Molecular modelling of the three-dimensional structure and conformational flexibility of bacterial lipopolysaccharide.

Molecular modelling techniques have been applied to calculate the three-dimensional architecture and the conformational flexibility of a complete bacterial S-form lipopolysaccharide (LPS) consisting of a hexaacyl lipid A identical to Escherichia coli lipid A, a complete Salmonella typhimurium core oligosaccharide portion, and four repeating units of the Salmonella serogroup B O-specific chain. X-ray powder diffraction experiments on dried samples of LPS were carried out to obtain information on the dimensions of the various LPS partial structures. Up to the Ra-LPS structure, the calculated model dimensions were in good agreement with experimental data and were 2.4 nm for lipid A, 2.8 nm for Re-LPS, 3.5 nm for Rd-LPS, and 4.4 nm for Ra-LPS. The maximum length of a stretched S-form LPS model bearing four repeating units was evaluated to be 9.6 nm; however, energetically favored LPS conformations showed the O-specific chain bent with respect to the Ra-LPS portion and significantly smaller dimensions (about 5.0 to 5.5 nm). According to the calculations, the Ra-LPS moiety has an approximately cylindrical shape and is conformationally well defined, in contrast to the O-specific chain, which was found to be the most flexible portion within the molecule.     

The three-dimensional structure of P2 myelin protein.

The three-dimensional structure of P2 protein from peripheral nervous system myelin has been determined at 2.7 A resolution by X-ray crystallography. The single isomorphous replacement/anomalous map was interpreted using skeletonized electron density on a computer graphics system. An atomic model was built using fragment fitting. The structure forms a compact 10-stranded up-and-down beta-barrel which encapsulates residual electron density that we interpret as a fatty acid molecule. This beta-barrel shows some similarity to, but is different from, the retinol binding protein family of structures. The relationship of the P2 structure to a family of cytoplasmic, lipid binding proteins is described.     

Viral cystatin evolution and three-dimensional structure modelling: A case of directional selection acting on a viral protein involved in a host-parasitoid interaction

Background  

In pathogens, certain genes encoding proteins that directly interact with host defences coevolve with their host and are subject to positive selection. In the lepidopteran host-wasp parasitoid system, one of the most original strategies developed by the wasps to defeat host defences is the injection of a symbiotic polydnavirus at the same time as the wasp eggs. The virus is essential for wasp parasitism success since viral gene expression alters the immune system and development of the host. As a wasp mutualist symbiont, the virus is expected to exhibit a reduction in genome complexity and evolve under wasp phyletic constraints. However, as a lepidopteran host pathogenic symbiont, the virus is likely undergoing strong selective pressures for the acquisition of new functions by gene acquisition or duplication. To understand the constraints imposed by this particular system on virus evolution, we studied a polydnavirus gene family encoding cyteine protease inhibitors of the cystatin superfamily.     

The three-dimensional structure of retinol-binding protein

The complex of retinol with its carrier protein, retinol-binding protein (RBP) has been crystallized and its three-dimensional structure determined using X-ray crystallography. Its most striking feature is an eight-stranded up-and-down beta barrel core that completely encapsulates the retinol molecule. The retinol molecule lies along the axis of the barrel with the beta-ionone ring innermost and the tip of the isoprene tail close to the surface.     

Molecular basis of the Tfs1/Ira2 interaction: a combined protein engineering and molecular modelling study

Tfs1p and Ylr179cp are yeast proteins belonging to the PEBP family. Tfs1p, but not Ylr179cp, has been shown to interact with and inhibit Ira2p, a GTPase-activating protein of Ras. Tfs1p has been shown to be a specific inhibitor of the CPY protease and the 3D structure of the complex has been resolved. To shed light on the molecular determinants of Tfs1p involved in the Tfs1/Ira2 interaction, the 3D structure of Ylr179cp has been modelled and compared to that of Tfs1p. Tfs1p point mutants and Tfs1 hybrid proteins combining regions of Tfs1p and Ylr179cp were also designed and their function was tested. Results, interpreted from a structural point of view, show that the accessibility of the surface pocket of Tfs1p, its N-terminal region and the specific electrostatic properties of a large surface region containing these two elements, play a crucial role in this interaction.     

The three-dimensional structure of a helix-less variant of intestinal fatty acid-binding protein.

