The crystal structure of the 2:1 intermolecular complex containing 1-melhyl-5-flourouracil and 9-ethyl-2,6-diaminopurine

Two molecules of 1-methyl-5-fluorouracil complex with one molecule of 9-erthyl-2, -6-diaminopurine and crystsallize in a triclinic unit cell. The crystal structure was solves by analysis of 3-dimensional x-ray diffraction data. Asharpened Patterson map was used to dertermine the structure with apsuedo-heavy atom technique. The three molecule from a planar hydrogen bonded Watson-Crick pair with the purine while the other pyrimide forms hydrogen bond to adenine through the imdazole nitrogen. The network is compeleted by purine-purine hydrogen bond.     

Crystallographic studies of Escherichia coli citrate synthase

The citrate synthase from Escherichia coli B has been crystallized in a cubic space group with a unit cell spacing of 220 A. X-ray diffraction, electron microscopy, symmetry considerations, and low resolution projection Patterson syntheses are consistent with a model proposed in which 24 tetrameric molecules of Mr = 188,000 +/- 12,000 occupy the unit cell. The space group is apparently P23, although at low resolution the observed systematic absences in reflections are consistent with the space group P43n, a space group not allowed for asymmetric molecules. Estimates of VM suggest that in the true space group, P23, two tetrameric molecules occupy the asymmetric unit.     

Multi-isomorphous replacement phasing of the earthworm fibrinolytic enzyme component A from Eisenia fetida

Thrombosis is one of the most widely occurring diseases in modern life, which often causes disability and death. Fibrinolytic enzymes degrade fibrin, the major protein component of blood clots, and eventually lead to thrombolysis. Medications using fibrinolytic enzymes are the most effective methods used in the treatment of thrombosis. A variety of fibrinolytic enzymes, such as tPA, uPA, and streptokinase, have been extensively studied and used as thrombolytic agents in clinic. However, thes…     

Multi-isomorphous replacement phasing of the earthworm fibrinolytic enzyme component A from <Emphasis Type="Italic">Eisenia fetida</Emphasis>

Earthworm fibrinolytic enzyme component A (EFEa) from Eisenia fetida, a protein functioning not only as a direct fibrinolytic enzyme, but also as a plasminogen activator, has been crystallized in P212121 space group with 3 proteinmolecules per asymmetric unit. Four heavy atom derivatives were prepared using a mother liquor containing 1.4 mol@L-1 Li2SO4 and 0.1 mol@L-1 MOPS buffer (pH7.2) and used to solve the protein's diffraction phase. The heavy atom binding sites in the derivative crystals were determined using difference Patterson and difference Fourier methods and were refined in combination to yield the initial protein's structure phase at 0.25 nm resolution. The non-crystallographic symmetryrelationship of the three independent protein molecules in the asymmetric unit was determined using the correlative heavy atom sites and used for the averagingof the initial electron density. As a result, the electron density was significantly improved, providing a solid foundation for subsequent structure determination.     

The structure of oriented sphingomyelin bilayers

X-ray diffraction from oriented bilayers of sphingomyelin gave up to 14 orders of diffraction of a lamellar repeat of 68.5 Å on the meridian and up to eight reflections, including a strong reflection at 4.2 Å, on the equator. The diffraction spacings did not change when the sphingomyelin bilayers were exposed to different humidities. A direct analysis of the low resolution X-ray data, using deconvolution is presented. A comparison of the Patterson functions of sphingomyelin with those of phosphatidylcholine and phosphatidylethanolamine suggests that the molecular structure of sphingomyelin in oriented bilayers resembles the structure of both phosphatidylcholine and phosphatidylethanolamine. Molecular model calculations for sphingomyelin bilayers have also been performed. Electron density profiles of sphingomyelin bilayers at resolution of about 6 Å and about 2.5 Å are presented. Our results indicate that the phosphorylcholine head group of sphingomyelin is in the plane of the membrane and at right angles to the hydrocarbon chains, the hydrocarbon chains are nearly parallel to each other, and there is only a limited, if any, interdigitation of the hydrocarbon chains of the adjacent sphingomyelin molecules in the bilayer.     

