Crystal structure of rhodopsin: a template for cone visual pigments and other G protein-coupled receptors.

The crystal structure of rhodopsin has provided the first three-dimensional molecular model for a G-protein-coupled receptor (GPCR). Alignment of the molecular model from the crystallographic structure with the helical axes seen in cryo-electron microscopic (cryo-EM) studies provides an opportunity to investigate the properties of the molecule as a function of orientation and location within the membrane. In addition, the structure provides a starting point for modeling and rational experimental approaches of the cone pigments, the GPCRs in cone cells responsible for color vision. Homology models of the cone pigments provide a means of understanding the roles of amino acid sequence differences that shift the absorption maximum of the retinal chromophore in the environments of different opsins.

Crystal structure of rhodopsin: A G protein-coupled receptor.

Heterotrimeric guanine nucleotide-binding protein (G protein)-coupled receptors (GPCRs) respond to a variety of different external stimuli and activate G proteins. GPCRs share many structural features, including a bundle of seven transmembrane alpha helices connected by six loops of varying lengths. We determined the structure of rhodopsin from diffraction data extending to 2.8 angstroms resolution. The highly organized structure in the extracellular region, including a conserved disulfide bridge, forms a basis for the arrangement of the seven-helix transmembrane motif. The ground-state chromophore, 11-cis-retinal, holds the transmembrane region of the protein in the inactive conformation. Interactions of the chromophore with a cluster of key residues determine the wavelength of the maximum absorption. Changes in these interactions among rhodopsins facilitate color discrimination. Identification of a set of residues that mediate interactions between the transmembrane helices and the cytoplasmic surface, where G-protein activation occurs, also suggests a possible structural change upon photoactivation.

Identification of the calcium binding site and a novel ytterbium site in blood coagulation factor XIII by x-ray crystallography.

The presence or absence of calcium determines the activation, activity, oligomerization, and stability of blood coagulation factor XIII. To explore these observed effects, we have determined the x-ray crystal structure of recombinant factor XIII A2 in the presence of calcium, strontium, and ytterbium. The main calcium binding site within each monomer involves the main chain oxygen atom of Ala-457, and also the side chains from residues Asn-436, Asp-438, Glu-485, and Glu-490. Calcium and strontium bind in the same location, while ytterbium binds several angstroms removed. A novel ytterbium binding site is also found at the dimer two-fold axis, near residues Asp-270 and Glu-272, and this site may be related to the reported inhibition by lanthanide metals (Achyuthan, K. E., Mary, A., and Greenberg, C. S. (1989) Biochem. J. 257, 331-338). The overall structure of ion-bound factor XIII is very similar to the previously determined crystal structures of factor XIII zymogen, likely due to the constraints of this monoclinic crystal form. We have merged the three independent sets of water molecules in the structures to determine which water molecules are conserved and possibly structurally significant.

Structural determinants of the bifunctional corn Hageman factor inhibitor: x-ray crystal structure at 1.95 A resolution.

Corn Hageman factor inhibitor (CHFI) is a bifunctional 127 residue, 13.6 kDa protein isolated from corn seeds. It inhibits mammalian trypsin and Factor XIIa (Hageman Factor) of the contact pathway of coagulation as well as alpha-amylases from several insect species. Among the plasma proteinases, CHFI specifically inhibits Factor XIIa without affecting the activity of other coagulation proteinases. We have isolated CHFI from corn and determined the crystallographic structure at 1.95 A resolution. Additionally, we have solved the structure of the recombinant protein produced in Escherichia coli at 2.2 A resolution. The two proteins are essentially identical. The proteinase binding loop is in the canonical conformation for proteinase inhibitors. In an effort to understand alpha-amylase inhibition by members of the family of 25 cereal trypsin/alpha-amylase inhibitors, we have made three-dimensional models of several proteins in the family based on the CHFI coordinates and the coordinates determined for wheat alpha-amylase inhibitor 0.19 [Oda, Y., Matsunaga, T., Fukuyama, K., Miyazaki, T., and Morimoto, T. (1997) Biochemistry 36, 13503-13511]. From an analysis of the models and a structure-based sequence analysis, we propose a testable hypothesis for the regions of these proteins which bind alpha-amylase. In the course of the investigations, we have found that the cereal trypsin/alpha-amylase inhibitor family is evolutionarily related to the family of nonspecific lipid-transfer proteins of plants. This is a new addition to the group which now consists of the trypsin/alpha-amylase inhibitors, 2S seed storage albumins, and the lipid-transfer family. Apparently, the four-helix conformation has been a successful vehicle in plant evolution for providing protection from predators, food for the embryo, and lipid transfer.

