Secondary structure of histones in solution

The secondary structure of histones H2B and H3 from calf thymus has been quantitatively studied in heavy water solutions in a wide range of histone concentrations, pD, and concentrations of sodium chloride by an infrared spectroscopy method. Also, the interactions between molecules of different histones in equimolar mixtures H2A-H2B, H2A-H3, H2A-H4, H2B-H3, H2B-H4, H3-H4, and H2A-H2B-H3-H4 have been investigated using the same method. For H2B and H3 conditions favourable for aggregation have been shown to induce the formation of pleated sheet structure. When the pD and concentration of NaCl are in a physiological range, the secondary structure of H2B and H3 contains about 15% of alpha-helix, 4% of parallel pleated sheet structure, 14% of antipatallel pleated sheet structure in H2B and 18% in H3. For mixtures in all cases, except H2A-H4, there is an interaction between molecules of different histones followed by a reduction of the antiparallel pleated sheet structure content. The data on the secondary structure of histones in different states (under self-association, in mixtures, in nucleosomes, and in chromatin) have been discussed and it is suggested that: 1) the secondary structure of histones in chromatin is essentially similar to that in the state of self-association; 2) in the core nucleosome particle the quantity of DNA (in nucleotide pairs), and the quantities of alpha-helix and antiparallel pleated sheet structure (in peptide groups) satisfy the relation 1 : 1 : 1.     

The pleated sheet: an unusual negative-staining method for transmission electron microscopy of biological macromolecules

A novel method for preparing negatively stained specimens is described which appears to improve the routine resolution of biological structure in direct images obtained by transmission electron microscopy. In the new method, which we term the pleated sheet technique, macromolecules are adsorbed to a carbon film by the Valentine procedure (R. Valentine, B. Shapiro, and E. Stadtman (1968) Biochemistry, 7, 2143-2152), and the film then carefully pleated while in contact with a 1% uranyl formate solution to trap stain within the folds of pleats. A grid is placed on the compressed film, and film plus grid retrieved with a Saran Wrap drum. Subsequent dehydration produces a filmed grid containing negatively stained macromolecules within the folds of pleated regions and positively stained macromolecules in single sheet regions. The effect of sandwiching sample and stain between carbon layers is to produce exceedingly uniform negative staining so that stain contours more accurately and more reproducibly reflect true molecular contours. Electron micrographs of IgG and IgA molecules prepared by these methods are exhibited that permit unambiguous comparison of structure imaged in the electron microscope against known structures solved by single-crystal X-ray diffraction. Correlation is excellent; the smallest resolvable element in micrographs is an immunoglobulin domain, whose molecular weight is 12 000.     

Molecular structure of L-lysyl-L-tyrosyl-L-serine acetate

The structure of the tripeptide L-lysyl-L-tyrosyl-L-serine acetate was determined by X-ray diffraction. The crystals are triclinic space group P1, with two peptide molecules in the unit cell. The peptides are in zwitterionic form with positive charges both in the amino terminal and epsilon-amino groups of lysine. A negative charge is found in one of the carboxylic groups, whereas the other one is protonated. Both peptides show very similar backbone torsional angles, in the beta pleated sheet region, but different tyrosine and serine side-chain conformations. The two lysine side chains have a similar conformation g + tg + t, which had not been previously found. In the unit cell we also find one water molecule, one isopropanol molecule and four acetic acid molecules, three of them likely to be present as acetate anions. These molecules form layers which separate the beta-pleated sheets. The whole structure looks like an ordered solution of peptides in the beta-sheet conformation. An extensive network of hydrogen bonds stabilizes the crystal structure.     

X-ray analysis of renin substrates. Phenyloxyacetyl-leucyl-valyl-phenylalanine methyl ester: an analogue of angiotensinogen-(10-13) sequence

The crystal structure of the title compound, an analogue of the angiotensinogen-(10-13) peptide in which the N-terminal leucine and the C-terminal tyrosine are respectively replaced by the phenyloxy-acetic group and by phenylalanine, has been determined by X-ray diffraction. The peptide crystallizes in the space group P2(1)2(1)2(1) with a = 4.866(1), b = 22.311(3), c = 27.213(4) A and Z = 4. The crystal structure was solved by direct methods and refined to an R value of 0.056. The molecules adopt a pleated sheet conformation with the hydrophobic residues alternatively situated on the right and left of the main chain. In the crystallographic "a" direction, the molecules are linked by hydrogen bonds and form parallel pleated sheet-type structures.     