Location of two antioxidants in oriented model membranes. Small-angle x-ray diffraction study.

Small-angle x-ray diffraction has been applied in locating either butylated hydroxytoluene (BHT) or delta-tocopherol and their brominated analogues at a concentration of 40 mol% in oriented bilayers of dipalmitoylphosphatidylcholine (DPPC) or DPPC + 15 mol% cholesterol at 20 degrees C. Phases were determined using swelling experiments with structure factors plotted in reciprocal space, creating a relatively smooth curve as the amount of water between the bilayers was changed. Continuous Fourier transforms were also calculated using sampling theory (Shannon, C. E. 1949. Proc. Inst. Radio Engrs. NY. 37:10-21) to further test the consistency of the phase assignments. Fourier synthesis of structure factors resulted in absolute electron density profiles for different bilayers to a resolution of 5-6 A. In addition, difference Patterson maps were constructed to confirm the positions of the bromine atoms in the unit cell. Analysis of the data indicates the following: (a) The BHT molecules are dispersed throughout the alkyl-chain region in DPPC samples with and without cholesterol. (b) The chromanol ring of delta-tocopherol is in the vicinity of the glycerol backbone-headgroup region in samples of DPPC or DPPC + 15 mol% cholesterol. (c) Difference Patterson maps confirm the localization of bromine atoms in the various delta-tocopherol samples and lack of bromine localization in the various BHT samples.     

Low dose electron microscopy of the crotoxin complex thin crystal

The crotoxin complex from Crotalus d. terrificus rattlesnake venom was crystallized in the form of thin platelets. These crystals were prepared by the glucose embedding technique and examined by low dose electron microscopy. Electron diffraction patterns and images have been recorded to 2.2 and 4.5 A, respectively. By a combination of electron and X-ray diffraction techniques, the space group of this crystal was determined to be P4(2)22 with eight crotoxin complex molecules in one unit cell with dimensions of 38.8 A x 38.8 A x 256.8 A. The Patterson maps and the symmetry reliability factors calculated from the electron diffraction intensities clearly showed the existence of three types of electron diffraction patterns in different crystals. The phases in the computer-calculated transform of the low dose images also show the variation in symmetry among crystals. These phenomena are explained by the presence of crystals consisting of one-half, three-quarter and one unit cell in thickness. The interpretation of the computer reconstructed two-dimensional density map was limited, partly because of the similarity in density between the protein and the embedding glucose and partly because of the non-uniqueness in relating projected structure to the three-dimensional structure.     

Structural insights into the exchange domain of sec2p: expression, purification, crystallization, and preliminary x-ray diffraction data analysis

Sec2p is an essential yeast gene and is part of the cell polarization process that leads to budding. The N-terminal domain of sec2p (Sec2pN)--the guanine-nucleotide exchange factor for sec4p--has been expressed in Escherichia coli, purified, and crystallized. Crystals belong to the space group P2(1) with unit cell dimensions 178.1 x 98.4 x 180.0 A, beta = 91.7( degrees ), and diffract synchrotron-generated X-rays to better than 3.6 A resolution. Pseudo-precession plots reveal a Laue symmetry of 2/m, corresponding to the aforementioned space group, and unusual weak diffraction in the approximately 5-7 A resolution range. The Matthews number calculations for a typical crystal density suggest a range of 28 to 64 molecules per asymmetric unit. Self-rotation and native Patterson calculations demonstrate a pure helical array of protein subunits. Based on the X-ray diffraction data analysis and amino-acid sequence alignments, the paper presents a hypothetical model of the exchange domain of sec2p as a pair of coiled-coil helices that binds to sec4p and facilitates nucleotide disassociation.     

X-ray diffraction studies of the corneal stroma.

