Primary structure of bovine alpha 2-antiplasmin

Molecular cloning and functional expression of rabbit alpha2-antiplasmin

The rabbit is frequently employed in small animal models of in-vivo coagulation and fibrinolysis, but the degree to which its plasma proteins resemble their human counterparts is incompletely known. Our aims were: to determine the nucleotide sequence of a full-length rabbit liver alpha(2)-antiplasmin (alpha(2)AP) cDNA; compare it with its human, murine, and bovine counterparts; and express it in functional form. Partial cDNAs encoding 5' and 3' portions of the alpha(2)AP mRNA were obtained by reverse transcriptase (RT)-polymerase chain reaction (PCR), using rabbit liver RNA and 'guessmer' oligonucleotides based on known sequences. This information was employed to design additional oligonucleotides for RT-PCR and rapid amplification of cDNA ends (RACE) procedures yielding overlapping clones corresponding to the entire rabbit alpha(2)AP mRNA sequence. Mature alpha(2)AP was expressed as a hexahistidine-tagged recombinant protein in Escherichia coli, purified by nickel-chelate affinity and ion exchange chromatography, and its reaction with plasmin and soluble fibrin assessed electrophoretically and compared with an analogous recombinant human alpha(2)AP. The consensus rabbit alpha(2)AP cDNA is 2,157 bp long, and encodes a 464-residue mature sequence and a 27-amino-acid presequence. The mature protein is 82% identical to its human counterpart, and its recombinant form produced denaturation-resistant complexes with both plasmin and fibrin. The region of greatest sequence divergence lies within the C-terminal extension of alpha(2)AP, unique in the serpin family of proteins to which alpha(2)AP belongs. The highly conserved nature of rabbit alpha(2)AP reinforces its role as a vital antifibrinolytic protein and supports fibrinolytic investigations in models employing this small animal.

Structural/functional characterization of the alpha 2-plasmin inhibitor C-terminal peptide

The alpha(2)-plasmin inhibitor (A2PI) is a main physiological regulator of the trypsin-like serine proteinase plasmin. It is composed of an N-terminal 15 amino acid fibrin cross-linking polypeptide, a 382-residue serpin domain, and a flexible C-terminal segment. The latter, peptide Asn(398)-Lys(452), and its Lys452Ala mutant were expressed as recombinant proteins in Escherichia coli (r-A2PIC and r-A2PICmut, respectively). CD and NMR analyses indicate that r-A2PIC is flexible, loosely folded, and with low content of regular secondary structure. Functional characterization via intrinsic fluorescence ligand titrations shows that r-A2PIC interacts with the isolated plasminogen kringle 1 (r-K1) (K(a) approximately 69.9 mM(-)(1)), K4 (K(a) approximately 45.7 mM(-)(1)), K5 (K(a) approximately 4.3 mM(-)(1)), and r-K2 (K(a) approximately 3.2 mM(-)(1)), all of which are known to exhibit lysine-binding capability. The affinities of these kringles for r-A2PIC are consistently larger than those reported for the ligand N(alpha)-acetyllysine, a mimic of a C-terminal Lys residue. The r-A2PICmut, with a C-terminal Ala residue, also interacts with r-K1 and K4, although with approximately 5-fold lesser affinities relative to r-A2PIC, demonstrating that while Lys(452) plays a major role in the binding, internal residues in r-A2PIC tether the kringles. (1)H NMR spectroscopy shows that key aromatic residues within the K4 lysine-binding site (LBS), namely, Trp(25), Trp(62), Phe(64), Trp(72), and Tyr(74), selectively respond to the addition of r-A2PIC and r-A2PICmut, indicating that these interactions proceed via the kringles' canonical LBS. We conclude that r-A2PIC docks to kringles primarily through lysine side chains and that Lys(452) most definitely enhances the binding. This suggests that multiple Lys residues within A2PI could contribute, perhaps in a zipper-like fashion, to its binding to the in-tandem, multikringle array that configures the plasmin heavy chain.

Purification and partial characterisation of alpha(2)-antiplasmin and plasmin(ogen) from ostrich plasma

This study reports the isolation and partial characterisation of the ostrich serpin, alpha(2)AP, and its target enzyme, ostrich plasmin, in its active and inactive proenzyme, namely plasminogen, forms. Ostrich alpha(2)AP was purified using L-lysine-Sepharose chromatography, ammonium sulfate fractionation, and Super Q-650S and ostrich LBSI-Sepharose chromatographies. It revealed a M(r) of 84 K (thousand) and had one and two N-terminal amino acids in common with 11 of those of human and bovine alpha(2)AP, respectively. It showed the largest inhibitory effect on ostrich plasmin, followed by bovine trypsin and plasmin, respectively, and much less plasmin inhibition than bovine aprotinin, but much more so than human alpha(2)AP, DFP and EACA. Ostrich plasminogen was highly purified after L-lysine-Sepharose chromatography and showed a M(r) of 92 K, a total of 775 amino acids and its N-terminal sequence showed approximately 53% identity with those of human, rabbit, cat, and ox plasminogens. Ostrich plasmin, obtained by the urokinase-activation of ostrich plasminogen, revealed a M(r) of 78 K, a total of 638 amino acids, an N-terminal sequence showing two to four residues identical to five of those of human, cat, dog, rabbit, and ox plasmins, and pH and temperature optima of 8.0 and 40 degrees C, respectively.

