Abstract
The binding of heparin to antithrombin greatly accelerates the rate of inhibition of the target proteinases thrombin and factor Xa. Acceleration of the rate of inhibition of factor Xa involves a conformational change in antithrombin that is translated from the heparin binding site to the reactive center loop. A mechanism has been proposed for generation and propagation of the conformational change in which the binding of the negatively charged heparin reduces ionic repulsions between positively charged residues on and adjacent to the D-helix in the heparin binding site of antithrombin (van Boeckel, C. A. A., Grootenhuis, P. D. J., and Visser, A. (1994) Nature Struct. Biol. 1, 423-425). This charge neutralization is proposed to elongate the D-helix and initiate the conformational change which is then translated to the reactive center loop. Several basic residues, including arginine 132 and lysine 133, were predicted to be important both in heparin binding and in this mechanism of heparin activation. To test both the helix extension mechanism and the role of these two residues in heparin binding and factor Xa inhibition, we individually changed arginine 132 and lysine 133 to uncharged methionine by site-directed mutagenesis. The Kd values for binding of R132M and K133M variants to the high affinity pentasaccharide were weakened only 2.3- and 4.5-fold respectively, suggesting a location for R132 and K133 peripheral to the main pentasaccharide binding site. However, the Kd values for long chain high affinity heparin were weakened at least 17-fold for both R132M and K133M, indicating involvement of each residue in binding extended chain heparin species. These reductions in affinity were ionic strength-dependent. The rates of inhibition of factor Xa and thrombin by each variant, however, were indistinguishable from those of control antithrombin, and the accelerations of the rate of inhibition produced by heparin were normal. We conclude that neither arginine 132 nor lysine 133 plays an important role in the binding of heparin pentasaccharide or in the mechanism of heparin activation, suggesting that D-helix extension through charge neutralization is not the mechanism for transmission of conformational change from the heparin binding site to the reactive center region. Arginine 132 and lysine 133 do, however, play a role in tight binding of longer chain heparin species through ionic interactions.
Highlights
Antithrombin is a member of the serpin1 superfamily and is the principal inhibitor of thrombin and factor Xa, serine proteinases involved in the blood coagulation cascade
Van Boeckel and colleagues have proposed a mechanism for heparin activation of antithrombin in which the binding of heparin stabilizes and elongates the D-helix in the heparin binding site by reducing ionic repulsion between the positively charged lysine and arginine residues located on the same face of the D-helix and on the adjacent, less structured stretch of polypeptide
The elongation of the D-helix translates the conformational change to the reactive center as a result of the newly extended helix being attached to a strand of -sheet A, resulting in expulsion of the P15 and P14 residues of the reactive center loop from -sheet A [13] (Fig. 1)
Summary
Antithrombin is a member of the serpin superfamily and is the principal inhibitor of thrombin and factor Xa, serine proteinases involved in the blood coagulation cascade. The elongation of the D-helix translates the conformational change to the reactive center as a result of the newly extended helix being attached to a strand of -sheet A, resulting in expulsion of the P15 and P14 residues of the reactive center loop from -sheet A [13] (Fig. 1) From molecular modeling, these authors implicated eight basic residues as critical for heparin pentasaccharide binding and transmission of the conformational change, including arginine 132 and lysine 133. Normal rates were seen for inhibition of factor Xa, both in the absence and presence of pentasaccharide or full-length high affinity heparin, suggesting that these residues are not involved in the mechanism of activation of antithrombin and that D-helix extension through charge neutralization is unlikely to be the means of transmission of conformational change from the heparin binding site to the reactive center. The rate of inhibition of thrombin in the presence of full-length heparin was normal, implying that the bridging mechanism does not depend on either of these charged residues
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