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We have determined the X-ray crystal structure to 1.8 A resolution of the Ca(2+) complex of complement-like repeat 7 (CR7) from the low-density lipoprotein receptor-related protein (LRP) and characterized its calcium binding properties at pH 7.4 and 5. CR7 occurs in a region of the LRP that binds to the receptor-associated protein, RAP, and other protein ligands in a Ca(2+)-dependent manner. The calcium coordination is identical to that found in LB5 and consists of carboxyls from three conserved aspartates and one conserved glutamate, and the backbone carbonyls of a tryptophan and another aspartate. The overall fold of CR7 is similar to those of CR3 and CR8 from the LRP and LB5 from the LDL receptor, though the low degree of sequence homology of residues not involved in calcium coordination or in disulfide formation results in a distinct pattern of surface residues for each domain, including CR7. The thermodynamic parameters for Ca(2+) binding at both extracellular and endosomal pHs were determined by isothermal titration calorimetry for CR7 and for related complement-like repeats CR3, CR8, and LB5. Although the drop in pH resulted in a reduction in calcium affinity in each case, the changes were very variable in magnitude, being as low as a 2-fold reduction for CR3. This suggests that a pH-dependent change in calcium affinity alone cannot be responsible for the release of bound protein ligands from the LRP at the pH prevailing in the endosome, which in turn requires one or more other pH-dependent effects for regulating protein ligand release.

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Pigment epithelium-derived factor (PEDF), a noninhibitory member of the serpin superfamily, is the most potent inhibitor of angiogenesis in the mammalian ocular compartment. It also has neurotrophic activity, both in the retina and in the central nervous system, and is highly up-regulated in young versus senescent fibroblasts. To provide a structural basis for understanding its many biological roles, we have solved the crystal structure of glycosylated human PEDF to 2.85 A. The structure revealed the organization of possible receptor and heparin-binding sites, and showed that, unlike any other previously characterized serpin, PEDF has a striking asymmetric charge distribution that might be of functional importance. These results provide a starting point for future detailed structure/function analyses into possible mechanisms of PEDF action that could lead to development of therapeutics against uncontrolled angiogenesis.

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Activation of antithrombin by high-affinity heparin as an inhibitor of factor Xa has been ascribed to an allosteric switch between two conformations of the reactive center loop. However, we have previously shown that other, weaker binding, charged polysaccharides can give intermediate degrees of activation [Gettins, P. G. W., et al. (1993) Biochemistry 32, 8385-8389]. To examine whether such intermediate activation results from different reactive center loop conformations or, more simply, from a different equilibrium constant between the same two extreme conformations, we have used NBD covalently bound at the P1 position of an engineered R393C variant of antithrombin as a fluorescent reporter group and measured fluorescence lifetimes of the label in free antithrombin as well as in antithrombin saturated with long-chain high-affinity heparin, high-affinity heparin pentasaccharide, long-chain low-affinity heparin, and dextran sulfate. Steady state emission spectra, anisotropies, and dynamic quenching measurements were also recorded. We found that the large steady state fluorescence enhancements produced by binding of activators resulted from relief of a static quench of fluorescence of NBD in approximately 50% of the labeled antithrombin molecules rather than from any large change in lifetimes, and that similar lifetimes were found for NBD in all activated antithrombin-oligosaccharide complexes. Similar anisotropies and positions of the NBD emission maxima were also found in the absence and presence of activators. In addition, NBD was accessible to quenching agents in both the absence and presence of activators, with an at most 2-fold increase in quenching constants between these two extremes. The simplest interpretation of the partial static quench in the absence of activators, the different degrees of enhancement by different antithrombin activators, and the similar fluorescence properties and quenching behavior of the different states is that there are two distinct types of conformational equilibrium involving three distinct states of antithrombin, which we designate A, A', and B. A and A' represent low-affinity or inactive states of approximately equal energy, both having the hinge residues inserted into beta-sheet A. A is fluorescent, while A' is statically quenched. State B represents the activated loop-expelled conformation in which none of the NBD fluorophores are statically quenched, as a result of the loop, including the P1-NBD, moving away from the body of the antithrombin. Different activators are able to shift the equilibrium to the high-activity (B) state to different extents and hence give different degrees of measured activity, and different degrees of relief of static quench. The similar properties and accessibility of the NBD in the A and B conformations also indicate that the P1 side chain is not buried in the low-activity A conformation, suggesting that an earlier proposal that activation involves exposure of the P1 side chain cannot be the explanation for activation. As an alternative explanation, heparin activation may give access to an exosite on antithrombin for binding to factor Xa and hence be the principal basis for enhancement of the rate of inhibition.