Crystal structure of polyglycine I

An electron diffraction study has been made of oriented polyglycine I (the β modification of polyglycine) and of single crystals grown from solution. The unit cell is very similar to that postulated by Astbu?y (1949). It is monoclinic with parameters a = 9.54 Å, b(chainaxis) = 7.044 Å, c = 3.67 Å and β = 113°. Examination of the possible structures suggests that polyglycine I does not have the familiar antiparallel pleated sheet, but rather the closely related antiparallel rippled sheet structure first described by Pauling &; Corey (1953a).     

Crystals and a low resolution structure of interleukin-2

Recombinant derived human interleukin-2 and an analog in which cysteine 125 has been replaced with alanine have been crystallized in a form suitable for x-ray diffraction. The crystals are triclinic, space group P1, with two protein molecules in the unit cell; unit cell parameters are a = 55.8 A, b = 40.1 A, c = 33.7 A, alpha = 90.0 degrees, beta = 109.3 degrees, gamma = 93.2 degrees. The interleukin-2 structure has been solved to 5.5 A resolution using heavy atom isomorphous replacement methods. The resultant low resolution model reveals a significant fraction of alpha helical secondary structure and outlines the overall tertiary structure of the molecule.     

Three-dimensional structure of proteinase K at 0.15-nm resolution

The crystal and molecular structure of proteinase K was determined by X-ray diffraction data to 0.15-nm resolution. The enzyme belongs to the subtilisin family with an active-site catalytic triad Asp39--His69--Ser224 but is a representative of a subgroup with a free Cys73 close to and 'below' the active His69. Besides this Cys72, proteinase K has two disulfide bonds, Cys34--Cys123 and Cys178--Cys249, which contribute to the stability of the tertiary structure consisting of an extended central parallel beta-sheet decorated by six alpha-helices, three short antiparallel beta-sheets, 18 beta-turns and involving several internal, structurally important water molecules. Proteinase K exhibits two Ca2+-binding sites, one very strong and the other weak, which were the sites of the heavy atoms (Pb2+, Sm3+) used to solve the crystal structure. The weak binding site is liganded to the N and C termini, Thr16 and Asp260, and is only incompletely coordinated by oxygen ligands. The strong binding site is coordinated in the form of a pentagonal bipyramid with the side chain carboxylate of Asp200 and the C = O of Pro175 as apex, and C = O of Val177 and four water molecules in the equatorial plane. Upon removal of this Ca2+, proteinase K loses activity which is interpreted in terms of a local structural deformation involving the substrate-recognition site (Ser132--Gly136), probably associated with a cis----trans isomerization of cis Pro171. Several water molecules are located in the active site. One, W335, is positioned in the 'oxyanion hole' and is displaced by the C = O of the scissile peptide bond of the substrate, as indicated by crystallographic studies with peptide chloromethane inhibitors. Based on these experiments, a reaction mechanism is proposed where the peptide substrate forms a three-stranded antiparallel pleated sheet with the recognition site of proteinase K consisting of Ser132--Leu133--Gly134 on one side and Gly100--Ser101 on the other, followed by expulsion of the oxyanion hole water W335 and hydrolytic cleavage by the Asp39--His69--Serr224 triad. These latter residues display low thermal motion corresponding to well-defined geometry and are hardly accessible to solvent molecules, whereas the recognition-site amino acids are more flexible and partially exposed to solvent.     

Conformational analysis of the beta sheet structure of poly-L-alanine and poly(L-alanine-glycine).

The β pleated sheet structures of poly-l-alanine and the polydipeptide (Ala-Gly)_n are analysed by conformational energy calculations, and the results are compared with the structures previously determined by X-ray methods. Structural parameters calculated for β poly-l-alanine using two different sets of potentials are in close agreement (within 5% or less) with the results of X-ray structure analysis (Arnott et al., 1967). For (Ala-Gly)_n, the alanyl and glycyl-glycyl intersheet distances calculated by assuming the model of Fraser et al. (1965) are comparable to those observed in the polydipeptide, but differ significantly from those of (Gly)_n and (Ala)_n. These calculations help establish the structural details of both the polydipeptide and the closely related Bombyx mori silk protein in their β form.     