Intestinal fatty acid-binding protein (I-FABP) is a cytosolic 15.1-kDa protein that appears to function in the intracellular transport and metabolic trafficking of fatty acids. It binds a single molecule of long-chain fatty acid in an enclosed cavity surrounded by two five-stranded antiparallel beta-sheets and a helix-turn-helix domain. To investigate the role of the helical domain, we engineered a variant of I-FABP by deleting 17 contiguous residues and inserting a Ser-Gly linker (Kim K et al., 1996, Biochemistry 35:7553-7558). This variant, termed delta17-SG, was remarkably stable, exhibited a high beta-sheet content and was able to bind fatty acids with some features characteristic of the wild-type protein. In the present study, we determined the structure of the delta17-SG/palmitate complex at atomic resolution using triple-resonance 3D NMR methods. Sequence-specific 1H, 13C, and 15N resonance assignments were established at pH 7.2 and 25 degrees C and used to define the consensus 1H/13C chemical shift-derived secondary structure. Subsequently, an iterative protocol was used to identify 2,544 NOE-derived interproton distance restraints and to calculate its tertiary structure using a unique distance geometry/simulated annealing algorithm. In spite of the sizable deletion, the delta17-SG structure exhibits a backbone conformation that is nearly superimposable with the beta-sheet domain of the wild-type protein. The selective deletion of the alpha-helical domain creates a very large opening that connects the interior ligand-binding cavity with exterior solvent. Unlike wild-type I-FABP, fatty acid dissociation from delta17-SG is structurally and kinetically unimpeded, and a protein conformational transition is not required. The delta17-SG variant of I-FABP is the only wild-type or engineered member of the intracellular lipid-binding protein family whose structure lacks alpha-helices. Thus, delta17-SG I-FABP constitutes a unique model system for investigating the role of the helical domain in ligand-protein recognition, protein stability and folding, lipid transfer mechanisms, and cellular function.     

Identifying true protein complex constituents in interaction proteomics: The example of the DMXL2 protein complex

A typical high-sensitivity antibody affinity purification-mass spectrometry experiment easily identifies hundreds of protein interactors. However, most of these are non-valid resulting from multiple causes other than interaction with the bait protein. To discriminate true interactors from off-target recognition, we propose to differentially include an (peptide) antigen during the antibody incubation in the immuno-precipitation experiment. This contrasts the specific antibody-bait protein interactions, versus all other off-target protein interactions. To exemplify the power of the approach, we studied the DMXL2 interactome. From the initial six immuno-precipitations, we identified about 600 proteins. When filtering for interactors present in all anti-DMXL2 antibody immuno-precipitation experiments, absent in the bead controls, and competed off by the peptide antigen, this hit list is reduced to ten proteins, including known and novel interactors of DMXL2. Together, our approach enables the use of a wide range of available antibodies in large-scale protein interaction proteomics, while gaining specificity of the interactions.     

The interaction of proteins with hydroxyapatite. I. Role of protein charge and structure

The criteria for elution of proteins from hydroxyapatite columns were examined as a function of (1) protein isoelectric point (22 proteins with isoelectric points between 3.5 and 11.0); (2) ionic nature of eluant (Na salts of PO4, F-, Cl-, SCN-, ClO-4, and CaCl2); and (3) structural differences between related proteins. It was found that proteins can be classified into three groups: (1) basic proteins, which elute at similar, moderate molarities of PO4, F-, Cl-, SCN-, and ClO-4, and low (less than 0.003 M) Ca2+; (2) acidic proteins which elute at about equal moderate molarities of PO4 and F-, but do not elute with Ca2+ and usually not with Cl-; (3) neutral proteins, which elute with PO4, F-, and Cl-, but show a strong anion specificity, and do not elute with Ca2+ or SCN-. Furthermore, individual specific polar groups are not in general crucial to binding or desorption, and variations in structure, other than major loosening, do not influence strongly the pattern of protein-hydroxyapatite interaction.     

The SWISS-MODEL workspace: a web-based environment for protein structure homology modelling

MOTIVATION: Homology models of proteins are of great interest for planning and analysing biological experiments when no experimental three-dimensional structures are available. Building homology models requires specialized programs and up-to-date sequence and structural databases. Integrating all required tools, programs and databases into a single web-based workspace facilitates access to homology modelling from a computer with web connection without the need of downloading and installing large program packages and databases. RESULTS: SWISS-MODEL workspace is a web-based integrated service dedicated to protein structure homology modelling. It assists and guides the user in building protein homology models at different levels of complexity. A personal working environment is provided for each user where several modelling projects can be carried out in parallel. Protein sequence and structure databases necessary for modelling are accessible from the workspace and are updated in regular intervals. Tools for template selection, model building and structure quality evaluation can be invoked from within the workspace. Workflow and usage of the workspace are illustrated by modelling human Cyclin A1 and human Transmembrane Protease 3. AVAILABILITY: The SWISS-MODEL workspace can be accessed freely at http://swissmodel.expasy.org/workspace/     

