Interspecies exchange mutagenesis of the first epidermal growth factor-like domain of human factor VII.

The first epidermal growth factor-like (EGF1) domain of human factor VII (FVII) is essential for binding to tissue factor (TF). We hypothesized that the previously observed increased coagulant activity of rabbit plasma (i.e. FVII) with human TF might be explained by the five non-conserved amino acids in the rabbit vs. the human FVII EGF1 domain. Accordingly, we 'rabbitized' the human FVII EGF1 domain either by exchanging the entire EGF1 domain creating human FVII(rabEGF1) or by the single amino acid substitutions S53N, K62E, P74A, A75D and T83K. After transient expression in HEK293 cells, the recombinant FVII (rFVII) mutant proteins were analyzed for biological activity and binding affinity to human TF by competitive enzyme-linked immunosorbent assay (ELISA). Biological activity of the unpurified rFVII mutant proteins was either depressed or statistically unchanged vs. rFVII(WT). However, three of six rFVII mutant proteins had increased affinity for human TF in the rank order rFVII(rabEGF1) (3.3-fold) > rFVII(K62E) (2.9-fold) > rFVII(A75D) (1.7-fold). The mutant protein rFVII(K62E) was then permanently expressed and purified. Fully activated, purified rFVIIa(K62E) had a twofold greater clotting activity and 2.8-fold greater direct FVIIa amidolytic activity when compared with rFVIIa(WT). Quantitation of the affinity of TF binding by surface plasmon resonance indicated that the KD of purified rFVII(K62E) for human soluble TF (sTF) was 1.5 nM compared with 7.5 nM for rFVII(WT), i.e. fivefold greater affinity. We conclude that substitution of selected amino acid residues of the FVII EGF1 domain facilitated the creation of human rFVII chimeric proteins with both enhanced biological activity and increased affinity for TF.

The 1.85 A resolution crystal structures of tissue factor in complex with humanized Fab D3h44 and of free humanized Fab D3h44: revisiting the solvation of antigen combining sites.

The outstanding importance of the antigen-antibody recognition process for the survival and defence strategy of higher organisms is in sharp contrast to the limited high resolution structural data available on antibody-antigen pairs with antigenic proteins. The limitation is the most severe for structural data not restricted to the antigen-antibody complex but extending to the uncomplexed antigen and antibody. We report the crystal structure of the complex between tissue factor (TF) and the humanized Fab fragment D3h44 at a resolution of 1.85 A together with the structure of uncomplexed D3h44 at the same resolution. In conjunction with the previously reported 1.7 A crystal structure of uncomplexed TF, a unique opportunity is generated to explore details of the recognition process. The TF.D3h44 interface is characterised by a high number of polar interactions, including as may as 46 solvent molecules. Conformational changes upon complex formation are very small and almost exclusively limited to the reorientation of side-chains. The binding epitope is in complete agreement with earlier mutagenesis experiments. A revaluation of two other antibody-antigen pairs reported at similar resolutions, shows that all these complexes are very similar with respect to the solvation of the interface, the number of solvent positions conserved in the uncomplexed and complexed proteins and the number of water molecules expelled from the surface and replaced by hydrophilic atoms from the binding partner upon complex formation. A strategy is proposed on how to exploit this high resolution structural data to guide the affinity maturation of humanised antibodies.

IL-17s adopt a cystine knot fold: structure and activity of a novel cytokine, IL-17F, and implications for receptor binding.

The proinflammatory cytokine interleukin 17 (IL-17) is the founding member of a family of secreted proteins that elicit potent cellular responses. We report a novel human IL-17 homolog, IL-17F, and show that it is expressed by activated T cells, can stimulate production of other cytokines such as IL-6, IL-8 and granulocyte colony-stimulating factor, and can regulate cartilage matrix turnover. Unexpectedly, the crystal structure of IL-17F reveals that IL-17 family members adopt a monomer fold typical of cystine knot growth factors, despite lacking the disulfide responsible for defining the canonical "knot" structure. IL-17F dimerizes in a parallel manner like neurotrophins, and features an unusually large cavity on its surface. Remarkably, this cavity is located in precisely the same position where nerve growth factor binds its high affinity receptor, TrkA, suggesting further parallels between IL-17s and neurotrophins with respect to receptor recognition.

Generation of a humanized, high affinity anti-tissue factor antibody for use as a novel antithrombotic therapeutic.