A low-angle diffraction pattern has been obtained from corneal stroma. This pattern arises both from the arrangement of the collagen fibrils and from the packing of the tropocollagen molecules along the axes of the fibrils. The spacing arising from the packing of the fibrils increases homogeneously on swelling although the tissue as a whole swells only radially referred to the intact eye. The necessary rearrangement of the fibrils for this type of swelling to occur might result in the formation of regions devoid of collagen fibrils and the water not in the lattice of collagen fibrils could be synonymous with the lakes postulated by Benedek (1971) to explain the loss of transparency on swelling.The spacings due to the packing of the tropocollagen molecules are unusual in that, although they index as the third and fifth orders of the well-known 66 nm repeat, the first order of this spacing is absent. Calculation of the Patterson function for corneal collagen leads to peaks in electron density separated by distances of 0.38 and 0.24 of the repeat distance.     

Multi-isomorphous replacement phasing of the earthworm fibrinolytic enzyme component A from Eisenia fetida

Earthworm fibrinolytic enzyme component A (EFEa) from Eisenia fetida, a protein functioning not only as a direct fibrinolytic enzyme, but also as a plasminogen activator, has been crystallized in P2₁2₁2₁ space group with 3 protein molecules per asymmetric unit. Four heavy atom derivatives were prepared using a mother liquor containing 1.4 mol · L^-1 Li₂SO₄ and 0.1 mol · L^-1 MOPS buffer (pH7.2) and used to solve the protein’s diffraction phase. The heavy atom binding sites in the derivative crystals were determined using difference Patterson and difference Fourier methods and were refined in combination to yield the initial protein’s structure phase at 0.25 nm resolution. The non-crystallographic symmetry relationship of the three independent protein molecules in the asymmetric unit was determined using the correlative heavy atom sites and used for the averaging of the initial electron density. As a result, the electron density was significantly improved, providing a solid foundation for subsequent structure determination.     

Direct determination of crystallographic phases for diffraction data from phospholipid multilamellar arrays.

Direct determination of crystallographic phases based on probabilistic of sigma 1 and sigma 2 "triplet" structure invariants has been found to be an effective technique for structure analysis with lamellar x-ray or electron diffraction intensity data from phospholipids. In many cases, nearly all phase values are determined, permitting a structure density (electron density for x-ray diffraction; electrostatic potential for electron diffraction) map to be calculated, which is directly interpretable in terms of known bilayer lipid structure. The major source of error is found to be due to the distortion of observed electron diffraction intensity data by incoherent multiple scattering, which can significantly affect the appearance of the electrostatic potential map, but not the success of the phase determination, as long as the observed Patterson function can be interpreted.     

An X-ray crystallographic study of α-d-allopyranosyl α-d-allopyranoside · CaCl2 · 5H2O (a pentadentate complex)

Three-dimensional, single-crystal, X-ray diffraction methods were used to determine the structure of the calcium chloride complex of α-d-allopyranosyl α-d-allopyranoside. The crystal is monoclinic with cell dimensions: a = 16.262(5), b = 8.345(5), c = 8.298(5)Å, β = 98.428(5)Å, and z = 2. The space group is P2₁. The structure was solved by three-dimensional Patterson and Fourier methods, and was refined by least-squares techniques to give a conventional discrepancy factor of R = 0.026; 2435 diffractometer-read reflections were used. The cation was found to be in 9-fold co-ordination to O-1, O-2, O-3, O-2′, O-3′, and four water molecules.     

Crystal and molecular structure of the ammonium salt of the dinucleoside monophosphate d(CpG)

The crystal and molecular structure of the ammonium salt of deoxycytidylyl-(3'-5')-deoxyguanosine has been determined from 0.85 A resolution single crystal X-ray diffraction data. The crystals obtained by acetone diffusion technique at -20 degrees C, are orthorhombic, P212121, a = 12.880(2), b = 17444(2) and c = 27.642(2) A. The structure was solved by high resolution Patterson and Fourier methods and refined to R = 0.136. There are two d(CpG) molecules in the asymmetric unit forming a mini left handed Z-DNA helix. This is in contrast to the earlier reported forms of d(CpG) where the molecules form self base paired duplexes. There are two ammonium ions in the asymmetric unit. The major groove NH+4 ion interacts with N7 of guanines through water bridges besides making H-bonded interactions directly with the phosphate oxygen atoms. A second NH+4 ion is found in the minor groove interacting directly with the phosphate oxygen atoms. Symmetry related molecules pack in such a way that the cytosine base stacks on cytosine and guanine base on guanine. Our structure demonstrates that alternating d(CpG) sequences have the ability to adopt the left handed Z-DNA structure even at the dimer level i.e., in a sequence which is only two base pairs long.     

