Crystallization and preliminary crystallographic data of chicken gizzard G-actin . DNase I complex and Physarum G-actin . DNase I complex.

Smooth muscle G-actin from chicken gizzard and Physarum plasmodium G-actin both interact with DNase I and form 1 : 1 complexes. These complexes were crystallized by using polyethylene glycol 6000 as a precipitant. Both crystals belong to the same orthorhombic space group P2(1)2(1)2(1). The cell dimensions of chicken gizzard G-actin.DNase I complex are a=42.00 +/- 0.07 A, b=225.3 +/- 0.4 A, and c=77.4 +/- 0.1 A, while those of Physarum G-actin.DNase I complex are a=42 A, b=221 A, and c=77 A.     

X-ray diffraction photographs of chicken gizzard G-actin.DNase I complex crystals taken with synchrotron radiation

X-ray diffraction photographs of a chicken gizzard G-actin.DNase I complex crystal have been recorded using the synchrotron radiation beam emitted by the Synchrotron Radiation Source at Daresbury and the Photon Factory at Tsukuba. The resolution limit was extended to 2.4 A and the exposure time was reduced approximately by a factor of 10, when data recorded at the Photon Factory, were compared with those recorded with a conventional rotating-anode source. Using a newly designed Weissenberg camera equipped with a multi-layer line screen, the diffraction data in a 36 degrees oscillation range were recorded on a single film up to 3.5 A resolution.     

Crystallographic refinement and structure of DNase I at 2 A resolution

The structure of bovine pancreatic deoxyribonuclease I (DNase I) has been refined at 2 A resolution using the restrained parameter, reciprocal least-squares procedure of Hendrickson and Konnert. The conventional R-factor for 16,104 reflections with I greater than or equal to 3 sigma (I) from 6.0 to 2.0 A resolution is 0.157. Bond lengths and angles of the refined structure are close to ideal values with root-mean-square (r.m.s.) deviations of 0.023 A and 1.4 degrees, respectively. The r.m.s. deviation of short non-bonded contacts from the sum of van der Waals' radii is 0.18 A. The orientation of side-chains shows a clear trimodal distribution of chi 1-angles at -60 degrees, 180 degrees, 60 degrees (in the order of preference) corresponding to staggered conformations. The chemically determined sequence was corrected at four positions, the major correction being an insertion of the tripeptide Ile-Val-Arg between Arg27 and Arg28. Extended hydrophobic regions in between, and on either side of, the two central six-stranded beta-pleated sheets are mainly responsible for the low average isotropic temperature factor of 11.9 A2 for the 2033 protein atoms. Besides the flexible loop region between Gly97 and Gly102 (Glu99 and Ser100 are disordered) and the carbohydrate side-chain, which both extend into a large solvent channel, only the exposed loop Arg70 to Lys74 shows elevated thermal mobility. The longest of the eight helices in DNase I, together representing 26% of the structure, has a 22 degree kink and consists of two alpha-helical segments (residues 136 to 144 and 145 to 155) separated by a 3(10)-helical turn. DNase I fragments 1 to 120 and 121 to 257 can be superimposed by an approximate 2-fold axis (r.m.s. deviation 1.49 A for 61 equivalent C alpha positions), suggesting that the enzyme might be the result of gene duplication. The two Ca2+ bound to DNase I under crystallization conditions are important for its structural integrity by stabilizing the surface loop Asp198 to Thr204 and limiting the region of high thermal mobility in the flexible loop to residues Gly97 to Gly102. The N-linked carbohydrate side-chain attached to Asn18 is of the high-mannose type with a branching point at the mannose residue in position 3.(ABSTRACT TRUNCATED AT 400 WORDS)     

Three-dimensional structure of the complex of actin and DNase I at 4.5 A resolution.