Blocking the cofactor function of human tissue factor may be beneficial in various coagulation-mediated diseases. The murine antibody D3 binds to the membrane proximal substrate interaction region of human tissue factor and blocks tissue factor function even in the presence of bound factor VIIa. The cloned murine D3 antibody was humanized and affinity matured by exchanging amino acids in the complementarity determining regions as well as in the antibody framework. The humanized antibody, D3H44, bound to tissue factor with a 100-fold increased affinity (KD 0.1 nM) as compared to the original murine and chimeric versions. Depending on the particular disease, different pharmacokinetic properties of the antibody may be required and, therefore, several antibody variants-- F(ab), F(ab')2, IgG2, IgG4 and IgG4b-were generated. In vitro, the humanized D3 antibodies displayed potent inhibition of plasma clotting and tissue factor: factor VIIa-mediated activation of factors IX and X (e.g. D3H44-F(ab')2, IC50(F.X) 47 pM). In addition, D3H44-F(ab')2 completely prevented fibrin deposition in a human ex vivo thrombosis model under venous blood flow conditions (IC50 37 nM). The humanized D3 antibodies may be utilized for treatment of cardiovascular diseases which involve tissue factor activity, e.g. acute coronary syndrome and venous thrombosis.

The tissue factor region that interacts with factor Xa in the activation of factor VII.

Tissue factor is the cell membrane-anchored cofactor for factor VIIa and triggers the coagulation reactions. The initial step is the conversion of factor VII to factor VIIa which, in vitro, is efficiently catalyzed by low concentrations of factor Xa. To identify the tissue factor region that interacts with the activator factor Xa during this process, we evaluated a panel of soluble tissue factor (1-219) mutants for their ability to support factor Xa-mediated activation of factor VII. The tissue factor residues identified as most important for this interaction (Tyr157, Lys159, Ser163, Gly164, Lys165, Lys166, and Tyr185) were identical to those found to be important for the interaction of substrate factor X with the tissue factor.factor VIIa complex. The residues form a continuous surface-exposed patch with an area of about 500 A(2), which appears to be located outside the tissue factor-factor VII contact zone. In agreement, the two monoclonal antibodies 5G6 and D3H44-F(ab')(2), whose epitopes overlap with this identified region, inhibited the rates of factor VII activation by 86% and 95%, respectively. These antibodies also strongly inhibited the conversion of (125)I-labeled factor VII when cell membrane-expressed, full-length tissue factor (1-263) was employed. Together the results suggest the usage of a common surface region of tissue factor in its dual role-as a cofactor for factor Xa-mediated factor VII activation and as a cofactor for factor VIIa-mediated factor X activation. The finding that factor Xa and factor X may engage in similar, if not identical, molecular interactions with tissue factor further indicates that factor Xa and factor X are similarly oriented toward their respective interaction partners in the ternary catalytic complexes.

The tissue factor region that interacts with substrates factor IX and Factor X.

The enzymatic activity of coagulation factor VIIa is controlled by its cellular cofactor tissue factor (TF). TF binds factor VIIa with high affinity and, in addition, participates in substrate interaction through its C-terminal fibronectin type III domain. We analyzed surface-exposed residues in the C-terminal TF domain to more fully determine the area on TF important for substrate activation. Soluble TF (sTF) mutants were expressed in E. coli, and their ability to support factor VIIa-dependent substrate activation was measured in the presence of phospholipid vesicles or SW-13 cell membranes. The results showed that factor IX and factor X interacted with the same TF region located proximal to the putative phospholipid surface. According to the degree of activity loss of the sTF mutants, this TF region can be divided into a main region (residues Tyr157, Lys159, Ser163, Gly164, Lys165, Lys166, Tyr185) forming a solvent-exposed patch of 488 A(2) and an extended region which comprises an additional 7-8 residues, including the distally positioned Asn199, Arg200, and Asp204. Some of the identified TF residues, such as Trp158 and those within the loop Lys159-Lys165, are near the factor VIIa gamma-carboxyglutamic acid (Gla) domain, suggesting that the factor VIIa Gla-domain may also participate in substrate interaction. Moreover, the surface identified as important for substrate interaction carries a net positive charge, suggesting that charge interactions may significantly contribute to TF-substrate binding. The calculated surface-exposed area of this substrate interaction region is about 1100 A(2), which is approximately half the size of the TF area that is in contact with factor VIIa. Therefore, a substantial portion of the TF surface (3000 A(2)) is engaged in protein-protein interactions during substrate catalysis.