Coagulation factor XIIIa undergoes a conformational change evoked by glutamine substrate. Studies on kinetics of inhibition and binding of XIIIA by a cross-reacting antifibrinogen antibody.

Coagulation factor XIIIa, plasma transglutaminase (endo-gamma-glutamine:epsilon-lysine transferase EC 2.3.2.13) catalyzes isopeptide bond formation between glutamine and lysine residues and rapidly cross-links fibrin clots. A monoclonal antibody (5A2) directed to a fibrinogen Aalpha-chain segment 529-539 was previously observed from analysis of end-stage plasma clots to block fibrin alpha-chain cross-linking. This prompted the study of its effect on nonfibrinogen substrates, with the prospect that 5A2 was inhibiting XIIIa directly. It inhibited XIIIa-catalyzed incorporation of the amine donor substrate dansylcadaverine into the glutamine acceptor dimethylcasein in an uncompetitive manner with respect to dimethylcasein utilization and competitively with respect to dansylcadaverine. Uncompetitive inhibition was also observed with the synthetic glutamine substrate, LGPGQSKVIG. Theoretically, uncompetitive inhibition arises from preferential interaction of the inhibitor with the enzyme-substrate complex but is also found to inhibit gamma-chain cross-linking. The conjunction of the uncompetitive and competitive modes of inhibition indicates in theory that this bireactant system involves an ordered reaction in which docking of the glutamine substrate precedes the amine exchange. The presence of substrate enhanced binding of 5A2 to XIIIa, an interaction deemed to occur through a C-terminal segment of the XIIIa A-chain (643-658, GSDMTVTVQFTNPLKE), 55% of which comprises sequences occurring in the fibrinogen epitope Aalpha-(529-540) (GSESGIFTNTKE). Removal of the C-terminal domain from XIIIa abolishes the inhibitory effect of 5A2 on activity. Crystallographic studies on recombinant XIIIa place the segment 643-658 in the region of the groove through which glutamine substrates access the active site and have predicted that for catalysis, a conformational change may accompany glutamine-substrate binding. The uncompetitive inhibition and the substrate-dependent binding of 5A2 provide evidence for the conformational change.

Transglutaminase 1 mutations in autosomal recessive congenital ichthyosis: private and recurrent mutations in an isolated population.

Autosomal recessive congenital ichthyosis (ARCI) is a rare, heterogenous keratinization disorder of the skin, classically divided into two clinical subtypes, lamellar ichthyosis (LI) and nonbullous congenital ichthyosiformis erythroderma (CIE). Recently, strong evidence for the involvement of the transglutaminase 1 gene (TGM1) in LI has evolved. We have studied ARCI in the isolated Finnish population, in which recessive disorders are often caused by single mutations enriched by a founder effect. Surprisingly, five different mutations of TGM1 (Arg141His, Arg142Cys, Gly217Ser, Val378Leu, and Arg395Leu) were found in Finnish ARCI patients. In addition to affected LI patients, we also identified TGM1 mutations in CIE patients. Moreover, haplotype analysis of the chromosomes carrying the most common mutation, a C-->T transition changing Arg142 to Cys, revealed that the same mutation has been introduced twice in the Finnish population. In addition to this Arg142Cys mutation, three other mutations, in Arg141 and Arg142, have been described elsewhere, in other populations. These findings suggest that this region of TGM1 is more susceptible to mutation. The corresponding amino acid sequence is conserved in other transglutaminases, but, for example, coagulation factor XIII (FXIII) mutations do not cluster in this region. Protein modeling of the Arg142Cys mutation suggested disruption or destabilization of the protein. In transfection studies, the closely related transglutaminase FXIII protein with the corresponding mutation was shown to be susceptible to degradation in COS cells, further supporting evidence of the destabilizing effect of the Arg142Cys mutation in TGM1.

