Plasma Crystal as a Time Crystal

Plasma Physics Reports - The nonlinear development stage is studied of the instability of coupled waves in the planar plasma crystal in the external confining force field. It is assumed that the...     

Crystal packing effects on protein loops

The effects of crystal packing on protein loop structures are examined by (1) a comparison of loops in proteins that have been crystallized in alternate packing arrangements, and (2) theoretical prediction of loops both with and without the inclusion of the crystal environment. Results show that in a minority of cases, loop geometries are dependent on crystal packing effects. Explicit representation of the crystal environment in a loop prediction algorithm can be used to model these effects and to reconstruct the structures, and relative energies, of a loop in alternative packing environments. By comparing prediction results with and without the inclusion of the crystal environment, the loop prediction algorithm can further be used to identify cases in which a crystal structure does not represent the most stable state of a loop in solution. We anticipate that this capability has implications for structural biology.     

Crystal structure of methionine-enkephalin

The crystal structure of methionine-enkephalin has been determined by X-ray crystallography. There are two independent pentapeptides in the asymmetric unit and both display extended backbone conformations with their side chains arranged alternately below and above the backbone plane. The two molecules form a hydrogen-bonded head-to-tail dimer similar in conformation to one dimeric pair of leucine-enkephalin molecules in a previously reported crystal structure.     

Crystal structure of beta-D-psicopyranose

Here, we report the crystal structure of d-psicose, C(6)H(12)O(6), one of the rare sugars. The compound crystallizes as the beta-anomer with rarely observed in pyranose carbohydrate structures trans-gauche orientation of the hydroxymethyl group relative to the pyranosyl ring. The crystal system is orthorhombic, space group P2(1)2(1)2(1), Z=4, with cell dimensions a=7.727(2), b=8.672(2), c=11.123(3)A, V=745.3(3)A(3). The pyranosyl ring adopts chair (2)C(5) conformation. The crystal structure at 100(2)K is stabilized by three-dimensional network of O-Hcdots, three dots, centeredO and C-Hcdots, three dots, centeredO intermolecular hydrogen bonds.     

Surface Plasmon Induced Polarization Filter Based on Au Wires and Liquid Crystal Infiltrated Photonic Crystal Fibers

The polarization filter characteristics of Au wires and liquid crystal infiltrated photonic crystal fibers are investigated by using the finite element method. The nematic liquid crystal of E7 being injected into cladding air holes is benefit to induce large birefringence under controllable electrical field. The simulation results show that the surface plasmon resonance is strongly inspired by core modes in y-polarized direction. Meanwhile, the coupling between core modes in x-polarized direction and surface plasmon polaritons modes is faint. The confinement losses can achieve 446 dB/cm in y-polarized direction and 0.8 dB/cm in x-polarized direction at wavelength of 1550 nm in one of our designed fiber. The effects of fiber structural parameters and temperature are investigated with a view of tuning and optimizing the confinement loss spectrum. Own to the large contrast of confinement losses in two orthogonal directions, the designed Au wires and liquid crystal infiltrated photonic crystal fibers promise candidate for tunable polarization filter devices.     

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.     

Dependence of Protein Crystal Stability on Residue Charge States and Ion Content of Crystal Solvent

Protein crystallization is frequently induced by the addition of various precipitants, which directly affect protein solubility. In addition to organic cosolvents and long-chain polymers, salts belong to the most widely used precipitants in protein crystallography. However, despite such widespread usage, their mode of action at the atomistic level is still largely unknown. Here, we perform extensive molecular dynamics simulations of the villin headpiece crystal unit cell to examine its stability at different concentrations of sodium sulfate. We show that the inclusion of ions in crystal solvent at high concentration can prevent large rearrangements of the asymmetric units and a loss of symmetry of the unit cell without significantly affecting protein dynamics. Of importance, a similar result can be achieved by neutralizing several specific charged residues suggesting that they may play an active role in crystal destabilization due to unfavorable electrostatic interactions. Our results provide a microscopic picture behind salt-induced stabilization of a protein crystal and further suggest that adequate modeling of realistic crystallization conditions may be necessary for successful molecular dynamics simulations of protein crystals.     

Crystal packing analysis of Rhodopsin crystals

Oligomerization has been proposed as one of several mechanisms to regulate the activity of G protein-coupled receptors (GPCRs), but little is known about the structure of GPCR oligomers. Crystallographic analyses of two new crystal forms of rhodopsin reveal an interaction surface which may be involved in the formation of functional dimers or oligomers. New crystallization conditions lead to the formation of two crystal forms with similar rhodopsin-rhodopsin interactions, but changes in the crystal lattice are induced by the addition of different surfactant additives. However, the intermolecular interactions between rhodopsin molecules in these crystal structures may reflect the contacts necessary for the maintenance of dimers or oligomers in rod outer segment membranes. Similar contacts may assist in the formation of dimers or oligomers in other GPCRs as well. These new dimers are compared with other models proposed by crystallography or EM and AFM studies. The inter-monomer surface contacts are different for each model, but several of these models coincide in implicating helix I, II, and H-8 as contributors to the main contact surface stabilizing the dimers.     