The shape of an actin subunit has been derived from an improved 6 A map of the complex of rabbit skeletal muscle actin and bovine pancreatic DNase I obtained by X-ray crystallographic methods. The three-dimensional structure of DNase I determined independently at 2.5 A resolution was compared with the DNase I electron density in the actin:DNase map. The two structures are very similar at 6 A resolution thus leading to an unambiguous identification of actin as well as DNase I electron density. Furthermore the correct hand of the actin structure is determined from the DNase I atomic structure. The resolution of the actin structure was extended to 4.5 A by using a single heavy-atom derivative and the knowledge of the atomic coordinates of DNase I. The dimensions of an actin subunit are 67 A X 40 A X 37 A. It consists of a small and a large domain, the small domain containing the N terminus. Actin is an alpha,beta-protein with a beta-pleated sheet in each domain. These sheets are surrounded by several alpha-helices, comprising at least 40% of the structure. The phosphate peak of the adenine nucleotide is located between the two domains. The complex of actin and DNase I as found in solution (i.e., the actin:DNase I contacts which do not depend on crystal packing) was deduced from a comparison of monoclinic with orthorhombic crystals. Residues 44-46, 51, 52, 60-62 of DNase I are close to a loop region in the small domain of actin. At a distance of approximately 15 A there is a second contact in the large domain in which Glu13 of DNase I is involved. A possible binding region for myosin is discussed.     

Three-dimensional structure of bovine pancreatic DNase I at 2.5 A resolution

The three-dimensional structure of bovine pancreatic deoxyribonuclease I (DNase I) has been determined at 2.5 A resolution by X-ray diffraction from single crystals. An atomic model was fitted into the electron density using a graphics display system. DNase I is an alpha, beta-protein with two 6-stranded beta-pleated sheets packed against each other forming the core of a 'sandwich'-type structure. The two predominantly anti-parallel beta-sheets are flanked by three longer alpha-helices and extensive loop regions. The carbohydrate side chain attached to Asn 18 is protruding by approximately 15 A from the otherwise compact molecule of approximate dimensions 45 A X 40 A. The binding site of CA2+-deoxythymidine-3',5'-biphosphate (Ca-pdTp) has been determined by difference Fourier techniques confirming biochemical results that the active centre is close to His 131. Ca-pdTp binds at the surface of the enzyme between the two beta-pleated sheets and seems to interact with several charged amino acid side chains. Active site geometry and folding pattern of DNase I are quite different from staphylococcal nuclease, the only other Ca2+-dependent deoxyribonuclease whose structure is known at high resolution. The electron density map indicates that two Ca2+ ions are bound to the enzyme under crystallization conditions.     

Crystallographic structure of metal-free concanavalin A at 2.5 Å resolution

The three-dimensional structure of demetallized concanavalin A has been determined at 2.5 Å resolution and refined to a crystallographic R-factor of 18%. The lectin activity of concanavalin A requires the binding of both a transition metal ion, generally Mn²⁺, and a Ca²⁺ ion in two neighboring sites in close proximity to the carbohydrate binding site. Large structural differences between the native and the metal-free lectin are observed in the metal-binding region and consequently for the residues involved in the specific binding of saccharides. The demetallization invokes a series of conformational changes in the protein backbone, apparently initiated mainly by the loss of the calcium ion. Most of the Mn²⁺ ligands retain their position, but the Ca²⁺ binding site is destroyed. The Ala207-Asp208 peptide bond, in the β-strand neighboring the metal-binding sites, undergoes a cis to trans isomerization. The cis conformation for this bond is a highly conserved feature among the leguminous lectins and is critically maintained by the Ca²⁺ ion in metal-bound concanavalin A. A further and major change adjacent to the isomerized bond is an expansion of the loop containing the monosaccharide ligand residues Leu99 and Tyr100. The dispersion of the ligand residues for the monosaccharide binding site (Asn14, Agr228, Asp208, Leu99, and Tyr100) in metalfree concanavalin A abolishes the lectin's ability to bind saccharides. Since the quaternary structure of legume lectins is essential to their biological role, the tetramer formation was analyzed. In the crystal (pH 5), the metal-free concanavalin A dimers associate into a tetramer that is similar to the native one, but with a drastically reduced number of inter-dimer interactions. This explains the tetramer dissociation into dimers below pH values of 6.5. © 1995 Wiley-Liss, Inc.     

Limited proteolysis of chicken gizzard 5'-nucleotidase.