The core domain of the tissue transglutaminase Gh hydrolyzes GTP and ATP.

Tissue transglutaminase (TGase II) catalyzes the posttranslational modification of proteins by transamidation of available glutamine residues and is also a guanosinetriphosphatase (GTPase) and adenosinetriphosphatase (ATPase). Based on its homology with factor XIIIA, an extracellular transglutaminase, the structure of TGase II is likely composed of an N-terminal beta-sandwich domain, an alpha/beta catalytic core, and two C-terminally located beta-barrels. Here we used a domain-deletion approach to identify the GTP and ATP hydrolytic domains of TGase II. Full-length TGase II and two domain-deletion mutants, one retaining the N-terminal beta-sandwich and core domains (betaSCore) and the other retaining only the core domain, were expressed as glutathione S-transferase (GST) fusion proteins and purified. GST-Full and GST-betaSCore exhibited calcium-dependent TGase activity, whereas GST-Core had no detectable TGase activity, indicating the beta-sandwich domain is required for TGase activity but the C-terminal beta-barrels are not. All three GST-TGase II fusion proteins were photoaffinity-labeled with [alpha-32P]-8-azidoGTP and were able to bind GTP-agarose. The GTPase activity of GST-betaSCore was equivalent to that of GST-Full, whereas the ATPase activity was approximately 40% higher than GST-Full. GST-Core had approximately 50% higher GTPase activity and approximately 75% higher ATPase activity than GST-Full. The GTPase and ATPase activities of each of the GST-TGase II fusion proteins were inhibited in a dose-dependent manner by both GTPgammaS and ATPgammaS. These results demonstrate that the GTP and ATP hydrolysis sites are localized within the core domain of TGase II and that neither the N-terminal beta-sandwich domain nor the C-terminal beta-barrels are required for either GTP or ATP hydrolysis. Taken together with previous work [Singh, U. S., Erickson, J. W., & Cerione, R. A. (1995) Biochemistry 34, 15863-15871; Lai, T.-S., Slaughter, T. F., Koropchak, C. M., Haroon, Z. A., & Greenberg, C. S. (1996) J. Biol. Chem. 271, 31191-31195] the results of this study indicate that the GTP and ATP hydrolysis sites are localized to a 5. 5 kDa (47 amino acid) region at the start of the core domain.

Crosslinking kinetics of the human transglutaminase, factor XIII[A2], acting on fibrin gels and gamma-chain peptides.

Factor XIII is the terminal enzyme of the coagulation cascade which serves to rapidly crosslink the adjacent gamma-chain C-termini of fibrin clots. In vivo, this process is initiated by the proteolytic action of thrombin which simultaneously converts both soluble fibrinogen to fibrin and activates zymogen FXIII; fibrin then spontaneously polymerizes to form a gel which activated FXIII stabilizes through crosslinking. Due to the kinetic complexity and the difficulty of investigating gel phase reactions, methods employing pre-activation of recombinant human Factor XIII (rFXIII[A'2]) were developed to effectively decouple these reactions. By utilizing these methods, the kinetic parameters of gamma-chain crosslinking in fibrin gels could be determined by both initial rate and integrated rate techniques under physiologically relevant conditions. The crosslinking of the gamma-chain of fibrin gels could be described by apparent Michaelis kinetics with K(m)(app) = 6.2 microM, kcat = 1872 min-1, and Ksp = 302 min-1 microM-1 for a fibrin gamma-chain monomer of M(r) = 170000 Da. In contrast, both the crosslinking rates of alpha-chains within fibrin gels (Ksp = 0.38 min-1 microM-1: Bishop et al. (1993)) and the crosslinking of a soluble synthetic peptide containing the unique gamma-chain fibrin crosslinking site (Ksp = 0.030 min-1 microM-1) could not be shown to saturate and gave apparent first-order rates with respect to rFXIII[A'2]. These observations coupled with the large differences in the turnover rates (approximately 10(4)) suggest two likely mechanisms for FXIII[A'2]-substrate interactions: (1) random (or independent) binding of non- or weakly interacting substrate pairs imposes a high entropic barrier (i. e., delta Gbinding) to the formation of a productive catalytic complex, e.g., for soluble gamma-chain peptides and the flexible alpha-chains within fibrin, and (2) binding to an oriented substrate pair effectively lowers the entropic barrier to formation of a Michaelis complex and thus greatly enhances the rate of catalysis, e.g., for gamma-chain pairs within the fibrin fibrils.

