insulin, has been used to prepare a proteinase powder. This powder was used as a source of trypsin and chymo-trypsin. The individual enzymes were isolated and purified by chromatography on sulfopropyl (SP)-Sephadex C-25 and affinity chromatography on soybean trypsin inhibitor (STI)-Sepharose. The bovine proteinase powder contained a-chymotrypsin, trypsin and chymotrypsin B in the ratio 5:2:1. The porcine powder contained cationic trypsin, anionic trypsin and cationic chymotrypsin in the ratio 5 : 1. 4 : 3. The isolated enzymes were characterized and found to be identical with enzymes isolated from fresh tissue with the exception of porcine chymotrypsin. Porcine cationic chymotrypsin was isolated as two distinct forms, A-l and A-2, which appear to be different activation products of porcine chymotrypsinogen A. Both forms resemble bovine a-chymotrypsin, a three chain structure, rather than porcine chymo-trypsin A, a two chain structure. Furthermore, the B-chain appears to be cleaved, possibly at residues Phe₈₉-Lys₉₀.     

Characterization of lamprey fibrinopeptides

1. Lamprey fibrinopeptide B is a relatively large peptide made up of about 40 amino acid residues. The peptide is highly electronegative, containing a large number of aspartic acid residues and a tyrosine O-sulphate residue. 2. The amino acid sequence of the first 18 residues from the N-terminal end of fibrinopeptide B has been established. The C-terminal ends with the sequence Val-Arg. Fibrino-peptide B is released by both lamprey and bovine thrombins. 3. Lamprey fibrino-peptide A is a short peptide containing only eight residues. The proposed amino acid sequence is: Asp-Asp-Ser-Ile/Leu-Asp-Ser-Leu/Ile-ArgThis peptide is released by lamprey thrombin but not by bovine thrombin.     

High-resolution NMR studies of fibrinogen-like peptides in solution: interaction of thrombin with residues 1-23 of the A alpha chain of human fibrinogen

The interaction of the following human fibrinogen-like peptides with bovine thrombin was studied by use of one- and two-dimensional NMR techniques in aqueous solution: Ala(1)-Asp-Ser-Gly-Glu-Gly-Asp-Phe(8)-Leu-Ala-Glu-Gly-Gly-Gly-Val-Arg(16 )- Gly(17)-Pro-Arg(19)-Val(20)-Val-Glu-Arg (F10), residues 1-16 of F10 (fibrinopeptide A), residues 17-23 of F10 (F12), residues 1-20 of F10 (F13), residues 6-20 of F10 with Arg(16) replaced by a Gly residue (F14), and residues 6-19 of F10 with Arg(16) replaced by a Leu residue (F15). At pH 5.3 and 25 degrees C, the Arg(16)-Gly(17) peptide bonds of both peptides F10 and F13 were cleaved instantaneously in the presence of 0.6 mM thrombin, whereas the cleavage of the Arg(19)-Val(20) peptide bonds in peptides F12, F13, and F14 took over 1 h for completion. On the basis of observations of line broadening, fibrinopeptide A was found to bind to thrombin. While resonances from residues Ala(1)-Glu(5) were little affected, binding of fibrinopeptide A to thrombin caused significant line broadening of NH and side-chain proton resonances within residues Asp(7)-Arg(16). There is a chain reversal within residues Asp(7)-Arg(16) such that Phe(8) is brought close to the Arg(16)-Gly(17) peptide bond in the thrombin-peptide complex, as indicated by transferred NOEs between the aromatic ring protons of Phe(8) and the C alpha H protons of Gly(14) and the C gamma H protons of Val(15). A similar chain reversal was obtained in the isolated peptide F10 at a subzero temperature of -8 degrees C. The titration behavior of Asp(7) in peptide F13 does not deviate from that of the reference peptide, N-acetyl-Asp-NHMe at both 25 and -8 degrees C, indicating that no strong interaction exists between Asp(7) and Arg(16) or Arg(19). Peptides with Arg(16) replaced by Gly and Leu, respectively, i.e., F14 and F15, were also found to bind to thrombin but with a different conformation, as indicated by the absence of the long-range NOEs observed with fibrinopeptide A. Residues Asp(7)-Arg(16) constitute an essential structural element in the interaction of thrombin with fibrinogen.     