A unique zinc-binding site revealed by a high-resolution X-ray structure of homotrimeric Apo2L/TRAIL.

Apoptosis-inducing ligand 2 (Apo2L, also called TRAIL), a member of the tumor necrosis factor (TNF) family, induces apoptosis in a variety of human tumor cell lines but not in normal cells [Wiley, S. R., Schooley, K., Smolak, P. J., Din, W. S., Huang, C.-P., Nicholl, J. K., Sutherland, G. R., Smith, T. D., Rauch, C., Smith, C. A., and Goodwin, R. G. (1995) Immunity 3, 673-682; Pitti, R. M., Marsters, S. A., Ruppert, S., Donahue, C. J., Moore, A., and Ashkenazi, A. (1996) J. Biol. Chem. 271, 12687-12690]. Here we describe the structure of Apo2L at 1.3 A resolution and use alanine-scanning mutagenesis to map the receptor contact regions. The structure reveals a homotrimeric protein that resembles TNF with receptor-binding epitopes at the interface between monomers. A zinc ion is buried at the trimer interface, coordinated by the single cysteine residue of each monomer. The zinc ion is required for maintaining the native structure and stability and, hence, the biological activity of Apo2L. This is the first example of metal-dependent oligomerization and function of a cytokine.

Epitope location on tissue factor determines the anticoagulant potency of monoclonal anti-tissue factor antibodies.

Tissue factor (TF), the cellular cofactor for the serine protease factor VIIa (F.VIIa), triggers blood coagulation and is involved in the pathogenesis of various thrombosis-related disorders. Therefore, agents which specifically target tissue factor, such as monoclonal antibodies, may provide promising new antithrombotic therapy. We mapped the epitopes of several anti-TF antibodies using a panel of soluble TF mutants. They bound to three distinct TF regions. The epitope of the 7G11 antibody included Phe50 and overlapped with a TF-F.VIIa light chain contact area. The common epitope of the antibodies 6B4 and HTF1 included residues Tyr94 and Phe76 both of which make critical contacts to the catalytic domain of F.VIIa. The antibodies D3 and 5G6 had a common epitope outside the TF-F.VIIa contact region. It included residues Lys 165, Lys 166, Asn199, Arg200 and Lys201 and thus overlapped with the substrate interaction region of tissue factor. The antibodies 5G6 and D3 were potent anticoagulants when infused to flowing human blood in an ex-vivo thrombosis model. Plasma fibrinopeptide A levels and fibrin deposition were completely inhibited. In contrast, 6B4 was a weak inhibitor in this ex-vivo thrombosis model, and HTF1 displayed no inhibition at all. These disparate activities were also reflected in TF-dependent F.X activation assays performed with human plasma. The potency differences could neither be explained by the determined binding affinities nor by the on-rates of antibodies. Therefore, the results suggest that antibody binding epitope and hence the particular mechanism of inhibition, is the main determinative factor of anticoagulant potency of anti-TF antibodies.

Triggering cell death: the crystal structure of Apo2L/TRAIL in a complex with death receptor 5.

Formation of a complex between Apo2L (also called TRAIL) and its signaling receptors, DR4 and DR5, triggers apoptosis by inducing the oligomerization of intracellular death domains. We report the crystal structure of the complex between Apo2L and the ectodomain of DR5. The structure shows three elongated receptors snuggled into long crevices between pairs of monomers of the homotrimeric ligand. The interface is divided into two distinct patches, one near the bottom of the complex close to the receptor cell surface and one near the top. Both patches contain residues that are critical for high-affinity binding. A comparison to the structure of the lymphotoxin-receptor complex suggests general principles of binding and specificity for ligand recognition in the TNF receptor superfamily.

Antibody variable region binding by Staphylococcal protein A: thermodynamic analysis and location of the Fv binding site on E-domain.

