Tissue Factor Residues That Modulate Magnesium-Dependent Rate Enhancements of the Tissue Factor/Factor VIIa Complex.

The blood coagulation cascade is initiated when the cell-surface complex of factor VIIa (FVIIa, a trypsin-like serine protease) and tissue factor (TF, an integral membrane protein) proteolytically activates factor X (FX). Both FVIIa and FX bind to membranes via their γ-carboxyglutamate-rich domains (GLA domains). GLA domains contain seven to nine bound Ca(2+) ions that are critical for their folding and function, and most biochemical studies of blood clotting have employed supraphysiologic Ca(2+) concentrations to ensure saturation of these domains with bound Ca(2+). Recently, it has become clear that, at plasma concentrations of metal ions, Mg(2+) actually occupies two or three of the divalent metal ion-binding sites in GLA domains, and that these bound Mg(2+) ions are required for full function of these clotting proteins. In this study, we investigated how Mg(2+) influences FVIIa enzymatic activity. We found that the presence of TF was required for Mg(2+) to enhance the rate of FX activation by FVIIa, and we used alanine-scanning mutagenesis to identify TF residues important for mediating this response to Mg(2+). Several TF mutations, including those at residues G164, K166, and Y185, blunted the ability of Mg(2+) to enhance the activity of the TF/FVIIa complex. Our results suggest that these TF residues interact with the GLA domain of FX in a Mg(2+)-dependent manner (although effects of Mg(2+) on the FVIIa GLA domain cannot be ruled out). Notably, these TF residues are located within or immediately adjacent to the putative substrate-binding exosite of TF.

High-Resolution NMR Studies of Human Tissue Factor.

In normal hemostasis, the blood clotting cascade is initiated when factor VIIa (fVIIa, other clotting factors are named similarly) binds to the integral membrane protein, human tissue factor (TF). The TF/fVIIa complex in turn activates fX and fIX, eventually concluding with clot formation. Several X-ray crystal structures of the soluble extracellular domain of TF (sTF) exist; however, these structures are missing electron density in functionally relevant regions of the protein. In this context, NMR can provide complementary structural information as well as dynamic insights into enzyme activity. The resolution and sensitivity for NMR studies are greatly enhanced by the ability to prepare multiple milligrams of protein with various isotopic labeling patterns. Here, we demonstrate high-yield production of several isotopically labeled forms of recombinant sTF, allowing for high-resolution NMR studies both in the solid and solution state. We also report solution NMR spectra at sub-mM concentrations of sTF, ensuring the presence of dispersed monomer, as well as the first solid-state NMR spectra of sTF. Our improved sample preparation and precipitation conditions have enabled the acquisition of multidimensional NMR data sets for TF chemical shift assignment and provide a benchmark for TF structure elucidation.

Experimental Protein Structure Verification by Scoring with a Single, Unassigned NMR Spectrum.

Standard methods for de novo protein structure determination by nuclear magnetic resonance (NMR) require time-consuming data collection and interpretation efforts. Here we present a qualitatively distinct and novel approach, called Comparative, Objective Measurement of Protein Architectures by Scoring Shifts (COMPASS), which identifies the best structures from a set of structural models by numerical comparison with a single, unassigned 2D (13)C-(13)C NMR spectrum containing backbone and side-chain aliphatic signals. COMPASS does not require resonance assignments. It is particularly well suited for interpretation of magic-angle spinning solid-state NMR spectra, but also applicable to solution NMR spectra. We demonstrate COMPASS with experimental data from four proteins--GB1, ubiquitin, DsbA, and the extracellular domain of human tissue factor--and with reconstructed spectra from 11 additional proteins. For all these proteins, with molecular mass up to 25 kDa, COMPASS distinguished the correct fold, most often within 1.5 Å root-mean-square deviation of the reference structure.

Backbone resonance assignments of the C2 domain of coagulation factor VIII.

Factor VIII (FVIII, other clotting factors are named similarly) is a glycoprotein that circulates in the plasma bound to von Willebrand factor. During the blood coagulation cascade, activated FVIII (FVIIIa) binds to FIXa and activates FX in the presence of calcium ions and phospholipid membranes. The C1 and C2 domains mediate membrane binding that is essential for activation of the FVIIIa-FIXa complex. Here, (1)H, (13)C, and (15)N backbone chemical shift assignments are reported for the C2 domain of FVIII, including assignments for the residues in solvent-exposed loops. The NMR resonance assignments, along with further structural studies of membrane-bound FVIII, will advance understanding of blood-clotting protein interactions.