Identification of coagulation factor VIII A2 domain residues forming the binding epitope for low-density lipoprotein receptor-related protein

Regulation of the coagulation factor VIII (fVIII) level in circulation involves a hepatic receptor low-density lipoprotein receptor-related protein (LRP). One of two major LRP binding sites in fVIII is located within the A2 domain (A2), likely exposed within the fVIII complex with von Willebrand factor and contributing to regulation of fVIII via LRP. This work aimed to identify A2 residues forming its LRP-binding site, previously shown to involve residues 484-509. Isolated A2 was subjected to alanine-scanning mutagenesis followed by expression of a set of mutants in a baculovirus system. In competition and surface plasmon resonance assays, affinities of A2 mutants K466A, R471A, R484A, S488A, R489A, R490A, H497A, and K499A for LRP were found to be decreased by 2-4-fold. This correlated with 1.3-1.5-fold decreases in the degree of LRP-mediated internalization of the mutants in cell culture. Combining these mutations into pairs led to cumulative effects, i.e., 7-13-fold decrease in affinity for LRP and 1.6-2.2-fold decrease in the degree of LRP-mediated internalization in cell culture. We conclude that the residues mentioned above play a key role in formation of the A2 binding epitope for LRP. Experiments in mice revealed an approximately 4.5 times shorter half-life for A2 in the circulation in comparison with that of fVIII. The half-lives of A2 mutant R471A/R484A or A2 co-injected with receptor-associated protein, a classical ligand of LRP, were prolonged by approximately 1.9 and approximately 3.5 times, respectively, compared to that of A2. This further confirms the importance of the mutated residues for interaction of A2 with LRP and suggests the existence of an LRP-dependent mechanism for removing A2 as a product of dissociation of activated fVIII from the circulation.     

On the mechanism of αC polymer formation in fibrin

Our previous studies revealed that the fibrinogen αC-domains undergo conformational changes and adopt a physiologically active conformation upon their self-association into αC polymers in fibrin. In the present study, we analyzed the mechanism of αC polymer formation and tested our hypothesis that self-association of the αC-domains occurs through the interaction between their N-terminal subdomains and may include β-hairpin swapping. Our binding experiments performed by size-exclusion chromatography and optical trap-based force spectroscopy revealed that the αC-domains self-associate exclusively through their N-terminal subdomains, while their C-terminal subdomains were found to interact with the αC-connectors that tether the αC-domains to the bulk of the molecule. This interaction should reinforce the structure of αC polymers and provide the proper orientation of their reactive residues for efficient cross-linking by factor XIIIa. Molecular modeling of self-association of the N-terminal subdomains confirmed that the hypothesized β-hairpin swapping does not impose any steric hindrance. To "freeze" the conformation of the N-terminal subdomain and prevent the hypothesized β-hairpin swapping, we introduced by site-directed mutagenesis an extra disulfide bond between two β-hairpins of the bovine Aα406-483 fragment corresponding to this subdomain. The experiments performed by circular dichroism revealed that Aα406-483 mutant containing Lys429Cys/Thr463Cys mutations preserved its β-sheet structure. However, in contrast to wild-type Aα406-483, this mutant had lower tendency for oligomerization, and its structure was not stabilized upon oligomerization, in agreement with the above hypothesis. On the basis of the results obtained and our previous findings, we propose a model of fibrin αC polymer structure and molecular mechanism of assembly.     

Interaction of fibrin(ogen) with apolipoprotein(a): further characterization and identification of a novel lysine-dependent apolipoprotein(a)-binding site within the gamma chain 287-411 region

Interaction of lipoprotein(a) with fibrin associated with atherosclerotic lesions promotes its accumulation in the lesions, thereby contributing to the development of atherothrombosis. Numerous studies revealed that this interaction occurs through the apolipoprotein(a) [apo(a)] component of lipoprotein(a) and COOH-terminal Lys residues generated by partial degradation of fibrin with plasmin (a COOH-Lys-dependent mechanism). At the same time, the mechanism of the interaction of apo(a) with intact fibrin(ogen) remained unclear. Our recent study identified the Lys-independent apo(a)-binding sites within the fibrin(ogen) alphaC domains which contribute to an alternative Lys-independent mechanism. In this study, we performed direct measurements of the interaction between apo(a) and various fibrin(ogen) fragments representing the whole fibrin(ogen) molecule except the alphaC regions. The experiments revealed that the apo(a)-binding site, identified previously within fibrinogen gamma chain residues 207-235 [Klose, R., et al. (2000) J. Biol. Chem. 275, 38206-38212], is a high-affinity site and mainly Lys-independent, suggesting that it should also contribute to the Lys-independent mechanism. The experiments also identified a novel Lys-dependent high-affinity apo(a)-binding site within the sequence of gamma chain residues 287-411. This site may provide interaction of apo(a) with intact fibrin(ogen) through another alternative mechanism, which depends on internal Lys residues. Thus, apo(a) may interact with intact fibrin through the Lys-independent and Lys-dependent mechanisms, while the COOH-Lys-dependent mechanism may prevail in the presence of fibrinolytic activity.     