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We describe here the high-level expression of bovine trypsinogen in E. coli, its refolding and activation to beta-trypsin, and the selective incorporation of (15)N-labeled alanine through supplementation of the growth medium. Using this procedure, we expressed (15)N-labeled S195A trypsinogens, both on a wild-type and on a D189S background, in amounts suitable for NMR spectroscopy. 2D [(1)H-(15)N]-HSQC NMR was used to follow conformational changes upon activation of trypsinogen and formation of noncovalent complexes between S195A or S195A/D189S trypsin and protein proteinase inhibitors of different structural families and different sizes, as well as to examine the effects of introduction of the D189S mutation. Spectra of good quality were obtained for both trypsins alone and in complexes of increasing size with the proteinase inhibitors BPTI (total molecular mass 31 kDa), SBTI (total molecular mass 44 kDa), and the serpin alpha(1)-proteinase inhibitor Pittsburgh (alpha(1)PI Pittsburgh) (total molecular mass 69 kDa). Assignments of alanines 55 and 56, close to the active site histidine, and of alanine 195, present in the S195A variant used for most of the studies, were made by mutagenesis. These three alanines, together with two others, probably close to the S1 specificity pocket, were very sensitive to complex formation. In contrast, the remaining 10 alanines were invariant in chemical shift in all 3 of the noncovalent complexes formed, reflecting the conservation of structure in complexes with BPTI and SBTI known from X-ray crystal structures, but also indicating that there is no change in backbone conformation for the noncovalent complex with alpha(1)PI, for which there is no crystal structure. This was true both for S195A and for S195A/D189S trypsins. This high-level expression and labeling approach will be of great use for solution NMR studies on trypsin-serpin complexes, as well as for structural and mechanistic studies on trypsin variants.

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We have used [(1)H-(15)N]-HSQC NMR to investigate the structural changes that occur in both serpin and proteinase in forming the kinetically trapped covalent protein-protein complex that is the basis for serpin inhibition of serine proteinases. By alternately using (15)N-alanine specifically-labeled alpha(1)-proteinase inhibitor (alpha(1)PI) Pittsburgh (serpin) and bovine trypsin (proteinase), we were able to selectively monitor structural changes in each component of the 69 kDa complex. Residue-specific assignments of four alanines in the reactive center loop and seven other alanines aided interpretation of the spectral changes in the serpin. We found that the majority of the alanine resonances, including those from reactive center loop residues P12, P11, and P9, were at identical positions in covalent complex and in cleaved alpha(1)PI. Five alanines that are close to the contact region with proteinase showed some chemical shift perturbation compared with cleaved alpha(1)PI, indicating some degree of structural deformation. With (15)N label in the proteinase, an HSQC spectrum was obtained that more closely resembled that of a molten globule, suggesting that the structure of the proteinase had been significantly altered as a result of complex formation. Large increases in line width for all alpha(1)PI resonances in the covalent complex, with the sole exception of two residues in the flexible N-terminal tail, indicate that, unlike the noncovalent alpha(1)PI-anhydroproteinase complex, the covalent complex is a rigid body of effectively increased molecular weight. We conclude that the mutual perturbations of serpin and proteinase result from steric compression and distortion, rather than simple contact effects. This distortion provides a structural basis for the greatly reduced catalytic efficiency of the proteinase in the complex and hence kinetic trapping of the covalent reaction intermediate.

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Tva is the cellular receptor for subgroup A avian sarcoma and leukosis virus (ASLV-A). The viral receptor function of Tva is determined by a 40-residue cysteine-rich motif called the LDL-A module. In this study, we expressed and purified the wild-type (wt) Tva LDL-A module as well as several mutants and examined their in vitro folding properties. We found that, as for other LDL-A modules, correct folding and structure of the Tva LDL-A module is Ca2+ dependent. When calcium was present during in vitro protein folding, the wt module was eluted as a single peak by reverse-phase high-pressure liquid chromatography. Furthermore, two-dimensional nuclear magnetic resonance (NMR) spectroscopy gave well-dispersed spectra in the presence of calcium. In contrast, the same protein folded in vitro in the absence of calcium was eluted as multiple broad peaks and gave a poorly dispersed NMR spectrum in the presence of calcium. The calcium affinity (Kd) of the Tva LDL-A module, determined by isothermal titration calorimetry, is approximately 40 microM. Characterization of several Tva mutants provided further evidence that calcium is important in protein folding and function of Tva. Mutations of the Ca2+-binding residues (D46A and E47A) completely abrogated the Ca2+-binding ability of Tva, and the proteins were not correctly folded. Interestingly, mutations of two non-calcium-binding residues (W48A and L34A) also exerted adverse effect on Ca2+-dependent folding, albeit to a much less extent. Our results provide new insights regarding the structure and function of Tva in ASLV-A entry.