Immunoglobulins of human heavy chain subgroup III have a binding site for Staphylococcal protein A on the heavy chain variable domain (V(H)), in addition to the well-known binding site on the Fc portion of the antibody. Thermodynamic characterization of this binding event and localization of the Fv-binding site on a domain of protein A is described. Isothermal titration calorimetry (ITC) was used to characterize the interaction between protein A or fragments of protein A and variants of the hu4D5 antibody Fab fragment. Analysis of binding isotherms obtained for titration of hu4D5 Fab with intact protein A suggests that 3-4 of the five immunoglobulin binding domains of full length protein A can bind simultaneously to Fab with a Ka of 5.5+/-0.5 x 10(5) M(-1). A synthetic single immunoglobulin binding domain, Z-domain, does not bind appreciably to hu4D5 Fab, but both the E and D domains are functional for hu4D5 Fab binding. Thermodynamic parameters for titration of the E-domain with hu4D5 Fab are n = 1.0+/-0.1, Ka = 2.0+/-0.3 x 10(5) M(-1), and deltaH = -7.1+/-0.4 kcal mol(-1). Similar binding thermodynamics are obtained for titration of the isolated V(H) domain with E-domain indicating that the E-domain binding site on Fab resides within V(H). E-domain binding to an IgG1 Fc yields a higher affinity interaction with thermodynamic parameters n = 2.2+/-0.1, Ka > 1.0 x 10(7) M(-1), and deltaH = -24.6+/-0.6 kcal mol(-1). Fc does not compete with Fab for binding to E-domain indicating that the two antibody fragments bind to different sites. Amide 1H and 15N resonances that undergo large changes in NMR chemical shift upon Fv binding map to a surface defined by helix-2 and helix-3 of E-domain, distinct from the Fc-binding site observed in the crystal structure of the B-domain/Fc complex. The Fv-binding region contains negatively charged residues and a small hydrophobic patch which complements the basic surface of the region of the V(H) domain implicated previously in protein A binding.

The effect of O-fucosylation on the first EGF-like domain from human blood coagulation factor VII.

The first epidermal growth factor-like domain (EGF-1) from blood coagulation factor VII (FVII) contains two unusual O-linked glycosylation sites at Ser-52 and Ser-60. We report here a detailed study of the effect of O-fucosylation at Ser-60 on the structure of FVII EGF-1, its Ca2+-binding affinity, and its interaction with tissue factor (TF). The in vitro fucosylation of the nonglycosylated FVII EGF-1 was achieved by using O-fucosyltransferase purified from Chinese hamster ovary cells. Distance and dihedral constraints derived from NMR data were used to determine the solution structures of both nonglycosylated and fucosylated FVII EGF-1 in the presence of CaCl2. The overall structure of fucosylated FVII EGF-1 is very similar to the nonfucosylated form even for the residues near the fucosylation site. The Ca2+ dissociation constants (Kd) for the nonfucosylated and fucosylated FVII EGF-1 were found to be 16.4 +/- 1.8 and 8.6 +/- 1.4 mM, respectively. The FVII EGF-1 domain binds to the extracellular part of TF with a low affinity (Kd approximately 0. 6 mM), and the addition of fucose appears to have no effect on this affinity. These results indicate that the FVII EGF-1 alone cannot form a tight complex with TF and suggest that the high binding affinity of FVIIa for TF requires cooperative interaction among the four domains in FVII with TF. Although the fucose has no significant effect on the interaction between TF and the individual FVII EGF-1 domain, it may affect the interaction of full-length FVIIa with TF by influencing its Ca2+-binding affinity.

Factor VIIa's first epidermal growth factor-like domain's role in catalytic activity.

Factor VIIa-tissue factor complex formation initiates the extrinsic blood coagulation pathway. We investigated factor VIIa's first epidermal growth factor-like (egf1) domain's role in the catalytic activity increase caused when factor VIIa binds tissue factor. Starting with a factor VIIa with factor IX's egf1 domain (factor VII(IXegf1)a), we made 4 proteins with egf1 residues changed to those in factor VIIa, including E51A, D64Q, FG74-75PA, and K79R. We measured each enzyme's affinity for tissue factor and determined the enzymes' kinetic constants with and without tissue factor. The Kd for factor VII(IXegf1)a binding to tissue factor was 60-200-fold higher than that of factor VIIa depending on the assay employed. Only factor VII(IXegf1)a with the K79R (K79Ra) mutation, among all the mutants, had an effect on binding with a Kd 3-8-fold lower than that of factor VII(IXegf1)a. In kinetic analyses with a small peptide substrate, in the absence of tissue factor, factor VIIa, factor VII(IXegf1)a, and K79Ra had similar kcat's and Km's. With tissue factor, due to a kcat decrease, factor VII(IXegf1)a's catalytic efficiency (kcat/Km) was 2-fold lower than factor VIIa's. K79Ra's catalytic efficiency was intermediate between those of factor VIIa and factor VII(IXegf1)a. With factor X as substrate, in the absence of tissue factor, K79Ra and factor VII(IXegf1)a had catalytic efficiencies 1.5-fold and 2-fold lower than that of factor VIIa. In contrast, with tissue factor and with factor X as substrate, due to higher Km's, factor VII(IXegf1)a and K79Ra had only 9% and 33% of factor VIIa's catalytic efficiency. Our results suggest the egf1 domain's role in tissue factor binding involves critical alignment of tissue factor with factor VIIa's catalytic domain. Proper alignment in turn promotes optimal catalytic activities.