Far-infrared spectra of sequential copolymers of amino acids with alkyl group side chains

Far-infrared spectra were measured for the sequential copolymers of amino acids with alkyl group side chains. The analysis of the spectra showed that (L -Ala-L -Ala-Gly)_n, (L -Ala-Gly)_n, (L -Ala-Gly-Gly)_n, (L -Val-L -Ala-L -Ala)_n, and (L -Val-L -Ala)_n, have the antiparallel pleated sheet structures and that the backbone conformations of (L -Val-L -Val-L -Ala)_n and (L -Val-L -Val-Gly)_n are the same as that of poly-L -valine. The far-infrared bands characteristic of the antiparallel pleated sheet structure were assigned on the basis of the result of the normal coordinate analysis of poly-L -alanine with this structure. The intersheet and interchain spacings of the sequential copolymers with the antiparallel pleated sheet structure were determined from the x-ray powder-diffraction patterns of these samples.     

X-ray structure analysis of the sodium salt of beijeran

The three-dimensional structure of the sodium salt of beijeran has been determined by X-ray fiber diffraction analysis. The acidic polysaccharide forms an extended twofold helix. Two chains are nestled tightly in a monoclinic unit cell of dimensions a=12.72, b=11.41, c (fiber axis)=24.62 A and gamma=123.7 degree in an antiparallel fashion. In the crystalline lattice, helices are stacked tightly to form a thick sheet along the vertical plane passing through the short diagonal of the basal net. Adjacent sheets associate via a network of sodium ions and water molecules embedded between them. The morphology of sodium beijeran in the solid state is consistent with its observed rheological properties.     

棉酚对鱼精DNA作用的量子生物学研究

紫外吸收光谱显示棉酚与DNA相互作用没有共价键形成.也不生成电荷迁移络台物.量子化学计算棉酚与胸腺嘧啶分子中的净电荷分布,发现沿两者结构式粗线上各原子的电荷恰好符号相反(图2).这表示棉酚很可能以共轭平面平行地插入到DNA分子双螺旋结构的碱基片层之间,与其中的胸腺嘧啶碱基以弱相互作用的极性键形成复合物.这种结合是可逆的,不影响DNA的一级结构.     

Structure of polyglycine I: a comparison of the antiparallel pleated and antiparallel rippled sheets

Packing energy calculations are made for two possible sheet structures of polyglycine I, i.e. the antiparallel pleated and rippled sheets. They indicate that the rippled sheet is the more stable structure and that its calculated lattice parameters are close to those experimentally determined. Furthermore, the results on the packing of pleated sheets of polyglycine improve understanding of the well-known model of silk fibroin structure of Marsh et al. (1955). They also suggest that the sheet structures of l-polypeptides with short side-chains should pack in monoclinic unit cells rather than the orthorhombic ones which are observed. A possible origin of this discrepancy is discussed.     

Complexation of trivalent lanthanide cations by inositols in the solid state: crystal structure and an FT-IR study of PrCl3.myo-inositol.9 H2O

The title compound, PrCl3.C6H12O6.9 H2O crystallized in the monoclinic space group P2(1)/n with cell dimensions a = 15.8293(3), b = 8.67750(10), c = 16.2292(3) A, beta = 107.0788(8) degrees, V = 2130.92(6) A3 and Z = 4. Each Pr ion is coordinated to nine oxygen atoms, two from the inositol and seven from water molecules, with Pr-O distances from 2.4729 to 2.6899 A; the other two water molecules are hydrogen-bonded. No direct contacts exist between Pr and Cl. There is an extensive network of hydrogen bonds formed by hydroxyl groups, water molecules, and chloride ions. The IR spectra of Pr-, Nd-, and Sm-inositol complexes are similar, which shows that the three metal ions have the same coordination mode. The IR results are consistent with the crystal structure.     

An X-Ray diffraction study of poly-L-ornithine hydrobromide

An X-ray study has been made of the synthetic polypeptide poly-L -ornithine hydrobromide to investigate whether, like the chemically related polypeptides poly-L -lysine and poly-L -arginine hydrochlorides, it can undergo conformational changes merely from variations in its degree of hydration. X-ray powder and fiber photographs of specimens with from half up to about three molecules of water per ornithine residue show features that suggest a “cross-β-pleated-sheet” structure. Each pleated sheet is formed from parallel chains and the sheets are piled up along the b axis. The spacings, which do not vary appreciably with hydration, can be satisfactorily indexed in terms of an orthogonal unit cell with a = 4.60 Å, b = 30.2 Å, and c = 6.64 Å. These dimensions are shown by models to be compatible with the proposed structure. Removal of the last half molecule of water results in a very diffuse pattern but on rehydration the sharp pattern reappears. Specimens containing four to nine molecules of water per residue show a quite different pattern. Reflections other than equatorial are absent in oriented diagrams except for a 5.4 Å diffuse streak across the meridian which is suggestive of an α-helical structure. Increasing the relative humidity from 86% to about 100% causes the a axis of the hexagonal unit cell to increase from 14.7 Å to 15.3 Å. On drying, the β structure reappears once again. These conformational changes are very similar to those observed in poly-L -lysine hydrochloride except that the latter shows a more stable α-helical form. This difference may be explained in terms of stabilizing hydrophobic interactions between side chains, since ornithine has a shorter side chain than lysine.     