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CrmA is an unusual serpin that has a reactive-center loop one residue shorter than other members of the superfamily. Most interestingly, crmA has inhibitory activity against both cysteine and serine proteinases involved in the regulation of cell apoptosis. The three-dimensional structure of crmA will give insight into the mechanism that this serpin employs to inhibit both cysteine and the serine proteinases, as well as help to explain the significance of the shorter reactive-center loop. The monodisperse cysteine-free mutant of crmA was crystallized in the presence of phosphate salts. Crystals diffract to 2.90 A and belong to space group P2(1)2(1)2(1), with unit-cell parameters a = 42.67, b = 93.15, c = 101.63 A.

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A structural understanding of the nature and scope of serpin inhibition mechanisms has been limited by the inability so far to crystallize any serpin-proteinase complex. We describe here the application of [(1)H-(15)N]-HSQC NMR on uniformly and residue-selectively (15)N-labeled serpin alpha(1)-proteinase inhibitor (Pittsburgh variant with stabilizing mutations) to provide a nonperturbing and exquisitely sensitive means of probing the conformation of the serpin alone and in a noncovalent complex with inactive, serine 195-modified, bovine trypsin. The latter should be a good model both for the few examples of reversible serpin-proteinase complexes and for the initial Michaelis-like complex formed en route to irreversible covalent inhibition. Cleavage of the reactive center loop, with subsequent insertion into beta-sheet A, caused dramatic perturbation of most of the NMR cross-peaks. This was true for both the uniformly labeled and alanine-specifically labeled samples. The spectra of uniformly or leucine- or alanine-specifically labeled alpha(1)-proteinase inhibitor in noncovalent complex with unlabeled inactive trypsin gave almost no detectable chemical shift changes of cross-peaks, but some general increase in line width. Residue-specific assignments of the four alanines in the reactive center loop, at P12, P11, P9, and P4, allowed specific examination of the behavior of the reactive center loop. All four alanines showed higher mobility than the body of the serpin, consistent with a flexible reactive center loop, which remained flexible even in the noncovalent complex with proteinase. The three alanines near the hinge point for insertion showed almost no chemical shift perturbation upon noncovalent complex formation, while the alanine at P4 was perturbed, presumably by interaction with the active site of bound trypsin. Reporters from both the body of the serpin and the reactive center loop therefore indicate that noncovalent complex formation involves no conformational change in the body of the serpin and only minor perturbation of the reactive center loop in the region which contacts proteinase. Thus, despite the large size of serpin and serpin-proteinase complex, 45 and 69 kDa respectively, NMR provides a very sensitive means of probing serpin conformation and mobility, which should be applicable both to noncovalent and to covalent complexes with a range of different proteinases, and probably to other serpins.

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alpha(1)-Antitrypsin is the most abundant circulating protease inhibitor and the archetype of the serine protease inhibitor or serpin superfamily. Members of this family may be inactivated by point mutations that favor transition to a polymeric conformation. This polymeric conformation underlies diseases as diverse as alpha(1)-antitrypsin deficiency-related cirrhosis, thrombosis, angio-edema, and dementia. The precise structural linkage within a polymer has been the subject of much debate with evidence for reactive loop insertion into beta-sheet A or C or as strand 7A. We have used site directed cysteine mutants and fluorescence resonance energy transfer (FRET) to measure a number of distances between monomeric units in polymeric alpha(1)-antitrypsin. We have then used a combinatorial approach to compare distances determined from FRET with distances obtained from 2.9 x 10(6) different possible orientations of the alpha(1)-antitrypsin polymer. The closest matches between experimental FRET measurements and theoretical structures show conclusively that polymers of alpha(1)-antitrypsin form by insertion of the reactive loop into beta-sheet A.

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A three-dimensional reconstruction of a protein-engineered mutant alpha(2)-macroglobulin (alpha(2)M) in which a serine residue was substituted for the cysteine 949 (C949S), making it unable to form internal thiol ester moieties, was compared with native and methylamine-transformed alpha(2)Ms. The native alpha(2)M structure consists of two oppositely oriented Z-shaped strands. Thiol ester cleavage following an encounter with a proteinase or a nucleophilic attack by methylamine causes a structural transformation in which the strands assume an opposite handedness and a significant portion of the protein density migrates from the distal ends of the molecule toward the center. The C949S mutant showed a protein density distribution very similar to that of transformed alpha(2)M, with a compact central region of protein density connected to two receptor-binding arms on each end of the molecule. Since no particle shapes characteristic of native or half-transformed alpha(2)Ms were seen in electron micrographs and the C949S mutant and alpha(2)M-methylamine structures are highly similar, we conclude that the intact thiol esters maintain native alpha(2)M in a quasi-stable state. In their absence, alpha(2)M folds into the more stable transformed structure, which displays the functionally important receptor-binding domains and contains the proteinase-entrapping internal cavity.

