Crystal structure of polymerization-competent actin

All actin crystal structures reported to date represent actin complexed or chemically modified with molecules that prevent its polymerization. Actin cleaved with ECP32 protease at a single site between Gly42 and Val43 is virtually non-polymerizable in the Ca-ATP bound form but remains polymerization-competent in the Mg-bound form. Here, a crystal structure of the true uncomplexed ECP32-cleaved actin (ECP-actin) solved to 1.9 A resolution is reported. In contrast to the much more open conformation of the ECP-actin's nucleotide binding cleft in solution, the crystal structure of uncomplexed ECP-actin contains actin in a typical closed conformation similar to the complexed actin structures. This unambiguously demonstrates that the overall structure of monomeric actin is not significantly affected by a multitude of actin-binding proteins and toxins. The invariance of actin crystal structures suggests that the salt and precipitants necessary for crystallization stabilize actin in only one of its possible conformations. The asymmetric unit cell contains a new type of antiparallel actin dimer that may correspond to the "lower dimer" implicated in F-actin nucleation and branching. In addition, symmetry-related actin-actin contacts form a head to tail dimer that is strikingly similar to the longitudinal dimer predicted by the Holmes F-actin model, including a rotation of the monomers relative to each other not observed previously in actin crystal structures.     

Crystal structure of a zwitterionic detergent: n-octyl-2-hydroxyethylsulfoxide

The crystal structure of n-octyl-2-hydroxyethylsulfoxide (1) (space group P2(1)/c, a = 16.516(7), b = 9.053(4), c = 8.222(4) A, beta = 97.58 degrees) was determined by X-ray diffraction methods to 0.94 A resolution and refined to R = 0.050 (Rw = 0.052). In the crystal lattice the molecules are not arranged tail-to-tail, as usually observed with amphiphilic compounds, but head-to-tail and aligned in the a-axis direction. They form layers in the b, c plane which are interdigitated such that adjacent molecules in one layer are in antiparallel orientation. The packing is stabilized by intermolecular hydrogen bonds O-H--O-S. No solvent molecules were detectable.     

A nanosecond molecular dynamics study of antiparallel d(G)7 quadruplex structures: effect of the coordinated cations

Nanosecond scale molecular dynamics simulations have been performed on antiparallel Greek key type d(G7) quadruplex structures with different coordinated ions, namely Na+ and K+ ion, water and Na+ counter ions, using the AMBER force field and Particle Mesh Ewald technique for electrostatic interactions. Antiparallel structures are stable during the simulation, with root mean square deviation values of approximately 1.5 A from the initial structures. Hydrogen bonding patterns within the G-tetrads depend on the nature of the coordinated ion, with the G-tetrad undergoing local structural variation to accommodate different cations. However, alternating syn-anti arrangement of bases along a chain as well as in a quartet is maintained through out the MD simulation. Coordinated Na+ ions, within the quadruplex cavity are quite mobile within the central channel and can even enter or exit from the quadruplex core, whereas coordinated K+ ions are quite immobile. MD studies at 400K indicate that K+ ion cannot come out from the quadruplex core without breaking the terminal G-tetrads. Smaller grooves in antiparallel structures are better binding sites for hydrated counter ions, while a string of hydrogen bonded water molecules are observed within both the small and large grooves. The hydration free energy for the K+ ion coordinated structure is more favourable than that for the Na+ ion coordinated antiparallel quadruplex structure.     

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.     

Antiparallel beta-sheets in the crystal structure of the heptapeptide Met-Glu-His-Phe-Arg-Trp-Gly (ACTH 4-10)

The conformation of the molecules in ACTH 4-10 has been determined as part of a study of the conformations of the biologically active N-terminal fragments of the adrenocorticotropic hormone (ACTH). ACTH 4-10 crystallizes in two different superstructures. The substructure considered in the present work, is monoclinic, space group C2, a = 25.75(1) A, b = 27.78(1) A, c = 20.35(1) A, beta = 114.0(1) degrees, Z = 8 molecules ACTH 4-10 plus 22 weight per cent solvent. The crystals contain antiparallel beta-sheets, the orientations of the side groups are not found, because of disorder. The present crystal structure and those of other linear oligopeptides emphasize that antiparallel beta-sheets are energetically favourable. It is very unlikely, however, that the ACTH 4-10 crystals contain the molecules in their biologically active form.     