Cesium cholate: determination of X-ray crystal structure indicates participation of the ring hydroxyl groups in metal binding

The crystal structure of cesium cholate, C(24)H(36)(OH)(3) COOCs has been determined with three-dimensional X-ray diffractometer data. It crystallized in the monoclinic space group P2(1) with unit-cell dimensions a = 11.543(5) A, b = 8.614(3) A, and c = 12.662(5) A, beta(deg) = 107.95(2), V = 1197.7 A(3) and Z = 2. The atomic parameters were refined to a final r = 0.0269 and R(omega) = 0.0280 for 2342 observed reflections. Each Cs(+) is coordinated to 7 oxygen atoms from 5 different cholate anions with Cs-O distances ranging from 2.957(4) A to 3.678(5) A. In this crystal, 5 cholates are coordinated with 1 Cs(+), and 5 Cs(+) are coordinated with 1 cholate anion. Carboxyl and all the 3 ring hydroxyl groups of cholate anion participate in binding to Cs(+) simultaneously, and there is no water molecule coordinated with the Cs(+). The pattern of successive rows arranged with polar (p) and non-polar (n) faces in apposition leads to the formation of a sandwich sheet structure with polar and non-polar channels. The Cs ions lie within the polar interior of the sandwich. The H-bond network is reorganized in forming cesium cholate from cholic acid. All the oxygen atoms in cholate anion are involved in H-bonding reciprocally or with water molecules to form an extensive 3-dimensional network of H-bonds. Compared with cholic acid and other similar type of steroids, the coordination structure and H-bonding of Cs cholate crystal are distinct.     

Crystallization and molecular structure of cyclic dodecadepsipeptide cyclo]D-Val-D-Hyi-Val-Hyi-(D-Val-Hyi-Val-D-Hyi)2-].2C3H60

The crystal structure of a synthetic analogue of meso-valinomycin, crystallized with two acetone molecules, has been solved by X-ray direct methods. The trigonal crystals belong to the P32 space group, with the number of molecules in the unit cell z = 3, and cell dimensions a = b = 15,2085 A, c = 29,3250 A, alpha = beta = 90 degrees, gamma = 120 degrees. The standard (R) and weighted (Rw) factors after the structure refinement of atoms C, N, O in anisotropic thermal motion approximation and with the contribution from H atoms taken into account are 0,070 and 0,082, respectively. The molecule adopts an asymmetric conformations stabilized by six amide intramolecular hydrogen bonds NH ... OC of the 4----4 type; one of those is strong and the other are weakened in different extent. The side chains occupy the external pseudoaxial positions towards the cyclic frame of the molecule, whereas six free ester carbonyl groups have different orientations. In contrast to meso-valinomycin, the analogue under study has no specific binding site for metal ions. The isopropyl side chains of D-Hyi(2) and Hyi(4) residues effectively shield, from both sides, the access to the inner molecular cavity.     

Crystal structure of a cyclomaltoheptaose-4-hydroxybiphenyl inclusion complex

The crystal structure of the inclusion complex of cyclomaltoheptaose (beta-cyclodextrin) with 4-hydroxybiphenyl was determined by single-crystal X-ray diffraction at 150K. The complex contains two cyclomaltoheptaose molecules, two 4-hydroxybiphenyl molecules, one ethanol molecule and fifteen water molecules in the asymmetric unit, and could be formulated as [2(C(42)H(70)O(35)).2(C(12)H(10)O).(C(2)H(6)O).15(H(2)O)]. It crystallized in the triclinic space group P1 with unit cell constants a=15.257(3), b=15.564(3), c=15.592(2)A, alpha=104.485(15) degrees , beta=101.066(14) degrees , gamma=104.330(17) degrees , V=3,343.6(10)A(3). In the crystal lattice, two beta-cyclodextrins form a head-to-head dimer jointed through hydrogen bonds. Two 4-hydroxybiphenyls were included in the dimer cavity with their hydroxyl groups protruding from two primary hydroxyl sides of the cyclodextrin molecules. The guest 4-hydroxybiphenyl molecules linked into a chain via a combination of an O-Hcdots, three dots, centeredO hydrogen bond and face-to-face pi-pi stacking of the phenyl rings. The crystal structure supports the calculation results indicating that the 2:2 inclusion complex formed by beta-cyclodextrin and 4-hydroxybiphenyl is the energetically favored structure.     