Crystal structure of wild-type chaperonin GroEL

The 2.9A resolution crystal structure of apo wild-type GroEL was determined for the first time and represents the reference structure, facilitating the study of structural and functional differences observed in GroEL variants. Until now the crystal structure of the mutant Arg13Gly, Ala126Val GroEL was used for this purpose. We show that, due to the mutations as well as to the presence of a crystallographic symmetry, the ring-ring interface was inaccurately described. Analysis of the present structure allowed the definition of structural elements at this interface, essential for understanding the inter-ring allosteric signal transmission. We also show unambiguously that there is no ATP-induced 102 degrees rotation of the apical domain helix I around its helical axis, as previously assumed in the crystal structure of the (GroEL-KMgATP)(14) complex, and analyze the apical domain movements. These results enabled us to compare our structure with other GroEL crystal structures already published, allowing us to suggest a new route through which the allosteric signal for negative cooperativity propagates within the molecule. The proposed mechanism, supported by known mutagenesis data, underlines the importance of the switching of salt bridges.     

小檗胺结晶因素的研究

研究了小檗胺结晶与提取溶剂、萃取剂加入量及盐析的关系,得出提高工业生产小檗胺结晶得率的方法．     

Coupling Enhancement of Plasmonic Liquid Photonic Crystal Fiber

Plasmonics - In this paper, the coupling characteristics of a dual-core hybrid plasmonic liquid crystal photonic crystal fiber (PCF) is proposed and analyzed using full-vectorial finite-difference...     

苏云金杆菌Cyt类杀虫晶体蛋白及其特征

本文综述了国内外有关苏云金杆菌Cyt类杀虫晶体蛋白的分类、杀虫特性、作用机理 ;具有分子伴侣功能的 2 0kDa蛋白对cyt基因在大肠杆菌和苏云金杆菌中的表达的影响 ;以及利用Cyt类蛋白控制害虫对苏云金杆菌抗性的意义。     

Immunological Homology Between Crystal and Spore Protein of Bacillus thuringiensis

Spore suspensions containing about 0.3% crystals and crystal suspensions containing about 0.1% spores were obtained from cultures of Bacillus thuringiensis by extraction with a two-phase system. Both preparations were tested for the presence of contaminating material from vegetative cells and were judged to be clean. Solutions of spore protein were obtained by extracting broken spores with phosphate buffer followed by extraction with either alkali- or urea-mercaptoethanol. The alkali spore or urea spore extracts had the same isoelectric point as crystal protein solubilized with these reagents. An antiserum prepared against alkali crystal solution precipitated alkali or urea spore extracts and crystal solutions but not phosphate spore extracts or extracts of whole cells. Lines of identity between spore and crystal precipitates were observed by using the Ouchterlony double-diffusion technique. Absorption of the antiserum with an excess of urea spore extract caused a disappearance of the precipitin bands originating from the spore protein and the homologous bands from the crystal protein. The results suggest that the crystal and endospore contain one or more common proteins.     

Crystal structures of active LytM

Lysostaphin-type enzymes are metalloendopeptidases that are present in bacteriophages and in bacteria. They share the catalytic domain, but normally contain other domains as well. The well-characterized enzymes in this group are all specific for the pentaglycine crosslinks in the cell walls of some Gram-positive bacterial species. Lysostaphin-type enzymes are synthesized as secreted preproenzymes and require proteolytic activation for maturation. Although lysostaphin, the prototypical peptidase in the group, is widely used as a tool in biotechnology and developed as an antistaphylococcal agent, the detailed structure of this enzyme is unknown. So far, only one lysostaphin-type enzyme, the Staphylococcus aureus autolysin LytM, has been crystallized in its full-length, inactive form. Here, we describe the synthesis of a convenient reporter substrate, characterize the metal and pH-dependence of an active LytM fragment, and present its crystal structure in three crystal forms at different pH values that either support or do not support activity. In all structures, we find an extended, long and narrow groove that has the active site at its bottom and is delineated on the sides by the most flexible regions of the molecule. In two cases, the groove is partially filled by a loop of a neighbouring molecule in the crystal. As the loop contains three consecutive glycine residues, this crystal packing effect supports the interpretation that the groove is the substrate-binding cleft. To characterize the substrate-binding mode more closely, a phosphinate analogue of tetraglycine was synthesized. Although tetraglycine is a substrate of the active LytM fragment, the phosphinate analogue turned out to be a very poor inhibitor. Crystals that were grown in its presence contained an L+-tartrate molecule from the crystallization buffer and not the phosphinate in the active site.     

Crystal protein formed by Bacillus subtilis cells.