Gramicidin channels: a new mechanism for transmembrane transfer of ions (from high resolution x-ray structural studies of the antibiotic)]

The crystal structure of the membrane-active antibiotic-cyclopeptide gramicidin S complex with urea was determined by the X-ray structure analysis. The gramicidin S molecule possesses an antiparallel beta-structure, its slightly twisted 30-membered cycle has a roughly rectangular form about 4.8 x 13.6 A in size, with the lesser side being formed by the main chain atoms of Phe and Pro residues. The maximum size of the molecule is 22.9 A. A characteristic feature of the molecule is the position of the extended side chains of the Orn residues on one side of the molecular cycle in the form of peculiar "legs--tentacles". One of these legs is "fastened" by the intramolecular H-bond to O atom of the nearer Phe4 residue, the other being free. The distance between the terminal NE atoms of the Orn residues is 5.7 A. The side chains of the Phe and Orn2 residues have trans-orientation, those of the Val, Orn7, Leu residues gauche-orientation. For Val1 and Leu3 side chains statistical disorder of the terminal C atoms is realized. The pyrrolidine rings of the Pro residues adopt Cs-C beta-exo conformation. There are one urea and 20 water molecules per one antibiotic molecule in the structure. The positions of three water molecules are fully occupied, the others with the probability of 0.56-0.20. One of the "water" positions is occupied on 2/3 by water, and on 1/3 by the O atom of the alcohol. There is a complicated system of intra- and intermolecular H-bonds in the structure, with and without the participation of water, alcohol and urea molecules. The gramicidin S molecules, collecting around 3(1) axis according to the left-handed double helix, form the channels whose outside hydrophobic surface is built of the side uncharged radicals, the inside surface being built of the main chain atoms, mainly of the O and N atoms and of the ornithine "tails" with uncharged NE atoms at the termini. The outer diameter of the channel is 29-43 A, inner (without ornithine "tails") is about 12.7 A. At the expense of the change of these "tails" conformation, the inner diameter of the channel filled with water molecules may change from 3.4 up to 6.3 A. Thus, the ions and particles of a rather large size may pass through the channel. The gramicidin channels are discovered and described for the first time. The channels in the crystal structure are close-packed under the hexagonal law.(ABSTRACT TRUNCATED AT 400 WORDS)     

Regularly alternating L,D-peptides. II. The double-stranded right-handed antiparallel beta-helix in the structure of t-Boc-(L-Phe-D-Phe)4-OMe

The crystal structure of Boc-(L-Phe-D-Phe)4-OMe has been determined by x-ray diffraction analysis. The peptide crystallizes in the triclinic system, space group P1 with a = 15.290 A, b = 15.163 A, c = 19.789 A, alpha = 102.49 degrees, beta = 96.59 degrees, gamma = 74.22 degrees, and Z = 2. The structure has been solved by coupling of the molecular replacement technique and expansion by tangent formula refinement of the set of known phases. Several cycles of Fourier calculations and least-squares refinement led to the location of 194 atoms of the two independent octapeptide chains and few molecules of cocrystallized solvent (chloroform, water, and methanol). The isotropic refinement converged to R = 0.13 for the 3077 "observed" reflections. The two independent octapeptide molecule form a dimer in the solid state: the two chains are associated by interstrand hydrogen bonds (12 of the type N-H ... O = C) with the formation of a double-stranded antiparallel right-handed -- beta 5.6-helix. These double helices can be represented as a cylinder with a hydrophilic inner core represented by the peptide units and an hydrophobic exterior constituted by the aromatic moieties. The dimensions of the cylinder are equal to those observed for Boc-(L-Val-D-Val)4-OMe. In the solid state the dimers pack with each other in an hexagonal fashion with the formation of layers; between the layers, solvent molecules fill empty spaces.     