Inhibitory activity against plasmin, trypsin, and elastase in rennet whey and in cheese fortified with whey protein

The inhibitory activity against trypsin, elastase, and plasmin was determined in samples of Danbo 45+ that were manufactured from milk pasteurized at 72, 80, and 90 degrees C for 15, 30 and 60 s; the corresponding rennet wheys; and Havarti 45+ manufactured from milk concentrated 1.8-fold, 2.7-fold, and 4.6-fold by ultrafiltration. A sensitive colorimetric assay demonstrated that the incorporation of thermally denatured whey proteins into the cheese curd by pasteurization resulted in a decreased proteinase inhibitory activity against trypsin and elastase in Danbo 45+ and against trypsin, elastase, and plasmin in the corresponding rennet wheys. However, incorporation of native whey proteins into Havarti 45+ by ultrafiltration of the cheese milk resulted in an increased inhibitory activity against trypsin and elastase in the cheeses. Cheese manufactured from milk concentrated 1.8-fold, 2.7-fold, or 4.6-fold displayed trypsin inhibitory activity that was 1.8, 2.9, and 5.1 times, respectively, that of the reference cheese. Similarly, the elastase inhibitory activity in the cheeses increased 2.2, 3.2 and 7.8 times. The increased inhibitory activity in cheese fortified with native whey protein likely contributes to the decreased proteolysis and altered ripening characteristics of the resulting cheeses, and further, the method can be adapted to detection of other inhibitors if sufficiently sensitive substrates are available.

Assignment of a single disulphide bridge in human alpha2-antiplasmin: implications for the structural and functional properties

Human alpha2-antiplasmin (alpha2AP) is a serpin involved in the regulation of blood coagulation. Most serpins, unlike smaller serine proteinase inhibitors, do not contain disulphide bridges. alpha2AP is an exception from this generalization and has previously been shown to contain four Cys residues organized into two disulphide bridges [Lijnen, Holmes, van Hoef, Wiman, Rodriguez and Collen (1987) Eur. J. Biochem. 166, 565-574]. However, we found that alpha2AP incorporates iodo[14C]acetic acid, suggesting that the protein contains reactive thiol groups. This observation prompted a re-examination of the state of the thiol groups, which revealed (i) a disulphide bridge between Cys43 and Cys116, (ii) that Cys76 is bound to a cysteinyl-glycine dipeptide, and (iii) and Cys125 exists as either a free thiol or in a mixed disulphide with another Cys residue. The disulphide identified between Cys43 and Cys116 appears to be conserved in orthologous proteins since the homologous Cys residues form disulphide bonds in bovine and possibly mouse alpha2AP. The conservation of this disulphide bridge suggests that it is important for functional aspects of alpha2AP. However, the structural and functional analysis described in this study does not support this conclusion.

Reaction of human alpha2-antiplasmin and plasmin stopped-flow fluorescence kinetics

The interaction of human plasmin with human alpha2-antiplasmin was measured in the presence and absence of lysine-binding ligands using the corresponding active site fluorescence changes. The stopped-flow method allows for direct determination of reliable values of the second order rate constant for the fast association step of plasmin and alpha2-antiplasmin in the absence of another interacting compound, e.g. a plasmin substrate. At pH 7.4, 25 degrees C, k1 = 2.2 x 10(7) M(-1)s(-1) was obtained. Substantial reductions in k1 were seen in the presence of trans-4-(aminomethyl)cyclohexane-1-carboxylic acid at concentrations corresponding to lysine-binding site interactions at kringle 4 of plasmin; at saturation the rate constant is reduced 20-fold, whereas the effect of saturation of kringle 1 is only a 2-fold reduction. It is thus found that the interaction of alpha2-antiplasmin with the lysine-binding site of kringle 1 is of little importance compared with that of kringle 4 in regulating the inhibition reaction of plasmin with alpha2-antiplasmin. Similar results were recently obtained for the bovine plasmin-bovine alpha2-antiplasmin reaction (Christensen et al. (1995) Biochem. J. 305, 97-102).