PDB2MultiGIF: A Web Tool to Create Animated Images of Molecules

A new web tool, PDB2MultiGIF (http://www.dkfz-heidelberg.de/spec/pdb2mgif/),which converts the topological information (atom types, 3D coordinates, molecular connectivity) of molecules (given in PDB format [1]) to a series of animated images (in GIF Format) [2] is described. The molecular visualisation program RASMOL [3] is used to generate the images.Electronic Supplementary Material available.     

LOX-DB-- database on lipoxygenases

SUMMARY: Lipoxygenases are a family of enzymes involved in a variety of human diseases like inflammation, asthma, artherosclerosis and cancer. The lipoxygenases database (LOX-DB) aims to be a web accessible compendium of information in particular on the mammalian members of this multigene family. This resource includes molecular structures, reference data, tools for structural and computational analysis as well as links to related information maintained by others. The data can be retrieved by the use of various search options and analyzed applying publicly available visualization tools. AVAILABILITY: LOX-DB is available at http://www.dkfz-heidelberg.de/spec/lox-db/     

PATH: a task for the inference of phylogenies

Phylogenetic Analysis Task in Husar (PATH) is a task for the inference of phylogenies. It executes three phylogenetic methods and automatically chooses the evolutionary model for each set of data. The output of the tasks shows the consensus trees together with full results obtained from all executed methods. AVAILABILITY: PATH is available at the German EMBnet node after registration via www at http://genome.dkfz-heidelberg.de     

WWW access to the SYSTERS protein sequence cluster set

SUMMARY: We present a Web server where the SYSTERS cluster set of the non-redundant protein database consisting of sequences from SWISS-PROT and PIR is being made available for querying and browsing. The cluster set can be searched with a new sequence using the SSMAL search tool. Additionally, a multiple alignment is generated for each cluster and annotated with domain information from the Pfam protein family database. AVAILABILITY: The server address is http://www.dkfz-heidelberg.de/tbi/services/cluster/ systersform     

QuickLIMS: facilitating the data management for DNA-microarray fabrication

SUMMARY: QuickLIMS is a Microsoft Access-based laboratory information and management system, capable of processing all information for microarray production. The program's operational flow is protocol-based, dynamically adapting to changes of the process. It interacts with the laboratory robot and with other database systems over the network, and it represents a complete solution for the management of the entire manufacturing process. AVAILABILITY AND SUPPLEMENTARY INFORMATION: http://www.dkfz-heidelberg.de/kompl_genome/Other/QuickLims/index.html     

SWEET-DB: an attempt to create annotated data collections for carbohydrates

Complex carbohydrates are known as mediators of complex cellular events. Concerning their structural diversity, their potential of information content is several orders of magnitude higher in a short sequence than any other biological macromolecule. SWEET-DB (http://www.dkfz.de/spec2/sweetdb/) is an attempt to use modern web techniques to annotate and/or cross-reference carbohydrate-related data collections which allow glycoscientists to find important data for compounds of interest in a compact and well-structured representation. Currently, reference data taken from three data sources can be retrieved for a given carbohydrate (sub)structure. The sources are CarbBank structures and literature references (linked to NCBI PubMed service), NMR data taken from SugaBase and 3D co-ordinates generated with SWEET-II. The main purpose of SWEET-DB is to enable an easy access to all data stored for one carbohydrate structure entering a complete sequence or parts thereof. Access to SWEET-DB contents is provided with the help of separate input spreadsheets for (sub)structures, bibliographic data, general structural data like molecular weight, NMR spectra and biological data. A detailed online tutorial is available at http://www.dkfz.de/spec2/sweetdb/nar/.     

In situ analysis of gene expression in Xenopus embryos

The molecular anatomy of the vertebrate embryo was systematically analysed through gene expression during early development of the Xenopus frog using whole-mount in situ hybridization. Expression patterns are documented and assembled into the database Axeldb (http://www.dkfz-heidelberg.de/abt0135/axeldb.htm). Synexpression groups representing genes with shared, complex expression pattern that predict molecular pathways involved in patterning and differentiation have been identified. These sets of co-regulated genes show a striking similarity with operons, and may be a key determinant facilitating evolutionary change leading to animal diversity.     

Axeldb: a Xenopus laevis database focusing on gene expression

Axeldb is a database storing and integrating gene expression patterns and DNA sequences identified in a large-scale in situ hybridization study in Xenopus laevis embryos. The data are organised in a format appropriate for comprehensive analysis, and enable comparison of images of expression pattern for any given set of genes. Information on literature, cDNA clones and their availability, nucleotide sequences, expression pattern and accompanying pictures are available. Current developments are aimed toward the interconnection with other databases and the integration of data from the literature. Axeldb is implemented using an ACEDB database system, and available through the web at http://www.dkfz-heidelberg.de/abt0135/axeldb.htm     