Beta-lactamase of Bacillus licheniformis 749/C at 2 A resolution

Two crystal forms (A and B) of the 29,500 Da Class A beta-lactamase (penicillinase) from Bacillus licheniformis 749/C have been examined crystallographically. The structure of B-form crystals has been solved to 2 A resolution, the starting model for which was a 3.5 A structure obtained from A-form crystals. The beta-lactamase has an alpha + beta structure with 11 helices and 5 beta-strands seen also in a penicillin target DD-peptidase of Streptomyces R61. Atomic parameters of the two molecules in the asymmetric unit were refined by simulated annealing at 2.0 A resolution. The R factor is 0.208 for the 27,330 data greater than 3 sigma (F), with water molecules excluded from the model. The catalytic Ser-70 is at the N-terminus of a helix and is within hydrogen bonding distance of conserved Lys-73. Also interacting with the Lys-73 are Asn-132 and the conserved Glu-166, which is on a potentially flexible helix-containing loop. The structure suggests the binding of beta-lactam substrates is facilitated by interactions with Lys-234, Thr-235, and Ala-237 in a conserved beta-strand peptide, which is antiparallel to the beta-lactam's acylamido linkage; an exposed cavity near Asn-170 exists for acylamido substituents. The reactive double bond of clavulanate-type inhibitors may interact with Arg-244 on the fourth beta-strand. A very similar binding site architecture is seen in the DD-peptidase.     

Crystal structure of archaeal ribonuclease P protein Ph1771p from Pyrococcus horikoshii OT3: an archaeal homolog of eukaryotic ribonuclease P protein Rpp29

Ribonuclease P (RNase P) is the endonuclease responsible for the removal of 5' leader sequences from tRNA precursors. The crystal structure of an archaeal RNase P protein, Ph1771p (residues 36-127) from hyperthermophilic archaeon Pyrococcus horikoshii OT3 was determined at 2.0 A resolution by X-ray crystallography. The structure is composed of four helices (alpha1-alpha4) and a six-stranded antiparallel beta-sheet (beta1-beta6) with a protruding beta-strand (beta7) at the C-terminal region. The strand beta7 forms an antiparallel beta-sheet by interacting with strand beta4 in a symmetry-related molecule, suggesting that strands beta4 and beta7 could be involved in protein-protein interactions with other RNase P proteins. Structural comparison showed that the beta-barrel structure of Ph1771p has a topological resemblance to those of Staphylococcus aureus translational regulator Hfq and Haloarcula marismortui ribosomal protein L21E, suggesting that these RNA binding proteins have a common ancestor and then diverged to specifically bind to their cognate RNAs. The structure analysis as well as structural comparison suggested two possible RNA binding sites in Ph1771p, one being a concave surface formed by terminal alpha-helices (alpha1-alpha4) and beta-strand beta6, where positively charged residues are clustered. A second possible RNA binding site is at a loop region connecting strands beta2 and beta3, where conserved hydrophilic residues are exposed to the solvent and interact specifically with sulfate ion. These two potential sites for RNA binding are located in close proximity. The crystal structure of Ph1771p provides insight into the structure and function relationships of archaeal and eukaryotic RNase P.     

Crystal structure of the potassium form of an Oxytricha nova G-quadruplex

The crystal structures of the potassium-containing quadruplex formed from the Oxytricha nova sequence d(GGGGTTTTGGGG) are reported, in two space groups, the orthorhombic P2(1)2(1)2(1) and the trigonal P3(2)21, which diffract to 2.0 A and 1.49 A, respectively. The orthorhombic form contains two independent quadruplexes in the asymmetric unit, and the trigonal form contains one. All three of these quadruplexes adopt an identical fold, with two strands forming an antiparallel diagonal arrangement. This is identical with that observed previously in NMR studies of the native sodium and potassium forms, and a crystallographic analysis of it complexed with an O. nova protein. The present analysis demonstrates that the native structure is the same in solution and in the crystalline state and, moreover, that the nature of the counter-ion does not affect the overall fold of this quadruplex. The analysis corrects an earlier crystallographic study of this quadruplex. The conformation of the tetra-thymine loop is described in detail, which involves the third thymine base folding back to interact with the first thymine base. The water networks in the grooves and loops are described and, in particular, the ability of water molecules to form a continuous spine of hydration in the narrow groove is detailed. Each quadruplex has five potassium ions organised in a linear channel, with square antiprismatic coordination to each ion from oxygen atoms.     