HLA—DRα＊0101、DRβ1＊04051和DRβ1＊07011的分子克隆、测序及空间结构模建

目的：Y国探索HLA（human leukocyte antigens,HLA)不同分子的空间结构差异与功能之间的关系以及结构差异能否对预测造血干细胞移植GVHD（graft-versus-host disease,GVHD)的发生奠定基础。方法：提取人外周血总RNA,RT-PCR扩增HLA——DR等位基因全序,连接、转化大肠杆菌后并测序,将第二外显子氨基酸序列输入微机,通过INTER-NET传送至SWISS-MODELLING蛋白质空间结构模建服务器进行结构模建,结果：本文反转录了2例健康无血缘关系个体的HLA-DR位点基因全序,测序结果与HLA-DRα*0101、DRβ1*04051和DRβ1*07011的公布序列完全一致。对后两者的蛋白质空间结构模建发现它们在空间结构上存在显著差异。结论：对HLA基因位点进行全长测序可以明确判断基因型别;空间结构模建可以直观地辨别HLA不同舂子在空间结构上的差异。这为研究HLA结构与功能的关系以及HLA不完全相合的造血干细胞移植后预测GVHD的研究提供实验基础。     

Function and structure of Drosophila glycans

Through the application of classic organismal genetic strategies, such as mutagenesis and interaction screens, Drosophila melanogaster provides opportunities to understand glycan function. For instance, screens for Drosophila genes that establish dorsal-ventral polarity in the embryo or that influence cellular differentiation through signal modulation have identified putative glycan modifying enzymes. Other genetic and molecular approaches have demonstrated the existence of phylogenetically conserved and novel oligosaccharide processing activities and carbohydrate binding proteins. While the structural characterization of Drosophila oligosaccharide diversity has lagged behind the elucidation of glycan function, landmarks are becoming apparent in the carbohydrate terrain. For instance, O-linked GlcNAc and mucins, spatially and temporally regulated N-linked oligosaccharide expression, glycosphingolipids, heparan sulfate, chondroitin sulfate and polysialic acid have all been described. A major challenge for Drosophila glycobiology is to expand the oligosaccharide structural database while endeavoring to link glycan characterization to functional analysis. The completion of the Drosophila genome sequencing project will yield a broad portfolio of glycosyltransferases, glycan modifying enzymes and lectins requiring characterization. To this end, the great range of genetic tools that allow the controlled spatial and temporal expression of transgenes in Drosophila will permit unprecedented manipulation of glycosylation in a whole organism.     

The three-dimensional structure of the seed storage protein phaseolin at 3 A resolution.

The polypeptides of the trimeric seed storage protein phaseolin comprise two structurally similar units each made up of a beta-barrel and an alpha-helical domain. The beta-barrel has the 'jelly-roll' folding topology of the viral coat proteins and the alpha-helical domain shows structural similarity to the helix-turn-helix motif found in certain DNA-binding proteins.     

Molecular mechanism of enzyme inhibition: prediction of the three-dimensional structure of the dimeric trypsin inhibitor from Leucaena leucocephala by homology modelling

Serine proteinase inhibitors are widely distributed in nature and inhibit the activity of enzymes like trypsin and chymotrypsin. These proteins interfere with the physiological processes such as germination, maturation and form the first line of defense against the attack of seed predator. The most thoroughly examined plant serine proteinase inhibitors are found in the species of the families Leguminosae, Graminae, and Solanaceae. Leucaena leucocephala belongs to the family Leguminosae. It is widely used both as an ornamental tree as well as cattle food. We have constructed a three-dimensional model of a serine proteinase inhibitor from L. leucocephala seeds (LTI) complexed with trypsin. The model was built based on its comparative homology with soybean trypsin inhibitor (STI) using the program, MODELLER6. The quality of the model was assessed stereochemically by PROCHECK. LTI shows structural features characteristic of the Kunitz type trypsin inhibitor and shows 39% residue identity with STI. LTI consists of 172 amino acid residues and is characterized by two disulfide bridges. The protein is a dimer with the two chains being linked by a disulfide bridge. Despite the high similarity in the overall tertiary structure, significant differences exist at the active site between STI and LTI. The present study aims at analyzing these interactions based on the available amino acid sequences and structural data. We have also studied some functional sites such as phosphorylation, myristoylation, which can influence the inhibitory activity or complexation with other molecules. Some of the differences observed at the active site and functional sites can explain the unique features of LTI.