Mechanism of action of thrombin on fibrinogen. Reaction of the N-terminal CNBr fragment from the Aalpha chain of human fibrinogen with bovine thrombin

The 51-residue N-terminal cyanogen bromide fragment from the Aα chain of human fibrinogen was isolated, and the Michaelis-Menten constants, K_m and k_cat, for its hydrolysis by bovine thrombin were determined. The measured values of K_m and k_cat are 4.7 × 10^?5m and 4.8 × 10^?10m [(NIH U/liter) sec]^?1, respectively. Since these values are similar to those for fibrinogen, it appears that the N-terminal CNBr fragment contains all amino acid residues whose interactions with thrombin account for the high specificity of this enzyme for fibrinogen.     

On the activation of bovine plasma factor XIII. Amino acid sequence of the peptide released by thrombin and the terminal residues of the subunit polypeptides.

A blood coagulation factor, Factor XIII, was highly purified from bovine fresh plasma by a method similar to those used for human plasma Factor XIII. The isolated Factor XIII consisted of two subunit polypeptides, a and b chains, with molecular weights of 79,000 +/- 2,000 and 75,000 +/- 2,000, respectively. In the conversion of Factor XIII to the active enzyme, Factor XIIIa, by bovine thrombin [EC 3.4.21.5], a peptide was liberated. This peptide, designated tentatively as "activation peptide," was isolated by gel-filtration on a Sephadex G-75 column. It contained a total of 37 amino acid residues with a masked N-terminal residue and C-terminal arginine. The whole amino acid sequence of "Activation peptide" was established by the dansyl-Edman method and standard enzymatic techniques, and the masked N-terminal residue was identified as N-acetylserine by using a rat liver acylamino acid-releasing enzyme. This enzyme specifically cleaved the N-acetylserylglutamyl peptide bond serine and the remaining peptide, which was now reactive to 1-dimethylamino-naphthalene-5-sulfonyl chloride. A comparison of the sequences of human and bovine "Activation peptide" revealed five amino acids replacements, Ser-3 to Thr; Gly-5 to Arg; Ile-14 to Val; Thr-18 to Asn, and Pro-26 to Leu. Another difference was the deletion of Leu-34 in the human peptide. Adsorption chromatography on a hydroxylapatite column in the presence of 0.1% sodium dodecyl sulfate was developed as a preparative procedure for the resolution of the two subunit polypeptides, a or a' chain and b chain, constituting the protein molecule of Factor XIII or Factor XIIIa. End group analyses on the isolated pure chains revealed that the structural change of Factor XIII during activation with thrombin occurs only in the N-terminal portion of the a chain, not in the N-terminal end of the b chain or in the C-terminal ends of the a and b chains. From these results, it was concluded that the activation of bovine plasma Factor XIII by thrombin must be accompanied by a limited proteolysis of the arginyl-glycyl bond located in the N-terminal region of the a chain, liberating the "Activation peptide." The possibility of activating Factor XII with other porteinases was examined using Factor Xa [EC 3.4.21.6], Factor XIIa, kallikreins [EC 3.4.21.8], urokinase [EC 3.4.99.26], trypsin [EC 3.4.21.4], ficin [EC 3.4.22.3], papain [EC 3.4.22.2], and bromelain [EC 3.4.22.4]. Among these enzymes, only bromelain and trypsin showed clear activating effects.     

The structure and composition of cartilage keratan sulphate

Keratan sulphate was isolated from bovine intervertebral disc and bovine nasal septum after hydrolysis with proteinases and treatment with dilute alkali. Each preparation was found to contain, per keratan sulphate chain: (a) 1 residue of mannose; (b) 3 residues of N-acetylneuraminic acid (2 residues after alkali treatment); (c) 1 residue of N-acetylgalactosamine (lost after alkali treatment); (d) 1 residue or less of fucose. N-Acetyl-neuraminic acid residues were at non-reducing termini and were bonded to keratan sulphate through galactose residues. Evidence is presented for two different types of linkage between skeletal keratan sulphate and protein. Consideration of molecular parameters and compositions leads to a proposed structure for keratan sulphate-protein as found in skeletal proteoglycans.     