Chicken gizzard 5'-nucleotidase represents an ectoenzyme which is linked to the plasma membrane via a phosphatidylinositol glycan. We have characterized the possible domain-like organization of 5'-nucleotidase by limited proteolysis. A hydrophobic proteolytic fragment carrying the intact C-terminus, as well as two major hydrophilic products, were identified. We developed procedures for specific radiolabelling of the active center of 5'-nucleotidase. This allowed us to locate the catalytic site within hydrophilic fragments obtained after limited proteolysis. We demonstrate that removal of N-linked carbohydrate chains increases the sensitivity of 5'-nucleotidase to proteolytic attack, indicating that sugar moieties protect against proteolysis. 5'-Nucleotidase represents a binding protein for components of the extracellular matrix. The interaction between 5'-nucleotidase and the laminin/nidogen complex unmasked proteolytic cleavage sites in the C-terminal portion of the enzyme. This resulted in the specific production of a hydrophilic form of 5'-nucleotidase. In summary, we have further characterized chicken gizzard 5'-nucleotidase: (1) the protein is organized into two domain-like structures, (2) the N-terminal domain harbors the active center; (3) N-linked carbohydrates protect the protein against proteolytic degradation; (4) interaction with components of the extracellular matrix alters the conformation of 5'-nucleotidase.     

X-ray structure of the DNase I-d(GGTATACC)2 complex at 2.3 A resolution.

The crystal structure of a complex between DNase I and the self-complementary octamer duplex d(GGTATACC)2 has been solved using the molecular replacement method and refined to a crystallographic R-factor of 18.8% for all data between 6.0 and 2.3 A resolution. In contrast to the structure of the DNase I-d(GCGATCGC)2 complex solved previously, the DNA remains uncleaved in the crystal. The general architecture of the two complexes is highly similar. DNase I binds in the minor groove of a right-handed DNA duplex, and to the phosphate backbones on either side over five base-pairs, resulting in a widening of the minor groove and a concurrent bend of the DNA away from the bound enzyme. There is very little change in the structure of the DNase I on binding the substrate. Many other features of the interaction are conserved in the two complexes, in particular the stacking of a deoxyribose group of the DNA onto the side-chain of a tyrosine residue (Y76), which affects the DNA conformation and the binding of an arginine side-chain in the minor groove. Although the structures of the DNA molecules appear at first sight rather similar, detailed analysis reveals some differences that may explain the relative resistance of the d(GGTATACC)2 duplex to cleavage by DNase I: whilst some backbone parameters are characteristic of a B-conformation, the spatial orientation of the base-pairs in the d(GGTATACC)2 duplex is close to that generally observed in A-DNA. These results further support the hypothesis that the minor-groove width and depth and the intrinsic flexibility of DNA are the most important parameters affecting the interaction. The disposition of residues around the scissile phosphate group suggests that two histidine residues, H134 and H252, are involved in catalysis.     

Crystallographic studies of a calcium binding lysozyme from equine milk at 2.5 A resolution.

The crystal structure of a calcium binding equine lysozyme has been determined at 2.5 A resolution by means of molecular replacement. The energy minimized equine lysozyme as the starting model, was refined with the molecular dynamics program, X-PLOR, and the R factor of the current model was found to be 24% without any water molecules. The conformation of the calcium binding loop is similar to that of alpha-lactalbumin. The profiles of backbone atomic displacements throughout the lysozyme and alpha-lactalbumin superfamilies are comparable as well as their homologous tertiary structures.     

Crystallographic structure of allosterically inhibited phosphofructokinase at 7 A resolution

The structure of the allosterically inhibited form of phosphofructokinase from Bacillus stearothermophilus has been determined by X-ray crystallography to 7 A resolution by molecular replacement using the known structure of the active state as a starting model. Comparing the inhibited state with the active state, the tetramer is twisted about its long axis such that one pair of subunits in the tetramer rotates relative to the other pair by about 8 degrees around one of the molecular dyad axes. This rotation partly closes the binding site for the co-operative substrate fructose-6-phosphate, explaining its weaker binding to this conformational state. Within the subunit, one domain rotates relative to the other by 4.5 degrees, which further closes the fructose-6-phosphate site, without closing the cleft between the domains of the same subunit: this motion causes little change to the catalytic site. This T-state model is consistent with the simple allosteric kinetic scheme in which the active and the inhibited conformations differ in their affinities for fructose-6-phosphate, but not in their catalytic rates. It does not explain the heterotropic allosteric effects.     

Covalent modification of G-actin by pyridoxal 5'-phosphate: polymerization properties and interaction with DNase I and myosin subfragment 1.