A specific cholesterol binding site is established by the 2.8 A structure of the human beta2-adrenergic receptor

The role of cholesterol in eukaryotic membrane protein function has been attributed primarily to an influence on membrane fluidity and curvature. We present the 2.8 A resolution crystal structure of a thermally stabilized human beta(2)-adrenergic receptor bound to cholesterol and the partial inverse agonist timolol. The receptors pack as monomers in an antiparallel association with two distinct cholesterol molecules bound per receptor, but not in the packing interface, thereby indicating a structurally relevant cholesterol-binding site between helices I, II, III, and IV. Thermal stability analysis using isothermal denaturation confirms that a cholesterol analog significantly enhances the stability of the receptor. A consensus motif is defined that predicts cholesterol binding for 44% of human class A receptors, suggesting that specific sterol binding is important to the structure and stability of other G protein-coupled receptors, and that this site may provide a target for therapeutic discovery.     

Crystal structure of a c-kit promoter quadruplex reveals the structural role of metal ions and water molecules in maintaining loop conformation

We report here the 1.62 Å crystal structure of an intramolecular quadruplex DNA formed from a sequence in the promoter region of the c-kit gene. This is the first reported crystal structure of a promoter quadruplex and the first observation of localized magnesium ions in a quadruplex structure. The structure reveals that potassium and magnesium ions have an unexpected yet significant structural role in stabilizing particular quadruplex loops and grooves that is distinct from but in addition to the role of potassium ions in the ion channel at the centre of all quadruplex structures. The analysis also shows how ions cluster together with structured water molecules to stabilize the quadruplex arrangement. This particular quadruplex has been previously studied by NMR methods, and the present X-ray structure is in accord with the earlier topology assignment. However, as well as the observations of potassium and magnesium ions, the crystal structure has revealed a highly significant difference in the dimensions of the large cleft in the structure, which is a plausible target for small molecules. This difference can be understood by the stabilizing role of structured water networks.     

Regularly alternating L,D-peptides. I. The double-stranded left-handed antiparallel beta-helix in the structure of Boc-(L-Val-D-Val)4-OMe

The structure of Boc-(L-Val-D-Val)4-OMe has been determined by x-ray single-crystal diffraction analysis. The octapeptide crystallizes in the trigonal system, space group P3(2)21 with a = b = 12.760 A, c = 63.190 A and Z = 6. The independent unit is represented by one octapeptide chain. The structure has been solved by direct methods and it was anisotropically refined by least-squares procedures to a final R value of 0.08 for the 3018 "observed" reflections. One molecule of water was also located in the unit cell. Two octapeptide chains, related by a crystallographic binary axis, wind up around each other giving rise to a double-stranded left-handed antiparallel increases decreases beta 5.6-helix. The dimer, stabilized by 14 interstrand N--H....O = C hydrogen bonds, can be regarded as a cylinder with an hydrophilic inner core represented by the peptide units and an hydrophobic exterior of isopropyl groups. The inner diameter of the cylinder is 5.1 A.     

The pore dimensions of gramicidin A.

The ion channel forming peptide gramicidin A adopts a number of distinct conformations in different environments. We have developed a new method to analyze and display the pore dimensions of ion channels. The procedure is applied to two x-ray crystal structures of gramicidin that adopt distinct antiparallel double helical dimer conformations and a nuclear magnetic resonance (NMR) structure for the beta6.3 NH2-terminal to NH2-terminal dimer. The results are discussed with reference to ion conductance properties and dependence of pore dimensions on the environment.     