Crystal structure of a 30 kDa C-terminal fragment from the gamma chain of human fibrinogen.

BACKGROUND: Blood coagulation occurs by a cascade of zymogen activation resulting from minor proteolysis. The final stage of coagulation involves thrombin generation and limited proteolysis of fibrinogen to give spontaneously polymerizing fibrin. The resulting fibrin network is covalently crosslinked by factor XIIIa to yield a stable blood clot. Fibrinogen is a 340 kDa glycoprotein composed of six polypeptide chains, (alphabetagamma)2, held together by 29 disulfide bonds. The globular C terminus of the gamma chain contains a fibrin-polymerization surface, the principal factor XIIIa crosslinking site, the platelet receptor recognition site, and a calcium-binding site. Structural information on this domain should thus prove helpful in understanding clot formation. RESULTS: The X-ray crystallographic structure of the 30 kDa globular C terminus of the gamma chain of human fibrinogen has been determined in one crystal form using multiple isomorphous replacement methods. The refined coordinates were used to solve the structure in two more crystal forms by molecular replacement; the crystal structures have been refined against diffraction data to either 2.5 A or 2.1 A resolution. Three domains were identified in the structure, including a C-terminal fibrin-polymerization domain (P), which contains a single calcium-binding site and a deep binding pocket that provides the polymerization surface. The overall structure has a pronounced dipole moment, and the C-terminal residues appear highly flexible. CONCLUSIONS: The polymerization domain in the gamma chain is the most variable among a family of fibrinogen-related proteins and contains many acidic residues. These residues contribute to the molecular dipole moment in the structure, which may allow electrostatic steering to guide the alignment of fibrin monomers during the polymerization process. The flexibility of the C-terminal residues, which contain one of the factor XIIIa crosslinking sites and the platelet receptor recognition site, may be important in the function of this domain.

Anatomy of a rhinoplasty: emphasis on the middle third of the nose.

The nose is an organ that serves many functions. These functions are intimately involved in an organ that occupies a very aesthetically prominent position on the face. A thorough knowledge of the anatomy is of the utmost importance for surgeons attempting to preserve or improve the functional capability and the aesthetic appearance of the nose. Nasal anatomy is extremely complex with a myriad of different three-dimensional variances. The middle third of the nose has largely been overlooked in its importance. The components of this portions of the nose consist of the paired upper lateral cartilages, the dorsal aspect of the septum, and the scroll of the upper lateral cartilages upon the lower lateral cartilages. This area is of key importance to the nasal valve area and can have a major impact on the functional capabilities of the nose. A description of the confluence of the flare of the septum to the upper lateral cartilages is necessary for an understanding of changes that may occur during rhinoplastic operations. A knowledge of the anatomy of the middle third of the nose may prevent nasal valve collapse, a pinched appearance of this portion of the nose, or an aesthetically unappealing appearance.

Four novel mutations in deficiency of coagulation factor XIII: consequences to expression and structure of the A-subunit.