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Antithrombin is unique among the serpins in that it circulates in a native conformation that is kinetically inactive toward its target proteinase, factor Xa. Activation occurs upon binding of a specific pentasaccharide sequence found in heparin that results in a rearrangement of the reactive center loop removing constraints on the active center P1 residue. We determined the crystal structure of an activated antithrombin variant, N135Q S380C-fluorescein (P14-fluorescein), in order to see how full activation is achieved in the absence of heparin and how the structural effects of the substitution in the hinge region are translated to the heparin binding region. The crystal structure resembles native antithrombin except in the hinge and heparin binding regions. The absence of global conformational change allows for identification of specific interactions, centered on Glu(381) (P13), that are responsible for maintenance of the solution equilibrium between the native and activated forms and establishes the existence of an electrostatic link between the hinge region and the heparin binding region. A revised model for the mechanism of the allosteric activation of antithrombin is proposed.

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Heparin regulates the inhibitory activity of antithrombin. It has been proposed that residues P15 and P14 are expelled from beta-sheet A of antithrombin by heparin binding, permitting better interaction of the reactive center loop with factor Xa. We have made a P14 antithrombin variant (S380E) to create an activated inhibitory form of antithrombin in which P14 is already expelled from beta-sheet A. S380E antithrombin fluorescence is enhanced 35 +/- 5% compared with control antithrombin. There is minimal further increase in antithrombin fluorescence upon heparin binding. The variant has a 5 degrees C lower T(m) than control antithrombin. The variant is an inhibitor of proteinases and has a nearly 200-fold increased basal rate of inhibition of factor Xa, after correction for an increased stoichiometry of inhibition. This is comparable to that of antithrombin activated by high affinity heparin pentasaccharide. Full-length high affinity heparin causes only a 7-fold additional increase in rate and a large increase in stoichiometry of inhibition. In contrast, the basal rate of inhibition of thrombin is similar to that of control antithrombin but is increased 300-fold by heparin. These findings suggest that the native state of the S380E variant exists in a loop-expelled conformation that is consequently highly reactive toward factor Xa.

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We have used NMR methods to determine the structure of the calcium complex of complement-like repeat 3 (CR3) from the low density lipoprotein receptor-related protein (LRP) and to examine its specific interaction with the receptor binding domain of human alpha(2)-macroglobulin. CR3 is one of eight related repeats that constitute a major ligand binding region of LRP. The structure is very similar in overall fold to homologous complement-like repeat CR8 from LRP and complement-like repeats LB1, LB2, and LB5 from the low density lipoprotein receptor and contains a short two-strand antiparallel beta-sheet, a one turn alpha-helix, and a high affinity calcium site with coordination from four carboxyls and two backbone carbonyls. The surface electrostatics and topography are, however, quite distinct from each of these other repeats. Two-dimensional (1)H,(15)N-heteronuclear single quantum coherence spectra provide evidence for a specific, though relatively weak (K(d) approximately 140 microM), interaction between CR3 and human alpha2-macroglobulin receptor binding domain that involves a contiguous patch of surface residues in the central region of CR3. This specific interaction is consistent with a mode of LRP binding to ligands that uses contributions from more than one domain to generate a wide array of different binding sites, each with overall high affinity.

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The binding of pentasaccharide heparin to antithrombin induces a conformational change that is transmitted to the reactive center loop and increases the rate of inhibition of factor Xa by approximately 300-fold. The mechanism of such transmission is not known. To test the role of residues 134-137, which link helix D to beta-sheet A, in this signal transduction, we created variant antithrombins in which we removed amino acids 134-137 stepwise and cumulatively. Although the deletions did not compromise the fundamental ability of antithrombin to bind to heparin or to inhibit target proteinases thrombin and factor Xa, they did largely decouple conformational changes in the heparin-binding site from conformational activation of the reactive center loop. Because the variant with only Ala(134) removed was as compromised as variants with larger deletions, yet the variant with Ser(137) removed was normal, we concluded that the length of the linker is less important than the precise interrelationship between residues in this region and other residues involved in conformational activation of antithrombin.