A crystal structure with features of an antiparallel α-pleated sheet

A single-crystal x-ray diffraction analysis of Boc-L -Ala-D -aIle-L -Ile-OMe has been carried out. The analysis has shown (a) that the tripeptide molecules have in part an α-extended conformation, the torsion angles of the L -Ala and D -aIle residues being φ₁ = ?75.1° and ψ₁ = ?25.8° and φ₂ = 67.3° and ψ₂ = 44.1°, respectively, and (b) that the molecules are organized in rippled planes where they occur in relative antiparallel orientation linked together side by side by H bonds. This molecular organization of the tripeptide corresponds closely to that of an antiparallel α-pleated sheet, and likely constitutes the first example of a structure of this kind for which a characterization at the atomic level has been achieved. A molecular dynamics study has shown that the molecular conformation of the tripeptide in the crystalline state is determined primarily by intermolecular interactions. © 1994 John Wiley & Sons, Inc.     

Structure of apoproteins in insect lipophorin

The two polypeptide chains of cockroach and locust lipophorins were separated and their amino acid compositions were determined. Circular dichroic spectra of the lipophorins and apolipophorin from 190 to 250 nm showed a single trough at 218 nm and a peak at 194 nm. Infrared spectra of the lipophorins in D2O showed a strong peak at 1625 cm-1 and a weak shoulder at 1693 cm-1 corresponding to v (pi, 0) and nu (0, pi) of antiparallel pleated sheet. The resonance frequency splitting delta nu = nu (0, pi) -nu (pi, 0) was 68 cm-1, which was larger than that of ordinary globular proteins containing antiparallel pleated sheet. From circular dichroic and infrared spectra it was concluded that lipophorins contained polypeptides rich in antiparallel pleated sheet with longer unbroken extensions than the case for ordinary globular proteins. Partial proteolytic digestion study of lipophorins with trypsin, chymotrypsin, and subtilisin showed that the larger apolipophorin (AL1) was exposed to the surface of the particle and the smaller apolipophorin (AL2) lay protected from the attack of the enzymes. Crosslinked products between AL1 and AL2 were readily obtained when dimethylsuberimidate or dimethyladipimidate was added to the lipophorin solution, without giving lipophorin dimers, suggesting that the two chains were located within 11 A from each other. Such structural features of insect lipoprotein were compared with other insect lipophorins and the human serum low-density lipoprotein (LDL). Similarities between lipophorins and LDL were found in the molecular weight, amino acid compositions, and the secondary structure of major apoproteins.     

Structure of inclusion complexes of cyclomaltoheptaose (cycloheptaamylose): crystal structure of the 1-adamantanemethanol adduct

Cyclomaltoheptaose (cycloheptaamylose) has been crystallized with 1-adamantanemethanol as the guest molecule. The complex crystallized in space group C222(1), with unit-cell dimensions a = 19.162 (13), b = 23.965 (17), and c = 32.597 (27) A. The structure was solved by rotation-translation search-methods. The cyclomaltoheptaose exists as a dimer in the crystal by means of extensive hydrogen-bonding across the secondary hydroxyl ends of two cyclomaltoheptaose molecules. The two halves of the dimer are related by a crystallographic two-fold axis. The primary hydroxyl ends of two adjacent cyclomaltoheptaose molecules are also related by a crystallographic two-fold axis, but do not directly hydrogen bond to one another. Instead, they are held in place by a strong hydrogen bond from the hydroxyl group of the 1-adamantanemethanol to a primary hydroxyl group on an adjacent cyclomaltoheptaose molecule. Other stabilizing hydrogen bonds are formed via three water molecules which are situated at the primary hydroxyl interface, and others that form parallel columns stabilizing the crystal structure. A unique feature of this complex is the presence of trapped water in the cavity at the secondary hydroxyl interface. This water is distributed over 3 disordered sites. Its presence blocks one possible site for the 1-adamantanemethanol, which, instead, binds near the primary hydroxyl end, with its hydroxyl group and part of the adamantane moiety protruding from the cyclomaltoheptaose.