Solution of the phase problem in the X-ray diffraction method for proteins with the nuclear magnetic resonance solution structure as initial model. Patterson search and refinement for the alpha-amylase inhibitor tendamistat

Patterson search calculations using the three-dimensional structure of the alpha-amylase inhibitor from Streptomyces tendae obtained from experimental nuclear magnetic resonance (n.m.r.) data were performed to study the possibility of solving the phase problem in the X-ray diffraction method with protein structures determined by n.m.r. Using all heavy atoms (C, N, O, S) of the residues 5 to 73 in the best n.m.r. structure of the alpha-amylase inhibitor (520 out of the 558 heavy atoms in the complete polypeptide chain), the maximum of the rotation function corresponded to the correct solution obtained by the previous independent determination of the crystal structure. However, additional local maxima, which are not significantly lower than the global maximum, also showed up. Performing the Patterson search with a model containing the backbone atoms and the heavy atoms of only the interior side-chains (399 atoms), which are much better defined by the n.m.r. data, the correct maximum was significantly higher than all other maxima. A translation search for the best orientation of the latter model yielded the correct solution. The energy-restrained crystallographic refinement was performed with this model to an R-factor of 26%. This corresponds approximately to the R-factor calculated for the X-ray crystal structure previously determined using the isomorphous replacement technique, if the residues 1 to 4 and 74 and all localized solvent molecules were removed from this structure. During the refinement the root-mean-square deviation between the two structures decreased from 1.03 A to 0.26 A for the polypeptide backbone and from 1.64 A to 0.73 A for all heavy atoms. There are no major local conformational differences between the two structures, with the single exception of the side-chain of Gln52.     

Lamellar packing of a chiral N,N-dimethylphosphatidylethanolamine: electron diffraction. Evidence for a lecithin-type headgroup conformation

Lamellar electron diffraction intensity data from epitaxially crystallized 1,2-dipalmitoyl-sn-glycerophospho-N,N-dimethylethanolamine were used to determine the layer packing in order to compare the chiral structure to the crystal structure of a racemic homologue. After finding the chain orientation, the structure was determined by interpretation of the Patterson function, followed by independent crystallographic phase assignments with conventional direct methods (use of three phase structure invariants). The phase determination was verified by a translational search with a molecular model based on a similar lecithin structure. The final R-value is 0.29, and this is lowered to 0.18 after a correction is made for incoherent multiple electron scattering. The layer packing is found to be very much like that of a diacyl phosphatidylcholine with the N,N-dimethylethanolamine moiety parallel to the bilayer surface rather than the perpendicular arrangement of headgroups involved in an interdigitated layer, as seen for racemic homolog.     

Crystal structure at 1.5-A resolution of d(CGCICICG), an octanucleotide containing inosine, and its comparison with d(CGCG) and d(CGCGCG) structures.

The octadeoxyribonucleotide d(CGCICICG) has been crystallized in space group P(6)5(22) with unit cell dimensions of a = b = 31.0 A and c = 43.7 A, and X-ray diffraction data have been collected to 1.5-A resolution. Precession photographs and the self-Patterson function indicate that 12 base pairs of Z-conformation DNA stack along the c-axis, and the double helices pack in a hexagonal array similar to that seen in other crystals of Z-DNA. The structure has been solved by both Patterson deconvolution and molecular replacement methods and refined in space group P(6)5 to an R factor of 0.225 using 2503 unique reflections greater than 3.0 sigma (F). Comparison of the molecules within the hexagonal lattice with highly refined crystal structures of other Z-DNA reveals only minor conformational differences, most notably in the pucker of the deoxyribose of the purine residues. The DNA has multiple occupancy of C:I and C:G base pairs, and C:I base pairs adopt a conformation similar to that of C:G base pairs.     