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Human alpha(2)-macroglobulin-proteinase complexes bind to their receptor, the low density lipoprotein receptor-related protein (LRP), through a discrete 138-residue C-terminal receptor binding domain (RBD), which also binds to the beta-amyloid peptide. We have used NMR spectroscopy on recombinantly expressed uniformly (13)C/(15)N-labeled human RBD to determine its three-dimensional structure in solution. Human RBD is a sandwich of two antiparallel beta-sheets, one four-strand and one five-strand, and also contains one alpha-helix of 2.5 turns and an additional 1-turn helical region. The principal alpha-helix contains two lysine residues on the outer face that are known to be essential for receptor binding. A calcium binding site (K(d) approximately 11 mM) is present in the loop region at one end of the beta-sandwich. Calcium binding principally affects this loop region and does not significantly perturb the stable core structure of the domain. The structure and NMR assignments will enable us to examine in solution specific binding of RBD to domains of the receptor and to beta-amyloid peptide.

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Thyroxine binding globulin (TBG) is the major carrier of the thyroid hormones triiodothyronine (T3) and thyroxine (T4) in plasma. TBG is member of the serpin family of proteins although it has no proteinase inhibitory activity. In this study we show that TBG has properties typical of a metastable serpin and provide evidence that occupancy of the hormone binding site alters the conformation of the reactive center loop. After reactive center loop cleavage by endoproteinase Asp-N or neutrophil elastase the protein became more stable to guanidine hydrochloride denaturation compared to the native protein, as a result of loop insertion. In addition, incubation of the native protein with a reactive center loop peptide, caused a change in mobility on a native gel. This is consistent with the idea that thyroxine binding globulin is able to form a binary complex with the peptide as a result of beta-sheet A expansion. To assess the effect of cleavage and loop insertion on the hormone binding site we used the specific binding of a fluorophore, 1,8-anilinonaphthalene sulfonic acid (ANS). Loop insertion itself had no effect on ANS affinity, but cleavage with elastase at the P4'-P5' bond caused a reduction in affinity, presumably because this cleavage site is located within the hormone binding site. These data support the concept that cleavage of TBG by proteinases released in inflammation is a mechanism to deliver thyroid hormones to target tissues. A linkage between the occupancy state of the hormone binding site and the conformation of the reactive center loop was indicated by the observation that binding of T3 to native TBG reduced proteolytic susceptibility by both endoproteinase Asp-N and elastase.

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A sequence-specific heparin pentasaccharide activates the serpin, antithrombin, to inhibit factor Xa through an allosteric mechanism, whereas full-length heparin chains containing this sequence further activate the serpin to inhibit thrombin by an alternative bridging mechanism. To test whether the factor Xa specificity of allosterically activated antithrombin is encoded in the serpin reactive center loop, we mutated the factor Xa-preferred P2 Gly to the thrombin-preferred P2 Pro. Kinetic studies revealed that the mutation maximally enhanced the reactivity of antithrombin with thrombin 15-fold and decreased its reactivity toward factor Xa 2-fold when the serpin was activated by heparin pentasaccharide, thereby transforming antithrombin into an allosterically activated inhibitor of both factor Xa and thrombin. Surprisingly, the enhanced thrombin specificity of the mutant antithrombin was attenuated when a full-length bridging heparin was the activator, due both to a reduced rate of covalent reaction of the mutant serpin and thrombin and preferred reaction of the mutant serpin as a substrate. These results demonstrate that the reactive center loop sequence determines the specificity of allosterically activated antithrombin for factor Xa and that the conformational flexibility of the P2 Gly may be critical for optimal bridging of antithrombin and thrombin by physiologic heparin and for preventing antithrombin from reacting as a substrate in the bridging complex.

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The low density lipoprotein receptor-related protein is a member of the low density lipoprotein receptor family and contains clusters of cysteine-rich complement-like repeats of about 42 residues that are present in all members of this family of receptors. These clusters are thought to be the principal binding sites for protein ligands. We have expressed one complement-like repeat, CR8, from the cluster in lipoprotein receptor-related protein that binds certain proteinase inhibitor-proteinase complexes and used three-dimensional NMR on the 13C/15N-labeled protein to determine the structure in solution of the calcium-bound form. The structure is very similar in overall fold to repeat 5 from the low density lipoprotein receptor (LB5), with backbone root mean square deviation of 1.5 A. The calcium-binding site also appears to be homologous, with four carboxyl and two backbone carbonyl ligands. However, differences in primary structure are such that equivalent surfaces that might represent the binding interfaces are very different from one another, indicating that different domains will have very different ligand specificities.

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