Structural basis for sequential cleavage of fibrinopeptides upon fibrin assembly

Nonsubstrate interaction of thrombin with fibrinogen promotes sequential cleavage of fibrinopeptides A and B (fpA and fpB, respectively) from the latter, resulting in its conversion into fibrin. The recently established crystal structure of human thrombin in complex with the central part of human fibrin clarified the mechanism of this interaction. Here, we reveal new details of the structure and present the results of molecular modeling of the fpA- and fpB-containing portions of the Aalpha and Bbeta chains, not identified in the complex, in both fibrinogen and protofibrils. The analysis of the results reveals that in fibrinogen the fpA-containing portions are in a more favorable position to bind in the active site cleft of bound thrombin. Surface plasmon resonance experiments establish that the fpB-containing portions interact with the fibrin-derived dimeric D-D fragment, suggesting that in protofibrils they bind to the newly formed DD regions bringing fpB into the vicinity of bound thrombin. These findings provide a coherent rationale for the preferential removal of fpA from fibrinogen at the first stage of fibrin assembly and the accelerated cleavage of fpB from protofibrils and/or fibrils at the second stage.     

Database for three dimensional structures of pepsin-like enzymes using the internal coordinate system

A database for 3D structures of pepsin-like enzymes has been created on the basis of a novel approach using the Internal Coordinate System (ICS). It allows rapid comparison of multiple structures of pepsin-like enzymes without the need for preliminary calculations. Atomic displacements measured by this approach are very close to those estimated by the superposition procedures widely employed in comparing three-dimensional structures of proteins. Any new structure of pepsin-like enzyme converted to the ICS automatically becomes superimposed with all structures in a database. The ICS approach can be used for any class of enzymes and is especially efficient for families containing a large number of homologous structures.     

Crystallization and preliminary X-ray diffraction data of two heparin-binding fragments of human fibronectin

Two different heparin-binding fragments of human fibronectin have been crystallized in forms which are suitable for crystal structure analyses. The 30 kDa hep-2A fragment, consisting of type III domains 12–14, was crystallized from solutions containing ammonium sulfate or polyethylene glycol 6000. The crystals grown in ammonium sulfate solutions were orthorhombic with space group I222 or I2₁2₁2₁ with a = 68.1 Å, b = 88.6 Å, and c = 144.9 Å. The crystals grown in polyethylene glycol solutions are hexagonal with space group P6₁22 or P6₅22 witha a = b = 66.7 Å and c = 245.7 Å. The 40 kDa hep-2B fragment, consisting of type III domains 12–15, was also crystallized from solutions containing ammonium sulfate with the addition of glycerol. Glycerol proved an effective agent for reducing the number of crystals in the crystallization experiments, and thus, increasing the size of the crystals in these experiments. This crystal form is nearly isomorphous to the orthorhombic form of the hep-2A fragment with space group I222 or I2₁2₁2₁ and a = 67.5 Å, b = 87.0 Å, and c = 144.3 Å. All crystal forms diffract to at least 3.5 Å resolution and contain a single molecule in the asymmetric unit. © 1993 Wiley-Liss, Inc.     

Synthesis and SAR studies of novel benzodiazepinedione-based inhibitors of Clostridium difficile (C. difficile) toxin B (TcdB)

Synthesis and structure-activity relationships (SAR) of a novel series of benzodiazepinedione-based inhibitors of Clostridium difficile toxin B (TcdB) are described. Compounds demonstrating low nanomolar affinity for TcdB, and which possess improved stability in mouse plasma vs. earlier compounds from this series, have been identified. Optimized compound 11d demonstrates a good pharmacokinetic (PK) profile in mouse and hamster and is efficacious in a hamster survival model of Clostridium difficile infection.     

Various aspects of structural studies of aspartate proteinases

The paper is a brief account of aspartic proteinases' structural studies developed in V.A. Engelhardt Institute of Molecular Biology during the last 3 years. The work on porcine pepsin has been finalized after the refinement of the monoclinic crystal form at 1.8 A resolution performed in collaboration with the group of protein structure and function studies of the University of Alberta in Canada. An important structural property of chymosin which explains the enzyme specificity has been found. Protein engineering work on chymosin is being developed. The structural template for aspartic proteinases has been elucidated and on the basis of this template the model of HIV-1 protease molecule has been built. Some approaches to the design of HIV-1 protease inhibitors were elucidated.