A trigonal form of the idarubicin:d(CGATCG) complex; crystal and molecular structure at 2.0 A resolution.

The X-ray crystal structure of the complex between the anthracycline idarubicin and d(CGATCG) has been solved by molecular replacement and refined to a resolution of 2.0 A. The final R-factor is 0.19 for 3768 reflections with Fo > or = 2 sigma (Fo). The complex crystallizes in the trigonal space group P31 with unit cell parameters a = b = 52.996(4), c = 33.065(2) A, alpha = beta = 90 degree, gamma = 120 degree. The asymmetric unit consists of two duplexes, each one being complexed with two idarubicin drugs intercalated at the CpG steps, one spermine and 160 water molecules. The molecular packing underlines major groove-major groove interactions between neighbouring helices, and an unusually low value of the occupied fraction of the unit cell due to a large solvent channel of approximately 30 A diameter. This is the first trigonal crystal form of a DNA-anthracycline complex. The structure is compared with the previously reported structure of the same complex crystallizing in a tetragonal form. The geometry of both the double helices and the intercalation site are conserved as are the intramolecular interactions despite the different crystal forms.     

Conformation and intramolecular hydrogen-bonding in the crystal structure of potassium D-gluconate monohydrate

The D-gluconate ion is found to have the planar, extended carbon-chain conformation in the crystal structure of potassium D-gluconate monohydrate, with an intramolecular hydrogen-bond between 0-2 and 0-4. The D-gluconate ions and water molecules are linked in puckered sheets by a series of intermolecular hydrogen-bonds that involve the water molecules, the carboxylate groups, and pairs of hydroxyl groups. One hydroxyl group in the ion does not form a hydrogen bond. The potassium ions lie between the puckered sheets, with an eight-fold coordination of six D-gluconate groups and two water oxygen atoms. The crystal structure was determined from three-dimensional, CuKα, X-ray diffraction data taken on an automatic diffractometer.     

Structure determination of histidine decarboxylase from Lactobacillus 30a at 3.0 A resolution

The crystal structure of histidine decarboxylase from Lactobacillus 30a has been determined by X-ray diffraction methods to a resolution of 3.0 A. This protein is a pyruvoyl-dependent enzyme that is formed by an unusual self-activation process. The structure was determined from an electron density map calculated using multiple isomorphous replacement phases from two heavy-atom derivatives and included contributions from anomalous scattering measurements. The final mean figure of merit was 0.79, based on 28,805 independent reflections. The molecule has an (alpha beta)6 subunit composition and crystallizes in the space group 14122 with a = b = 221.7 A and c = 107.1 A. There is one (alpha beta)3 half molecule per asymmetric unit. The (alpha beta)6 particle is dumbbell-shaped, with each (alpha beta)3 unit being approximately spherical, with a diameter of about 65 A. There is a large central cavity approximately 30 A deep around the molecular 3-fold axis of the (alpha beta)3 unit. The 3-fold related active site pockets are located around the bottom of this cavity and are separated from each other by a distance of approximately 23 A. The inner portion of each (alpha beta) unit, which lies near the interface between the two (alpha beta)3 particles, consists mainly of random coil with several small helical and sheet regions. The outer region of each (alpha beta) unit has an unusual structure consisting of two overlapping, predominantly antiparallel beta-pleated sheets, lined on each side by an alpha-helix. The walls of the central cavity are formed by the 3-fold repeat of two strands from this beta-sandwich structure and one of the helices.     

Intercalation of water molecules between nucleic acid bases in the crystal structures of 6-azathymine hemihydrate and 5-amino-2-thiocytosine dihydrochloride dihydrate