Pyridoxal 5'-phosphate (PLP), a lysine-specific reagent, has been used to modify G-actin. At pH 7.5, PLP reacted with 1.7-2 lysines on G-actin. Limited proteolytic digestion experiments indicated that, in agreement with previous works, essentially lysine-61 was modified in a 1:1 fashion by PLP, other lysines being much less reactive. A PLP-derivatized affinity label of ATP binding sites, AMPPLP, reacted with two additional lysines that do not appear to be located in the ATP site on G-actin. PLP-G-actin did not polymerize spontaneously up to 30 microM; however, it retained other essential native properties of G-actin. PLP-actin bound to the barbed ends of actin filaments with an equilibrium dissociation constant of 4 microM and prevented dilution-induced depolymerization like a capping protein. PLP-actin copolymerized with unmodified actin. The stability of F-actin copolymers decreased with the fraction of PLP-actin incorporated, consistent with a model within which the actin-PLP-actin interactions in the copolymer are 50-fold weaker, and PLP-actin-PLP-actin interactions are 200-fold weaker than regular actin-actin interactions. PLP-actin bound DNase I with an equilibrium association constant of 2 nM-1, i.e., 10-fold lower than that of unmodified actin. PLP modification did not affect the binding of G-actin to myosin subfragment 1. However, polymerization of PLP-actin by myosin subfragment 1 was not observed in low ionic strength buffers, whereas PLP-F-actin-S1 filaments, in which the stoichiometry PLP-actin:S1 is 1:1, were formed with an apparent critical concentration of 4.5 microM in the presence of 0.1 M KCl.     

Aplysia limacina myoglobin. Crystallographic analysis at 1.6 A resolution

The crystal structure of the ferric form of myoglobin from the mollusc Aplysia limacina has been refined at 1.6 A resolution, by restrained crystallographic refinement methods. The crystallographic R-factor is 0.19. The tertiary structure of the molecule conforms to the common globin fold, consisting of eight alpha-helices. The N-terminal helix A and helix G deviate significantly from linearity. The distal residue is recognized as Val63 (E7), which, however, does not contact the heme directly. Moreover the sixth (distal) co-ordination position of heme iron is not occupied by a water molecule at neutrality, i.e. below the acid-alkaline transition point of A. limacina myoglobin. The heme group sits in its crevice in the conventional orientation and no signs of heme isomerism are evident. The iron atom is 0.26 A out of the porphyrin plane, with a mean Fe-N (porphyrin) distance of 2.01 A. The co-ordination bond to the proximal histidine has a length of 2.05 A, and forms an angle of 4 degrees with the heme normal. A plane containing the imidazole ring of the proximal His intersects the heme at an angle of 29 degrees with the (porphyrin) 4N-2N direction. Inspection of the structure of pH 9.0 indicates that a hydroxyl ion is bound to the Fe sixth co-ordination position.     

Crystallographic refinement of the three-dimensional structure of the FabD1.3-lysozyme complex at 2.5-A resolution.

The three-dimensional crystal structure of the complex between the Fab from the monoclonal anti-lysozyme antibody D1.3 and the antigen, hen egg white lysozyme, has been refined by crystallographic techniques using x-ray intensity data to 2.5-A resolution. The antibody contacts the antigen with residues from all its complementarity determining regions. Antigen residues 18-27 and 117-125 form a discontinuous antigenic determinant making hydrogen bonds and van der Waals interactions with the antibody. Water molecules at or near the antigen-antibody interface mediate some contacts between antigen and antibody. The fine specificity of antibody D1.3, which does not bind (K alpha less than 10(5) M-1) avian lysozymes where Gln121 in the amino acid sequence is occupied by His, can be explained on the basis of the refined model.     

Crystallographic structure of PNP from Mycobacterium tuberculosis at 1.9A resolution

Even being a bacterial purine nucleoside phosphorylase (PNP), which normally shows hexameric folding, the Mycobacterium tuberculosis PNP (MtPNP) resembles the mammalian trimeric structure. The crystal structure of the MtPNP apoenzyme was solved at 1.9 A resolution. The present work describes the first structure of MtPNP in complex with phosphate. In order to develop new insights into the rational drug design, conformational changes were profoundly analyzed and discussed. Comparisons over the binding sites were specially studied to improve the discussion about the selectivity of potential new drugs.     