Hinge bending within the cytokine receptor superfamily revealed by the 2.4 A crystal structure of the extracellular domain of rabbit tissue factor.

Tissue factor (TF), a member of the cytokine receptor superfamily, is the obligate cofactor of coagulation factor VIIa (FVIIa), and has a pivotal role in initiating the extrinsic pathway of blood coagulation through formation of the TF x FVIIa complex. The crystal structure of the extracellular portion of rabbit TF has been solved at 2.35 A resolution and refined to a crystallographic R-value of 19.1% (free R-value, 27.7%). Like the human homologue, the extracellular portion consists of two fibronectin type III domains connected by a short alpha-helical segment. Unexpectedly, the two molecules in the crystallographic asymmetric unit differ in their relative domain-domain orientation, revealing unsuspected hinge motion consisting of a rotation of about 12.7 degrees around an axis intersecting the linker segment at residue 106. Superposition of rabbit tissue factor with free and bound human tissue factor allows for the detection of an identical, albeit smaller, hinge motion in human TF induced upon binding of FVIIa. This raises the possibility that a very similar hinge axis may be present in other members of the cytokine receptor superfamily.

A novel soluble tissue factor variant with an altered factor VIIa binding interface.

Tissue factor (TF) residues Lys20 and Asp58 form part of a binding epitope previously shown by alanine scanning to be critical for high affinity interactions with factor VIIa (FVIIa). To explore the possibility of enhancing the affinity of a TF-based antagonist for FVIIa, we created libraries in which residues at 20, 58, and adjacent positions were varied in constructs containing the soluble extracellular domain of TF (sTF) fused to the bacteriophage M13 tail coat protein. TF variants monovalently displayed on phage were then sorted on the basis of binding to FVIIa. Sorting of preliminary libraries, in which position 58 and/or 20 and surrounding residues were randomized, led to the selection of TF proteins of essentially wild-type sequence. Therefore, we devised a strategy wherein TF position 20 was held fixed as alanine and 5 specific residues near to, and including, position 58 were randomized to effectively obtain alternative sequences at this interface. The consensus sequence reached with this library included wild-type residues at positions 61, 62, 65, and 66 but exclusively tryptophan at position 58. Analyses of the soluble K20A,D58W (A20W58) TF protein indicated that it binds FVIIa with an affinity comparable with wild-type sTF but is defective as a cofactor for FVIIa-dependent factor X activation. Further experiments designed to elucidate the mechanism of binding suggest that the new binding interactions involve more than the simple addition of hydrophobic surface area.

Tween protects recombinant human growth hormone against agitation-induced damage via hydrophobic interactions.

In the absence of surfactants, recombinant human growth hormone (rhGH) rapidly forms insoluble aggregates during agitation. The nonionic surfactant Tween 20, when present at Tween:protein molar ratios >4, effectively inhibits this aggregation. Differential scanning calorimetry (DSC) of rhGH solutions showed melting transitions that decreased by ca. 2 degrees C in the presence of Tween. Circular dichroism (CD) studies of the same thermal transition showed that the decrease is specific to the relatively high protein concentrations required for DSC. CD studies showed melting transitions that decreased with lower protein concentrations. Tween has an insignificant effect on the melting transition of rhGH at lower protein concentrations (0.18 mg/mL). Injection titration microcalorimetry showed that the interaction of Tween with rhGH is characterized by a weak enthalpy of binding. For comparison, interferon-g, another protein which has been shown to bind Tween, also shows weak enthalpy of binding. Fluorescent probe binding studies and infrared spectroscopic investigations of rhGH secondary structure support suggestions in the literature (Bam, N. B.; Cleland, J. L., Randolph, T. W. Molten globule intermediate of recombinant human growth hormone: stabilization with surfactants. Biotechnol. Prog. 1996. 12, 801-809) that Tween binding is driven by hydrophobic interactions, with little perturbation of protein secondary structure.