Electron microscopic investigation of ultrathin sections of Bacillus subtilis Cgr4 cells revealed the presence of crystal-like inclusions which were formed of spheric homogeneous subunits. The frequency of cells with a crystal-like inclusion in the culture approached 1%. The appearance of the crystal protein in cells coincided in time with spore morphogenesis. However, the process of crystal protein formation and sporulation are two alternatives: the cells either form the crystal protein or continue spore morphogenesis. Fractionation of cells in the stationary growth phase on a Percoll density gradient showed that the cells containing the crystal protein accumulated in the fraction corresponding to a 1.14-g/ml Percoll density. The cells were disintegrated by sonication, and alkaline-extracted proteins were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. After sodium dodecyl sulfate-gel electrophoresis, the fraction enriched with crystal-containing cells showed practically a single band with a molecular weight of 47,000 that corresponded to the crystal-forming protein. The antigenic features and amino acid composition indicated certain similarities between the crystal-forming protein in B. subtilis Cgr4 cells and the spore coat protein.     

Crystal structure of beta-D-galactopyranosylamine

The crystal structure of beta-D-galactopyranosylamine (C6H13O5N) is orthorhombic, with space group P2(1)2(1)2(1), and cell dimensions a = 7.703(2), b = 7.788(2), c = 12.645(3) A, V = 757.612 A3, Z = 4; Dc and Dm are 1.573 and 1.587 cm-3, respectively. Using MoK alpha radiation (lambda = 0.7107 A), 2841 reflections were measured on a CAD-4 diffractometer. The structure was solved by using MULTAN-78, and refined anisotropically for the non-hydrogen positional and thermal parameters. Final agreement indices are R(F) = 0.074, wR(F) = 0.086, and S = 2.1523. The conformation is 4C1(D). The orientation of the primary alcohol group is gauche/trans. An unexpected feature of the hydrogen bonding is that the amino group accepts a strong O-H---N bond, but has no donor functionality in the crystal structure.     

Crystal structure of a theta-class glutathione transferase.

Glutathione S-transferases (GSTs) are a family of enzymes involved in the cellular detoxification of xenotoxins. Cytosolic GSTs have been grouped into four evolutionary classes for which there are representative crystal structures of three of them. Here we report the first crystal structure of a theta-class GST. So far, all available GST crystal structures suggest that a strictly conserved tyrosine near the N-terminus plays a critical role in the reaction mechanism and such a role has been convincingly demonstrated by site-directed mutagenesis. Surprisingly, the equivalent residue in the theta-class structure is not in the active site, but its role appears to have been replaced by either a nearby serine or by another tyrosine residue located in the C-terminal domain of the enzyme.     

Analysis of the Crystal Antigens of Bacillus thuringiensis by Gel Diffusion

S ummary . The antigenic patterns of the crystal protein inclusions of Bacillus thuringiensis were determined. No specific antigenic patterns associated with previously described subgroups of this species were found. A larger number of categories of crystal antigen than of flagellar antigen or esterase type were found. In some cases isolates indistinguishable in classifications based on flagellar antigens or esterase types could be subdivided by their crystal antigenic pattern. The use of crystal antigens in classification is discussed.     

表面活性剂液晶模板制备纳米材料的研究进展

纳米材料因为具有纳米效应而被大量研究。表面活性剂由于种类繁多、结构各异,不同的双亲分子形成各种聚集体结构的能力也并不相同,且受多种因素影响,所以在液晶模板合成纳米材料中被广泛应用。近年来表面活性剂液晶模板合成纳米材料的方法得到了迅速发展,正表现出广阔的应用前景。     

Preparation of Monodomain Liquid Crystal Elastomers and Liquid Crystal Elastomer Nanocomposites

LCEs are shape-responsive materials with fully reversible shape change and potential applications in medicine, tissue engineering, artificial muscles, and as soft robots. Here, we demonstrate the preparation of shape-responsive liquid crystal elastomers (LCEs) and LCE nanocomposites along with characterization of their shape-responsiveness, mechanical properties, and microstructure. Two types of LCEs — polysiloxane-based and epoxy-based — are synthesized, aligned, and characterized. Polysiloxane-based LCEs are prepared through two crosslinking steps, the second under an applied load, resulting in monodomain LCEs. Polysiloxane LCE nanocomposites are prepared through the addition of conductive carbon black nanoparticles, both throughout the bulk of the LCE and to the LCE surface. Epoxy-based LCEs are prepared through a reversible esterification reaction. Epoxy-based LCEs are aligned through the application of a uniaxial load at elevated (160 °C) temperatures. Aligned LCEs and LCE nanocomposites are characterized with respect to reversible strain, mechanical stiffness, and liquid crystal ordering using a combination of imaging, two-dimensional X-ray diffraction measurements, differential scanning calorimetry, and dynamic mechanical analysis. LCEs and LCE nanocomposites can be stimulated with heat and/or electrical potential to controllably generate strains in cell culture media, and we demonstrate the application of LCEs as shape-responsive substrates for cell culture using a custom-made apparatus.