Mechanism of action of thrombin on fibrinogen: Reaction of the N-terminal CNBr fragment from the Bβ chain of bovine fibrinogen with bovine thrombin

The N-terminal cyanogen bromide fragment from the Bβ chain of bovine fibrinogen was isolated, and its molecular weight was estimated to be approximately 14,000–15,500. The ratio of the Michaelis-Menten constants, $\text{k}{}_{\mathrm{<mtext>cat</mtext>}}\text{K}{}_{\mathrm{m}}$, for its hydrolysis by bovine thrombin was found to be 3 × 10^?7 [(NIH unit/liter)s]^?1, indicating that the Bβ fragment is a poor substrate for thrombin compared to the corresponding Aα chain fragment. This value of $\text{k}{}_{\mathrm{<mtext>cat</mtext>}}\text{K}{}_{\mathrm{m}}$ is too small to account for the rate of release of fibrinopeptide B from fibrinogen by thrombin. It is suggested that, while the Aα chain contains all of the amino acid residues necessary to interact with thrombin, the Bβ chain does not; i.e., some of the binding sites that are used in the hydrolysis of the Bβ chain are assumed to be located on either the α or γ chains of fibrinogen. An alternative hypothesis is that, after the Bβ chain fragment is removed from the fibrinogen molecule, it does not have the proper conformation to be hydrolyzed by thrombin.     

Observations on the carbohydrate moiety of bovine pancreatic deoxyribonuclease A

The carbohydrate side chain of bovine pancreatic deoxyribonuclease A, which is attached to asparagine residue 18, contains two residues of N-acetylglucosamine proximal to the peptide chain followed by a variable number of mannose residues (4–10). The oligosaccharide structure bears a similarity to that in bovine pancreatic ribonuclease B. The present sequence studies have made use of α-mannosidase chromatographically purified from jack bean meal.     

Improved Procedures for the Purification of Selected Vitamin K-Dependent Proteins

Improved methods are described to obtain bovine prothrombin, Factor IX, Protein C, and autoprothrombin III (Factor X, Auto-III) in purified form. The prothrombin had a specific activity of 4, 340 Iowa units/mg. Theoretically, a preparation of clean thrombin should have a specific activity of 8, 200 U/mg, because 47.08% of the protein in prothrombin is lost when thrombin forms. Such thrombin preparations have been obtained (Arch. Biochem. Biophys. 121, 372 (1967)). The prothrombin concentration of bovine plasma is near 60 mg/liter. Protein C, first isolated by Stenflo (J. Biol. Chem. 251, 355 (1976)), was found to be the precursor of autoprothrombin II-A (Auto-II-A), discovered earlier (Thromb. Diath. Haemorrh. 5, 218 (1960)). Protein C (Factor XIV) was converted to Auto-II-A (Factor XlVa) by thrombin. Digesting purified Auto-III with purified thrombin removed a small glycopeptide from the COOH-terminal end of the heavy chain to yield Auto-IIItm. Auto-III throtnbin Auto-IIIm + peptide. Auto-IIIm was not converted to the active enzyme with thromboplastin and, furthermore, inhibited the activation of purified native Auto-III with thromboplastin. Auto-11 Im was also not converted to the active enzymewhen the procoagulants consisted of purified Factor VIII, purified Factor IXa, platelet factor 3 and calcium ions. The “activation peptide” released by RVV-X from the NH₂-terminal end of the heavy chain and the active enzyme (Auto-Cm) were purified. Auto-III was also activated with purified RVV-X. The same “activation peptide” was isolated, but Auto-C was obtained instead of Auto-Cm. Purified Factor IX developed anticoagulant activity when reacted with an optimum concentration of purified thrombin. A suitable reagent for the assay of Factor IX was prepared by removing prothrombin complex from anticoagulated bovine plasma and restoring the prothrombin and Auto-III concentration with use of the respective purified proenzymes.     