A soluble tissue factor mutant is a selective anticoagulant and antithrombotic agent.

One approach to developing safer and more efficacious agents for the treatment of thrombotic disease involves the design and testing of inhibitors that block specific steps in the coagulation cascade. We describe here the development of a mutant of human tissue factor (TF) as a specific antagonist of the extrinsic pathway of blood coagulation and the testing of this mutant in a rabbit model of arterial thrombosis. Alanine substitutions of Lys residues 165 and 166 in human TF have been shown previously to diminish the cofactor function of TF in support of factor X (FX) activation catalyzed by factor VIIa (FVIIa). The K165A:K166A mutations have been incorporated into soluble TF (sTF; residues 1-219) to generate the molecule "hTFAA." hTFAA binds FVIIa with kinetics and affinity equivalent to wild-type sTF, but the hTFAA x FVIIa complex shows a 34-fold reduction in catalytic efficiency for FX activation relative to the activity measured for sTF x FVIIa. hTFAA inhibits the activation of FX catalyzed by the complex formed between FVIIa and relipidated TF(1-243). hTFAA prolongs prothrombin time (PT) determined with human plasma and relipidated TF(1-243) or membrane bound TF, and has no effect on activated partial thromboplastin time, but is 70-fold less potent as an inhibitor of PT with rabbit plasma. The rabbit homologue of this mutant ("rTFAA") was produced and shown to have greater potency with rabbit plasma. Both hTFAA and rTFAA display an antithrombotic effect in a rabbit model of arterial thrombosis with rTFAA giving full efficacy at a lower dose than hTFAA. Compared to heparin doses of equal antithrombotic potential, hTFAA and rTFAA cause less bleeding as judged by measurements of the cuticle bleeding time. These results indicate that TF x FVIIa is a good target for the development of new anticoagulant drugs for the treatment of thrombotic disease.

Potent bifunctional anticoagulants: Kunitz domain-tissue factor fusion proteins.

A strategy to design potent antagonists of human coagulation factor VIIa (FVIIa) by linking two proteins that independently inhibit activity and bind at separate, nonoverlapping sites is presented. A bifunctional inhibitor (KDTF5), comprising a Kunitz-type domain engineered to inhibit the FVIIa active site and a soluble tissue factor (TF) variant that is defective as a cofactor for factor X (FX) activation, was developed from structure-based modeling of a ternary FVIIa-Kunitz domain-TF complex. KDTF5 inhibited FVIIa-dependent FX activation with a Ki* of 235 +/- 45 pM, a 193-fold and 398-fold increase in potency compared to the TF variant and Kunitz domain individually. Similarly, KDTF5 was a more potent anticoagulant in vitro compared to either inhibitory domain alone. The results demonstrate the harnessing of a macromolecular chelate effect by fusing two inhibitory ligands that bind a target at spatially distinct sites.

Solution structure of the E-domain of staphylococcal protein A.

The E-domain of staphylococcal protein A is one of five homologous IgG-binding domains designated E, D, A, B, and C that comprise the extracellular portion of protein A. The E-domain binds tightly to Fc fragments of IgG and binds certain Fv fragments with micromolar affinity. To explore further the structural features of Fc binding by protein A, and as a first step in developing a structural understanding of E-domain/Fv complex formation, we have determined the solution structure of the uncomplexed E-domain using 2D homonuclear and heteronuclear NMR spectroscopy. Complete 1H and 15N resonance assignments were obtained, and the structure was determined from 383 NOE-derived distance restrains, 34 phi and 19 chi 1 dihedral angle restraints, and 54 restraints for 27 H-bonds. 3JH alpha-H beta coupling constants and long-range NOEs involving Phe11 indicate the side chain exists in more than one conformation with differing chi 1 values. NOE restraints that were incompatible with chi 1 = -60 degrees were removed from one set of structure calculations, and those incompatible with chi 1 = 180 degrees were removed from a second set to allow Phe11 to explore both rotamer wells. Thus, two sets of 20 final structures, having no distance or dihedral angle restraint violations greater than 0.12 A or 1.6 degrees, respectively, represent the solution structure of the E-domain. Backbone atomic rms differences with respect to the mean coordinates for each set of 20 structures for residues 8-53 averaged 0.41 +/- 0.06 and 0.35 +/- 0.06 A. No significant differences in the overall structure result from the different orientations of Phe11. The solution structure of the E-domain consists of three alpha-helices that pack together to form a compact helical bundle. A detailed comparison between the E-domain ensembles and the previously determined structure for the B-domain in complex with Fc indicates that only the 180 degrees chi 1 rotamer of Phe11 is competent for binding; the -60 degrees chi 1 rotamer must reorient to 180 degrees to create a cavity that is filled by Ile253 from the CH2 domain of Fc in the Fc-bound complex.

