The role of the insertion loop around tryptophan 148 in tthe activity of thrombin.
Research article published in Biochemistry (1996)
Abstract
Thrombin has trypsin-like specificity for Arg-Xaa and Lys-Xaa peptide bonds; however, it is much more specific than trypsin, cleaving far fewer peptide bonds in macromolecular substrates. To probe the nature of the specificity of thrombin, a mutant has been constructed in which the Trp148 loop of thrombin has been replaced with the same loop of bovine trypsin. This mutant was expressed in Escherichia coli as prethrombin-2(148) using a T7 expression system previously described for wild-type prethrombin-2 [DiBella et al. (1995) J. Biol. Chem. 270, 163-169]. After refolding and purification, prethrombin-2(148) was activated to thrombin(148) with Echis carinatus snake venom. The k(cat)/K(m) for the release of fibrinopeptide A from fibrinogen was 4.5 +/- 0.5 microM(-1)s(-1) for thrombin(148), which was approximately 20% of that of recombinant thrombin (25 +/- 2.0 microM(-1)s(-1)). Thrombin(148) was inhibited less well by hirudin with a K(i) of 500 pM compared to a value of 12 pM determined for recombinant thrombin. The mutant thrombin was also compared to trypsin and wild-type recombinant thrombin for the ability to cleave small peptide substrates. The Michaelis constants (K(m)) were found to be between 5- and 10-fold higher for thrombin(148) relative to wild-type recombinant thrombin, although the catalytic constants (k(cat)) for thrombin(148) and recombinant thrombin remained relatively unchanged for all three substrates. Thrombin(148) had a specificity constant (k(cat)/K(m)) 2-fold higher for the hydrolysis of H-D-phenyalanyl-L- pipecolyl-L-arginine-p-nitroaniline (a thrombin substrate) than that of trypsin. For N-benzoyl-L-isoleucyl-L-glutamylglycyl-L-arginine- p-nitroaniline (a trypsin substrate) and N-carbobenzoxyglycylprolyl-L-arginine-p-nitroaniline (a substrate for both enzymes), the specificity constants for trypsin were 1000- and 16-fold higher, respectively. Although replacement of the Trp(148) loop does not yield an enzyme with more trypsin-like specificity, the Trp(148) loop is important in the substrate binding and specificity of thrombin (on the basis of K(m) and K(i)).
Abstract sourced from PubMed (NCBI) for the cited record. See the original publication for the authoritative version.
Summary
Thrombin has trypsin-like specificity for Arg-Xaa and Lys-Xaa peptide bonds; however, it is much more specific than trypsin, cleaving far fewer peptide bonds in macromolecular substrates. To probe the nature of the specificity of thrombin, a mutant has been constructed in which the Trp148 loop of...
Why This Matters for Hirudotherapy
DiBella et al. (1996, Biochemistry) probed thrombin's substrate specificity by engineering a mutant in which thrombin's Trp148 insertion loop was replaced with the corresponding loop of bovine trypsin; the mutant retained thrombin-like specificity overall but showed altered kinetics, and notably was inhibited far less well by hirudin (Ki ~500 pM) than recombinant thrombin (Ki ~12 pM), implicating the Trp148 loop in substrate binding and specificity. For ASH this is foundational biochemistry behind the leech anticoagulant story: hirudin, the medicinal leech's signature thrombin inhibitor, is used here as a molecular probe, and the sharp loss of inhibition with the loop swap helps map how hirudin recognizes and blocks thrombin — the basis of leech-derived anticoagulation. Honest caveat: this is an in-vitro enzymology/protein-engineering study using recombinant proteins, not a clinical or even animal investigation of hirudotherapy, and the hirudin data are a mechanistic readout rather than evidence of therapeutic effect.
Citation
The role of the insertion loop around tryptophan 148 in tthe activity of thrombin.
DiBella et al. · Biochemistry, 1996
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