The co-crystal structure of unliganded bovine α-thrombin and prethrombin-2: Movement of the Tyr-Pro-Pro-Trp segment and active site residues upon ligand binding

Unliganded bovine α-thrombin and prethrombin-2 have been co-crystallized, in space group P2₁2₁2, using either ammonium sulfate or polyethylene glycol 2000 (PEG2K), and their structures determined at 2.2 Å and 2.3 Å, respectively. Initial phases were determined by molecular replacement and refined using XPLOR to final R factors of 0.187 (R_free = 0.255) and 0.190 (R_free = 0.282) for the salt and PEG2K models, respectively. The apo-enzyme form of bovine α-thrombin shows dramatic shifts in placement for the Tyr-Pro-Pro-Trp segment, for Glu-192, and for the catalytic residues His-57 and Ser-195, when compared to 4 thrombin complexes representing different states of catalysis, namely (1) the Michaelis complex (residues 7-19 of fibrinogen Aa with a non-cleavable scissile bond), (2) enzyme-inhibitor complex (D-Phe-Pro-Arg chloromethylketone), (3) enzyme product complex (residues 7-16 of fibrinopeptide A), and (4) the exosite complex (residues 53-64 of hirudin). The structures of bovine and human prethrombin-2 are generally similar to one another (RMS deviation of 0.68 8,) but differ significantly in the Arg-15/Ile-16 cleavage region and in the three activation domains, which are disordered in bovine prethrombin-2, analogous to that seen for trypsinogen.     

A peptide released from plasma fibrin stabilzing factor in the conversion to the active enzyme by thrombin

A peptide, which was released accompanying with the activation of bovine plasma fibrin stabilizing factor (FSF) by thrombin, was isolated and characterized. The peptide consisted of Asp4, Thr₃, Ser₄, Glu₄, Pro₅, Gly₄, Ala₄, Val₂, Ile₁, Leu₂, Phe₁, and Arg₃. The content of proline was highest in all of these amino acids. The carboxyl-terminal residue of the peptide was identified as arginine. However, no N-terminal amino acid reactive with phenyl$\text{iso}$thiocyanate and dansyl chloride could be determined. Edman degradation on the inactive FSF showed glutamic acid or glutamine as one N-terminal residue. After the activation of FSF by thrombin, glycine was identified as a second N-terminal residue, in addition to glutamic acid (glutamine).These results indicate that the transformation of FSF to the active enzyme by thrombin involves proteolysis of an arginyl-glycyl bond located in the N-terminal region of one of the subunits of the proenzyme.     

Two heads are better than one: crystal structure of the insect derived double domain Kazal inhibitor rhodniin in complex with thrombin.

Rhodniin is a highly specific inhibitor of thrombin isolated from the assassin bug Rhodnius prolixus. The 2.6 Angstrum crystal structure of the non-covalent complex between recombinant rhodniin and bovine alpha-thrombin reveals that the two Kazal-type domains of rhodniin bind to different sites of thrombin. The amino-terminal domain binds in a substrate-like manner to the narrow active-site cleft of thrombin; the imidazole group of the P1 His residue extends into the S1 pocket to form favourable hydrogen/ionic bonds with Asp189 at its bottom, and additionally with Glu192 at its entrance. The carboxy-terminal domain, whose distorted reactive-site loop cannot adopt the canonical conformation, docks to the fibrinogen recognition exosite via extensive electrostatic interactions. The rather acidic polypeptide linking the two domains is displaced from the thrombin surface, with none of its residues involved in direct salt bridges with thrombin. The tight (Ki = 2 x 10(-13) M) binding of rhodniin to thrombin is the result of the sum of steric and charge complementarity of the amino-terminal domain towards the active-site cleft, and of the electrostatic interactions between the carboxy-terminal domain and the exosite.     