The crystal structure of 6-azathymine hemihydrate (6AzTH) exhibits a novel intercalation of water molecules interposed half-way between the modified bases 6.3 to 6.7 A apart. The crystal contains four molecules of 6-azathymine (6AzT) and two water molecules as the independent repeating unit. These two water molecules together with the four bases form two separate water sandwiches. In the crystal structure these sandwiches form two sets of local clusters. The anhydrous crystalline form of 6AzT, on the other hand, is stabilized by base stacking interactions. Both the water molecules in 6AzTH that are involved in sandwich formation have trigonal coordination around them. A reexamination of the crystal structure of 5-amino-2-thiocytosine (5A2TC) revealed that one of the water molecules in this structure also forms a water sandwich and has trigonal coordination whereas the other water molecule with tetrahedral coordination does not form a sandwich. The environment and the characteristics of the intercalated water molecule in these structures suggest a possible role for such water intercalations in the dynamics of DNA. Crystals of 6AzTH are monoclinic, space group P21/n, with unit cell parameters a = 8.861 (1), b = 13.177 (3), c = 20.662 (2) A, beta = 93.35 (1) degrees, and Z = 16. From diffractometer data (2503 reflections, greater than or equal to 3 sigma), the crystal structure was solved and refined to an R of 0.056.     

The structure of yeast enolase at 2.25-A resolution. An 8-fold beta + alpha-barrel with a novel beta beta alpha alpha (beta alpha)6 topology

The three-dimensional structure of yeast enolase has been determined by the multiple isomorphous replacement method followed by the solvent flattening technique. A polypeptide model, corresponding with the known amino acid sequence, has been fitted to the electron density map. Crystallographic restrained least-squares refinement of the model without solvent gave R = 20.0% for 6-2.25-A resolution with good geometry. A model with 182 water molecules and 1 sulfate which is still being refined has presently R = 17.0%. The molecule is a dimer with subunits related by 2-fold crystallographic symmetry. The subunit has dimensions 60 X 55 X 45 A and is built from two domains. The smaller N-terminal domain has an alpha + beta structure based on a three-stranded antiparallel meander and four helices. The main domain is an 8-fold beta + alpha-barrel. The enolase barrel is, however, different from the triose phosphate isomerase barrel; its topology is beta beta alpha alpha (beta alpha)6 rather than (beta alpha)8 as found in triose phosphate isomerase. The inner beta-barrel is not entirely parallel, the second strand is antiparallel to the other strands, and the direction of the first helix is also reversed with respect to the other helices. This supports the hypothesis that some enzymes evolved independently producing the stable structure of beta alpha barrels with either enolase or triose phosphate isomerase topology. The active site of enolase is located at the carboxylic end of the barrel. A fragment of the N-terminal domain and two long loops protruding from the barrel domain form a wide crevice leading to the active site region. Asp246, Glu295, and Asp320 are the ligands of the conformational cation. Other residues in the active site region are Glu168, Asp321, Lys345, and Lys396.     

The structure of the outer membrane protein OmpX from Escherichia coli reveals possible mechanisms of virulence.

BACKGROUND: The integral outer membrane protein X (OmpX) from Escherichia coli belongs to a family of highly conserved bacterial proteins that promote bacterial adhesion to and entry into mammalian cells. Moreover, these proteins have a role in the resistance against attack by the human complement system. Here we present the first crystal structure of a member of this family. RESULTS: The crystal structure of OmpX from E. coli was determined at 1.9 A resolution using multiple isomorphous replacement. OmpX consists of an eight-stranded antiparallel all-next-neighbor beta barrel. The structure shows two girdles of aromatic amino acid residues and a ribbon of nonpolar residues that attach to the membrane interior. The core of the barrel consists of an extended hydrogen-bonding network of highly conserved residues. OmpX thus resembles an inverse micelle. The structure explains the dramatically improved crystal quality of OmpX containing the mutation His100-->Asn, which made the X-ray analysis possible. The coordination spheres of two bound platinum ions are described. CONCLUSIONS: The OmpX structure shows that within a family of virulence-related membrane proteins, the membrane-spanning part of the protein is much better conserved than the extracellular loops. Moreover, these loops form a protruding beta sheet, the edge of which presumably binds to external proteins. It is suggested that this type of binding promotes cell adhesion and invasion and helps defend against the complement system. Although OmpX has the same beta-sheet topology as the structurally related outer membrane protein A (OmpA), their barrels differ with respect to the shear numbers and internal hydrogen-bonding networks.