Identification of a GDP-L-fucose:polypeptide fucosyltransferase and enzymatic addition of O-linked fucose to EGF domains.

An assay of GDP-fucose:polypeptide fucosyltransferase has been established. The enzyme catalyzes the reaction that attaches fucose through an O-glycosidic linkage to a conserved serine or threonine residue in EGF domains. The assay uses recombinant human factor VII EGF-1 domain as acceptor substrate and GDP-fucose as donor substrate. Synthetic peptides with sequences taken from five proteins previously shown to contain O-linked fucose (Harris and Spellman, 1993; Glycobiology, 3, 219-224) did not serve as efficient acceptor substrates. These synthetic peptides did not compromise complete EGF domains and did not contain all six cysteine residues that define the EGF structure. Therefore, the enzyme appears to require more than just a consensus primary sequence and likely requires that the EGF domain disulfide bonds be properly formed. The enzymatic reaction showed linear dependency of its activity on time, amount of enzyme, and substrates. Although the enzyme did not exhibit an absolute requirement for Mn2+, enzymatic activity did increase ten fold in the presence of 50 mM MnCl2. The in vitro glycosylation reaction resulted in complete conversion of the acceptor substrate to glycosylated product, and characterization of the purified product by electrospray mass spectrometry revealed that one fucose was added onto the polypeptide. Most of the enzymatic activity was found to be in the soluble fraction of CHO cell homogenates. However, when enzyme was prepared from rat liver in the presence of protease inhibitors, 37% of the activity was recovered by Triton X-100 extraction of the membrane particles after extensive aqueous washes. The result suggests that the enzyme is probably a membrane protein and, by analogy with other glycosyltransferases, probably has a 'stem' region that is very susceptible to proteolysis.

Structural and mutational analysis of affinity-inert contact residues at the growth hormone-receptor interface.

Mutational studies have shown that over two-thirds of the contact side chains at the human growth hormone (hGH)-receptor interface have little or no impact on binding affinity when converted to alanine [Cunningham, B. C., & Wells, J. A. (1993) J. Mol. Biol. 234, 554-563; Clackson, T., & Wells, J. A. (1995) Science 267. 383-386]. Herein, three of the most buried, yet functionally inert, residues on hGH (F25, Y42, and Q46) have been simultaneously mutated to alanine. Binding kinetics of the triple-alanine mutant shows that neither association nor dissociation rates are significantly affected and only slight, local disorder is seen in the crystal structure. However, large and compensating changes were observed in the enthalpy and entropy of binding as determined by isothermal titration calorimetry. The triple-alanine mutant bound with a more favorable enthalpy (delta H = -12.2 +/- 0.7 kcal/mol) and corresponding less favorable entropy [delta S = -2.3 +/- 2.4 cal/(mol.K)] compared to the wild-type interaction [delta H = -9.4 +/- 0.3 kcal/mol; delta S = 7.7 +/- 1.2 cal/(mol.K)]. Dissection of the triple-alanine mutant into the single F25A and double Y42A/Q46A mutant showed that the more favorable enthalpy was derived from the removal of the F25 side chain on helix-1 of the hormone. The delta Cp values for both the triple-alanine mutant [-927 +/- 10 cal/(mol.K)] and the individual mutants were significantly more negative than the delta Cp for the wild-type interaction [-767 +/- 34 cal/(mol.K)]. Such negative delta Cp values are consistent with the proposal that the hydrophobic effect is the primary contributor to the free energy of binding at this protein-protein interface. These results show that multiple-alanine mutations at contact residues may not affect binding kinetics, affinity, or global structure; however, they can produce local structural changes and can cause large compensating effects on the heat and entropy of binding. These studies emphasize that one cannot infer binding free energy from the existence of contacts alone and further support the notion that only a small set of contacts are crucial for the human growth hormone-receptor interaction.