Crystallographic structure of Rhodospirillum molischianum ferricytochrome c' at 2.5 A resolution

This paper describes the 2.5 Å crystallographic structure determination of ferricytochrome c′ from the photosynthetic bacterium Rhodospirillum molischianum. The molecule is a symmetric dimer, with each 128-residue polypeptide chain incorporating a covalently bound protoheme IX prosthetic group. The monomer is structurally organized as an array of four nearly parallel α-helices, which pack most closely at one end and thereafter spatially diverge to accommodate the heme prosthetic group. Although local features of the heme attachment pattern resemble those seen in cytochrome c, the heme iron in cytochrome c′ is pentaco-ordinate with a solvent-exposed histidine residue furnishing the single axial ligand to the heme iron.Subunit association in the dimeric molecule is principally stabilized by helix interactions, which are qualitatively similar to those occurring within each monomer. These interactions result in a dimer geometry that situates the exposed regions of both hemes on the same molecular surface.The structural basis for some of the physiochemical properties cytochrome c′ are examined and compared to those of other heme proteins of known structure.     

A 130K protein from chicken gizzard: Its localization at the termini of microfilament bundles in cultured chicken cells

A protein with a molecular weight of 130,000 (130K protein) was extracted from chicken gizzard and purified to homogeneity by ammonium sulfate fractionation and ion-exchange chromatography. Antibodies prepared against the pure protein were used for its immunochemical characterization and immunofluorescent visualization in cultured chicken cells. Both peptide mapping and immunochemical analysis indicated that the 130K protein is not related either structurally or antigenically to other mechanochemical proteins, including α-actinin, actin, myosin, tropomyosin, filamin and tubulin. Immunofluorescent labeling of different cultured embryonic chicken cells (from skin, heart and gizzard) indicated that the label was predominantly organized in intracellular plaques at the bottom of the cells and in some areas of cell-cell contact. Immunoprecipitation of the 130K protein from biosynthetically ³⁵S-methionine-labeled cultured cells, using the pure antibodies and Staphylococcus aureus, resulted in the specific isolation of a single labeled electrophoretic band indistinguishable from the chicken gizzard 130K protein. The 130K protein-rich plaques were found, by interference-reflection microscopy, to coincide with cell substrate adhesion plaques. Double immunofluorescent labeling for the 130K protein and other cytoskeletal proteins (actin, α-actinin and tropomyosin) indicated that the 130K protein-rich areas are localized at the termini of stress fibers. α-Actinin was found in close association with the 130K protein, while tropomyosin was usually excluded from those areas.     

Evidence for the direct interaction of chicken gizzard 5'-nucleotidase with laminin and fibronectin

The ectoenzyme 5'-nucleotidase purified from chicken gizzard is shown to specifically interact with laminin and fibronectin, components of the extracellular matrix, by a number of different techniques: (i) cosedimentation with laminin by sucrose gradient centrifugation; (ii) affinity adsorption to both laminin- and fibronectin-Sepharose 4-B; (iii) specific binding to both laminin and fibronectin dotted onto cellulose filters; and (iv) monoclonal antibodies against 5'-nucleotidase are shown to interfere with the interaction of 5'-nucleotidase with laminin and fibronectin. For all the techniques employed, the interactions were found to be specific, since 5'-nucleotidase did not bind to unrelated proteins such as bovine serum albumin or to monomeric actin. The interaction of purified chicken gizzard 5'-nucleotidase could be demonstrated for the hydrophobic enzyme solubilized in detergent and after its reconstitution into artificial phospholipid vesicles. The affinity adsorption experiments indicate that reconstituted enzyme binds more strongly to both laminin and fibronectin. The 5'-nucleotidase employed in this study is anchored to the plasma membrane by a glycan-phosphatidylinositol linker. After treatment with phosphatidylinositol-specific phospholipase C, the enzyme is transformed into a hydrophilic form, for which interactions with laminin and fibronectin could also be demonstrated by the dot-blot technique. Thus controlled cleavage of the phosphatidylinositol linker of 5'-nucleotidase could enable cells to rapidly alter their adhesiveness to certain components of the extracellular matrix.