Structure of yeast hexokinase-B: I. Preliminary X-ray studies and subunit structure

Initial X-ray diffraction studies of large single crystals of yeast hexokinase-B provide information on its subunit structure and show the crystals to be suitable for a high resolution structure determination. Patterson maps of the native protein crystals suggest that the two 50,000 molecular weight subunits are identical, or very nearly so, and that they are related by an approximate rather than a true diad axis; that is, one subunit is translated relative to the other by 3.6 Å along the molecular symmetry axis. This results in heterologous subunit interactions rather than the isologous interactions expected.     

Electron microscopy of decorated crystals for the determination of crystallographic rotation and translation parameters in large protein complexes.

The lumazine synthase/riboflavin synthase complex of Bacillus subtilis consists of an icosahedral capsid of 60 beta subunits enclosing a core of 3 alpha subunits. The preparation of reconstituted hollow capsids consisting of 60 beta subunits and their crystallization in a hexagonal (space group P6(3)22) and in a monoclinic (space group C2) modification have been described. The rotational and translational parameters of the protein molecules in both crystal forms were studied by electron microscopy of freeze-etch replicas and by Patterson correlation techniques. Decoration with silver and image processing provided images with the positions of the 3-fold and 5-fold molecular axes being labelled by metal clusters. This allowed the unequivocal determination of the orientation and translational position of the protein molecules with respect to the crystallographic axes in the hexagonal modification. From inspection of the decoration images it was immediately obvious that the hexagonal crystal forms of alpha 3 beta 60 and of beta 60 are isomorphous. In the monoclinic crystals, a local icosahedral 2-fold coincides with the crystallographic 2-fold axis. The exact solution of the particle orientation was determined by interpretation of Patterson self-rotation functions for the icosahedral symmetry axes. Rotational and translational parameters for the monoclinic modification are given. A rational procedure for the efficient application of freeze-etching techniques in order to elucidate the packing in crystals of large proteins is described.     

Two different molecular conformations found in chitosan type II salts

The type II structure of chitosan acidic salts prepared from crab tendon in solid state was studied using an X-ray fiber diffraction technique together with the linked-atom least-squares (LALS) technique. The cylindrical Patterson method was applied to confirm the molecular conformation of the chitosan. It was shown that there are two different helical conformations for type II salts. One is the relaxed twofold helix having a tetrasaccharide as an asymmetric unit as found in chitosan.HCl salt, which was previously reported as a conformation of chitosan.HCOOH salt. The other is the fourfold helix having a disaccharide as an asymmetric unit newly found in chitosan.HI salt.     

Gene sequence and crystal structure of the aldehyde oxidoreductase from Desulfovibrio desulfuricans ATCC 27774

The aldehyde oxidoreductase (MOD) isolated from the sulfate reducer Desulfovibrio desulfuricans (ATCC 27774) is a member of the xanthine oxidase family of molybdenum-containing enzymes. It has substrate specificity similar to that of the homologous enzyme from Desulfovibrio gigas (MOP) and the primary sequences from both enzymes show 68 % identity. The enzyme was crystallized in space group P6(1)22, with unit cell dimensions of a=b=156.4 A and c=177.1 A, and diffraction data were obtained to beyond 2.8 A. The crystal structure was solved by Patterson search techniques using the coordinates of the D. gigas enzyme. The overall fold of the D. desulfuricans enzyme is very similar to MOP and the few differences are mapped to exposed regions of the molecule. This is reflected in the electrostatic potential surfaces of both homologous enzymes, one exception being the surface potential in a region identifiable as the putative docking site of the physiological electron acceptor. Other essential features of the MOP structure, such as residues of the active-site cavity, are basically conserved in MOD. Two mutations are located in the pocket bearing a chain of catalytically relevant water molecules.As deduced from this work, both these enzymes are very closely related in terms of their sequences as well as 3D structures. The comparison allowed confirmation and establishment of features that are essential for their function; namely, conserved residues in the active-site, catalytically relevant water molecules and recognition of the physiological electron acceptor docking site.