Bovine factor VII. Its purification and complete amino acid sequence

A modified method for purification of blood clotting factor VII from bovine plasma was developed, and its complete amino acid sequence was established. The isolated factor VII was activated with factor XIIa, and the resulting two-chain factor VII (factor VIIa) was reduced and S-pyridylethylated or S-aminoethylated. The amino acid sequences of the S-alkylated heavy and light chains were determined by sequencing the fragments obtained from enzymatic and chemical cleavages. Fast atom bombardment mass spectrometry was also used to establish the COOH-terminal sequence of the heavy chain. The light chain consists of 152 residues with one carbohydrate chain at Asn145, and 11 gamma-carboxyglutamic acid residues are found within the NH2-terminal 35 residues. The light chain contains 0.2-0.3 mol of beta-hydroxyaspartic acid/mol of protein, indicating that an aspartic acid residue in bovine factor VII is incompletely hydroxylated. Moreover, a pentapeptide, Ala-Ser*-Ser-Pro-Cys (positions 51-55), isolated from an enzymatic digest of the light chain, contained an unknown serine derivative, but its structure is still unclear. On the other hand, the heavy chain is composed of 255 residues and one asparagine-linked carbohydrate chain at Asn203. Bovine factor VII, with a total of 407 residues, has 71% sequence identity with the human molecule (406 residues) predicted from the cDNA sequence (Hagen, F. S., Gray, C. L., O'Hara, P., Grant, F. J., Saari, G. C., Woodbury, R. G., Hart, C. E., Insley, M., Kisiel, W., Kurachi, K., and Davie, E. W. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 2412-2416).     

Genetic variants of bovine beta-lactoglobulin. A novel wild-type beta-lactoglobulin W and its primary sequence

A novel bovine beta-lactoglobulin W has been isolated and its complete primary structure is presented. It was isolated by chromatofocusing of a beta-lactoglobulin AW heterozygote and purified by recrystallization. During sequencing of the oxidized protein, it became evident that the new beta-lactoglobulin W is a subtype of variant B with a single difference at position 56. This Ile----Leu substitution, which means a shift of a methyl group from C-beta to C-gamma of the amino-acid side chain causes a change of pI of 0.007 units, which can be detected by high resolution electrophoresis. This Ile56 amino-acid residue is among the most conserved residues with the exception of kangaroo beta-LG. The structures of other bovine beta-lactoglobulins and their relationships are discussed.     

Primary structure of human fibrinogen and fibrin. Structural studies on NH2-terminal part of B beta chain.

The cyanogen bromide fragment, N-DSK, containing the NH2-terminal portions of the three chains of fibrinogen, was found to exist in dimeric and polymeric forms. These different forms gave rise to identical chain fragments on reduction and alkylation. The B beta chain of N-DSK from fibrinogen and the beta chain of N-DSK from fibrin were isolated and characterized. The B beta chain fragment has a blocked NH2-terminal residue, and fibrinopeptide B is released on digestion with thrombin. The beta chain fragment has glycine as NH2-terminal residue. The molecular weight of the B beta chain fragment is 12200 as determined by ultracentrifugal analysis. Gel electrophoresis in sodium dodecyl sulphate gave the molecular weights of 14000 and 13000 for the B beta chain and beta chain fragments, respectively. The NH2-terminal B beta chain fragment consists of 118 amino acid residues and the beta chain fragment of 104 residues. The amino acid sequence of beta chain fragment is identical to B beta chain fragment except for the fibrinopeptide B portion. The isolation of a B beta-related fragment (B beta +), with a molecular weight of 30000, is also reported. The presence of B beta + was explained on the basis of incomplete cleavage at the Met-118 residue during treatment with cyanogen bromide. Some functional aspects of the B beta chain fragment are discussed.     

The structure of residues 7-16 of the A alpha-chain of human fibrinogen bound to bovine thrombin at 2.3-A resolution.