The characterization of naturally occurring mutations is one way to approach functionally significant domains of polypeptides. About 10 mutations have been reported in factor XIII (FXIII) A-subunit deficiency, but very little is known about the effects of the mutations on the expression or the structure of this enzyme. In this study, the recent crystallization of FXIII A-subunit and determination of the three-dimensional model were used for the first time to pursue the structural consequences of mutations in the A-subunit. The molecular analysis of four families from Sweden, Germany, and Denmark revealed four previously unreported point mutations. Three of the mutations were missense mutations, Arg326-->Gln, Arg252-->Ile, and Leu498-->Pro, and one was a nonsense mutation, a deletion of thymidine in codon for Phe8 resulting in early frameshift and premature termination of the polypeptide chain. In the case of the nonsense mutation, delT Phe8, the steady-state mRNA level of FXIII A-subunit was reduced, as quantitated by reverse transcriptase-polymerase chain reaction and solid-phase minisequencing. In contrast, none of the missense mutations affected mRNA levels, indicating the possible translation of the mutant polypeptides. However, by enzyme-linked immunosorbent analysis and immunofluorescence, all the patients demonstrated a complete lack of detectable factor XIIIA antigen in their platelets. In the structural analysis, we included the mutations described in this work and the Met242-->Thr mutation reported earlier by us. Interestingly, in the three-dimensional model, all four missense mutations are localized in the evolutionarily conserved catalytic core domain. The substitutions are at least 15 A away from the catalytic cleft and do not affect any of the residues known to be directly involved in the enzymatic reaction. The structural analyses suggest that the mutations are most likely interfering with proper folding and stability of the protein, which is in agreement with the observed absence of detectable FXIIIA antigen. Arg326, Arg252, and Met242 are all buried within the molecule. The Arg326-->Gln and Arg252-->Ile mutations are substitutions of smaller, neutral amino acids for large, charged residues. They disrupt the electrostatic balance and hydrogen-bonding interactions in structurally significant areas. The Met242-->Thr mutation is located in the same region of the core domain as the Arg252-->Ile site and is expected to have a destabilizing effect due to an introduction of a smaller, polar residue in a tightly packed hydrophobic pocket. The substitution of proline for Leu498 is predicted to cause unfavorable interatomic contacts and a disruption of the alpha-helix mainchain hydrogen-bonding pattern; it is likely to form a kink in the helix next to the dimer interface and is expected to impair proper dimerization of the A-subunits. In the case of all four missense mutations studied, the knowledge achieved from the three-dimensional model of crystallized FXIII A-subunit provides essential information about the structural significance of the specific residues and aids in understanding the biologic consequences of the mutations observed at the cellular level.

Structure and function studies of factor XIIIa by x-ray crystallography.

The three-dimensional structures of several forms of the factor XIII A subunit have been determined using single crystal x-ray diffraction methods. Our crystallographic studies have provided the first detailed structural view of the factor XIII A subunit and information that is useful for understanding transglutaminase function. We have identified a conserved Cys314-His373-Asp396 catalytic triad of residues in the active site of the molecule and a number of other conserved residues that may play important roles as well. The calcium and strontium structures have revealed several conserved acidic residues (Asp438, Glu485, and Glu490) involved in ion binding. We have also been able to use our crystal structures as scaffolds to model the possible structural effects of missense mutations that have been identified in factor XIII-deficient patients.

Structural evidence that the activation peptide is not released upon thrombin cleavage of factor XIII.

The three-dimensional structure of the recombinant human factor XIII a2 dimer after cleavage by thrombin has been determined by X-ray crystallography. Factor XIII zymogen was treated with bovine alpha-thrombin in the presence of 3 mM CaCl2, and the cleaved protein was crystallized from Tris buffered at pH 6.5 using ethanol as the precipitating agent. Refinement of the molecular model of thrombin-cleaved factor XIII against diffraction data from 10.0 to 2.5 A resolution has been carried out to give a crystallographic R factor of 18.2%. The structure of thrombin-cleaved factor XIII is remarkably similar to that of the zymogen: there are no large conformational changes in the protein and the 37 residue amino terminus activation peptide remains associated with the rest of the molecule. This work shows that the activation peptide, upon thrombin cleavage, has the same conformation and occupies the same position with respect to the rest of the molecule as it does in the zymogen structure.