The tetradecapeptide Ac-D-F-L-A-E-G-G-G-V-R-G-P-R-V-OMe, which mimics residues 7f-20f of the A alpha-chain of human fibrinogen, has been co-crystallized with bovine thrombin from ammonium sulfate solutions in space group P2(1) with unit cell dimensions of a = 83.0 A, b = 89.4 A, c = 99.3 A, and beta = 106.6 degrees. Three crystallographically independent complexes were located in the asymmetric unit by molecular replacement using the native bovine thrombin structure as a model. The standard crystallographic R-factor is 0.167 at 2.3-A resolution. Excellent electron density could be traced for the decapeptide, beginning with Asp-7f and ending with Arg-16f in the active site of thrombin; the remaining 4 residues, which have been cleaved from the tetradecapeptide at the Arg-16f/Gly-17f bond, are not seen. Residues 7f-11f at the NH2 terminus of the peptide form a single turn of alpha-helix that is connected by Gly-12f, which has a positive phi angle, to an extended chain containing residues 13f-16f. The major specific interactions between the peptide and thrombin are 1) a hydrophobic cage formed by residues Tyr-60A, Trp-60D, Leu-99, Ile-174, Trp-215, Leu-9f, Gly-13f, and Val-15f that surrounds Phe-8f; 2) a hydrogen bond linking Phe-8f NH to Lys-97 O;3) a salt link between Glu-11f and Arg-173; 4) two antiparallel beta-sheet hydrogen bonds between Gly-14f and Gly-216; and 5) the insertion of Arg-16f into the specificity pocket. Binding of the peptide is accompanied by a considerable shift in two of the loops near the active site relative to human D-phenyl-L-prolyl-L-arginyl chloromethyl ketone (PPACK)-thrombin.     

Amino acid sequence around the serine phosphorylated by casein kinase II in brain myosin heavy chain

Casein kinase II from bovine brain transfers about one mole of phosphate to a serine residue near the COOH terminus of the heavy chain of myosin isolated from bovine brain. We have purified and characterized a peptide that contains this phosphoserine. The peptide was generated by chymotryptic and thermolytic digestion and was isolated by gel filtration, Fe3+ affinity chromatography, and reverse-phase high pressure liquid chromatography. Its sequence, Leu-Glu-Leu-Ser(PO4)-Asp-Asp-Asp-Asp-Glu-Ser-Lys-Ala-Ser-(Xaa)-Ile-Asn-Glu-Thr- Gln-Pro-Pro-Gln, shows that the Ser(PO4) is in an acidic environment, as is typical for casein kinase II phosphorylation sites. The "hydrophobic repeat" typical of alpha-helical coiled-coils is absent, suggesting that the sequence is part of a non-helical "tail piece" of the heavy chain. A synthetic peptide corresponding to residues 1-9 is shown to be an effective substrate for casein kinase II.     

Crystal structure of thrombin-ecotin reveals conformational changes and extended interactions

The protease inhibitor ecotin fails to inhibit thrombin despite its broad specificity against serine proteases. A point mutation (M84R) in ecotin results in a 1.5 nM affinity for thrombin, 10(4) times stronger than that of wild-type ecotin. The crystal structure of bovine thrombin is determined in complex with ecotin M84R mutant at 2.5 A resolution. Surface loops surrounding the active site cleft of thrombin have undergone significant structural changes to permit inhibitor binding. Particularly, the insertion loops at residues 60 and 148 in thrombin, which likely mediate the interactions with macromolecules, are displaced when the complex forms. Thrombin and ecotin M84R interact in two distinct surfaces. The loop at residue 99 and the C-terminus of thrombin contact ecotin through mixed polar and nonpolar interactions. The active site of thrombin is filled with eight consecutive amino acids of ecotin and demonstrates thrombin's preference for specific features that are compatible with the thrombin cleavage site: negatively charged-Pro-Val-X-Pro-Arg-hydrophobic-positively charged (P1 Arg is in bold letters). The preference for a Val at P4 is clearly defined. The insertion at residue 60 may further affect substrate binding by moving its adjacent loops that are part of the substrate recognition sites.     

Rat prothrombin: Purification,characterization, and activation

Prothrombin has been purified from rat plasma and its properties compared to prothrombin isolated from other species. The molecular weight, amino acid composition, and amino-terminal sequence of rat prothrombin are similar to human and bovine prothrombin. Rat prothrombin binds to phospholipid in the presence of calcium ions, and calcium-binding measurements indicate that it may bind somewhat more calcium than does bovine prothrombin. The proteolytic cleavage of purified rat prothrombin by Factor X_a or thrombin yields the same peptides that are formed from similar proteolysis of bovine prothrombin. Factor V and phospholipid were shown to enhance the rate of Factor X_a and calcium ion generation of thrombin from rat prothrombin.