Domain structure, stability and domain-domain interactions in recombinant factor XIII.

The process of heat denaturation of recombinant factor XIII (rFXIII), as well as its C-terminal 24 kDA and 12 kDa elastase-produced fragments starting at Ser514 and Thr628, respectively, was investigated in a wide range of conditions by fluorescence, CD and differential scanning calorimetry (DSC). It was found that the intact protein melts in two distinct temperature regions reflecting unfolding of different parts of the molecule with different stability. The less stable structures unfold in a low temperature transition with a tm of 69 degrees C or lower depending on conditions. Unfolding of the more stable structures was observed at extremely high temperatures, tm > 110 degrees C at acidic pH < 3.5 and tm = 90 degrees C at pH 8.6 with 2 M GdmCL. Thermodynamic analysis of the low and high temperature DSC-obtained heat absorption peaks indicated unambiguously that the first represents melting of three thermolabile independently folded domains while two thermostable domains melt in the second one giving a total of five domains in each a subunit of rFXIII. Both 24 kDa and 12 kDa fragments exhibited a sigmoidal spectral transition at comparatively high temperature where the thermolabile structures are already denatured, indicating that two thermostable domains are formed by the C-terminal portion of rFXIII and correspond to the two beta-barrels revealed by crystallography. The remaining 56 kDa portion forms three thermolabile domains, one of which corresponds to the N-terminal beta-sandwich and the other two to the catalytic core. Fast accessible surface calculations of the X-ray model of rFXIII confirmed the presence of two structural subdomains in the core region with the boundary at residue 332. The thermolabile domains appear to interact with each other intra- and/or intermolecularly resulting in dimerization the a subunits. At acidic pH, where all domains became destabilized but still remained folded, interdomainial interactions seemed to be abolished, resulting in the reversible dissociation of the dimer as revealed by ultracentrifugation analysis.

Transglutaminase factor XIII uses proteinase-like catalytic triad to crosslink macromolecules.

The X-ray crystal structure of human transglutaminase factor XIII has revealed a cysteine proteinase-like active site involved in a crosslinking reaction and not proteolysis. This is among the first observations of similar active sites in 2 different enzyme families catalyzing a similar reaction in opposite directions. Although the size and overall protein fold of factor XIII and the cysteine proteinases are quite different, the active site and the surrounding protein structure share structural features suggesting a common evolutionary lineage. Here we present a description of the residues in the active site and the structural evidence that the catalytic mechanism of the transglutaminases is similar to the reverse mechanism of the cysteine proteinases.

Three-dimensional structure of a transglutaminase: human blood coagulation factor XIII.

Mechanical stability in many biological materials is provided by the crosslinking of large structural proteins with gamma-glutamyl-epsilon-lysyl amide bonds. The three-dimensional structure of human recombinant factor XIII (EC 2.3.2.13 zymogen; protein-glutamine:amine gamma-glutamyltransferase a chain), a transglutaminase zymogen, has been solved at 2.8-A resolution by x-ray crystallography. This structure shows that each chain of the homodimeric protein is folded into four sequential domains. A catalytic triad reminiscent of that observed in cysteine proteases has been identified in the core domain. The amino-terminal activation peptide of each subunit crosses the dimer interface and partially occludes the opening of the catalytic cavity in the second subunit, preventing substrate binding to the zymogen. A proposal for the mechanism of activation by thrombin and calcium is made that details the structural events leading to active factor XIIIa'.

The corn inhibitor of blood coagulation factor XIIa. Crystallization and preliminary crystallographic analysis.

A 13.6 kDa protein from corn seeds is known to be a highly selective inhibitor of human blood coagulation Factor XIIa (or activated Hageman factor). We have crystallized this inhibitor at 23 degrees C and pH 7.5 from a solution of 30% polyethylene glycol 400, 0.2 M MgCl2, and 0.1 M Hepes. The crystals diffract to at least 2.1 A resolution. The space group is P4(2)2(1)2 with a = b = 57.15 A and c = 80.5 A. The crystals contain 51% solvent. Two heavy atom derivatives have been identified.