The SYSTERS protein sequence cluster set

The SYSTERS (short for SYSTEmatic Re-Searching) protein sequence cluster set consists of the classification of all sequences from SWISS-PROT and PIR into disjoint protein family clusters and hierarchically into superfamily and subfamily clusters. The cluster set can be searched with a sequence using the SSMAL search tool or a traditional database search tool like BLAST or FASTA. Additionally a multiple alignment is generated for each cluster and annotated with domain information from the Pfam database of protein domain families. A taxonomic overview of the organisms covered by a cluster is given based on the NCBI taxonomy. The cluster set is available for querying and browsing at http://www.dkfz-heidelberg. de/tbi/services/cluster/systersform     

Rapid generation of a representative ensemble of N-glycan conformations

Glycosylated proteins are ubiquitous components of extracellular matrices and cellular surfaces where their oligosaccharide moieties are implicated in a wide range of cell-cell and cell-matrix recognition events. Glycans constitute highly flexible molecules. Only a small number of glycan X-ray structures is available for which sufficient electron density for an entire oligosaccharide chain has been observed. An unambiguous structure determination based on NMR-derived geometric constraints alone is often not possible. Time consuming computational approaches such as Monte Carlo calculations and molecular dynamics simulations have been widely used to explore the conformational space accessible to complex carbohydrates. The generation of a comprehensive data base for N-glycan fragments based on long time molecular dynamics simulations is presented. The fragments are chosen in such a way that the effects of branched N-glycan structures are taken into account. The prediction database constitutes the basis of a procedure to generate a complete set of all possible conformations for a given N-glycan. The constructed conformations are ranked according to their energy content. The resulting conformations are in reasonable agreement with experimental data. A web interface has been established (http://www.dkfz.de/spec/glydict/), which enables to input any N-glycan of interest and to receive an ensemble of generated conformations within a few minutes.     

Structure of a glycoconjugate in solution and in complex with an antibody Fv fragment

By use of heteronuclear (¹³c, ¹H) NMR methods, the threedimensionalstructure and dynamia of the glycoconjugate estrone-3-glucuronide(E3G) uniformly ¹³c enriched in the glucuronic acid moiety hasbeen probed both in free solution and in association with ananti-E3G antibody singlechain Fv fragment. The glycan is foundto exist in multiple conformations in free solution, with particularlylarge torsional fluctuations about the glycosidic linkage .Resonance assignments and distance restraints for the glycococonjugatein the bound state were obtained from heteronuclear protonarbon-carbon-proton-COSYand isotopeedited NOESY techniques, respectively. Quantitationof the NOE data with a full-relaxation matrix approach showedthat the antibody selects a conformation from the solution repertoirewhich does not correspond with either of the two lowest energyconformations of the free glycan, and the internal energy ofthe glycan in the bound state is estimated to be at most 15kcal/mol higher than the global minimum energy conformation.The glucuronide moiety undergoes a stacking interaction withan aromatic ring in the binding site, and both ring-currentshifts and nuclear Overhauser effects computed from the predictedboundstate conformation are in good agreement with experiment.The bound-state conformation is also in goad agreement withpreliminary x-ray data on a related complex. NMR estrone antibody ring current shifts     

Molecular modeling of a disialylated monofucosylated biantennary glycan of theN-acetyllactosamine type

The conformations of a disialylated monofucosylated biantennary glycan of theN-acetyllactosamine type were analysed using the Tripos 5.3 force field from the Sybyl software currently used for molecular modelling. The conformation of each glycosidic linkage was calculated when included in oligosaccharide structures of up to 5 units and the influence of the glycosidic environment on the overall structure was measured. The study clearly shows that the conformation of a branched glycan cannot result from the simple addition of the different low energy conformers of each of the glycosidic linkages constituting the glycan structure. The asymmetrical conformation of the two antennae was demonstrated. The lowest energy conformations of the overall glycan structure were built and classified into 5 main models: the Y, T, bird and broken wing conformations already described and a new one called the back folded wing conformation.     

Human disease glycomics: technology advances enabling protein glycosylation analysis – part 1

Introduction: Protein glycosylation is recognized as an important post-translational modification, with specific substructures having significant effects on protein folding, conformation, distribution, stability and activity. However, due to the structural complexity of glycans, elucidating glycan structure-function relationships is demanding. The fine detail of glycan structures attached to proteins (including sequence, branching, linkage and anomericity) is still best analysed after the glycans are released from the purified or mixture of glycoproteins (glycomics). The technologies currently available for glycomics are becoming streamlined and standardized and many features of protein glycosylation can now be determined using instruments available in most protein analytical laboratories.

Areas covered: This review focuses on the current glycomics technologies being commonly used for the analysis of the microheterogeneity of monosaccharide composition, sequence, branching and linkage of released N- and O-linked glycans that enable the determination of precise glycan structural determinants presented on secreted proteins and on the surface of all cells.

Expert commentary: Several emerging advances in these technologies enabling glycomics analysis are discussed. The technological and bioinformatics requirements to be able to accurately assign these precise glycan features at biological levels in a disease context are assessed.     

A molecular dynamics study of the effect of glycosidic linkage type in the hemicellulose backbone on the molecular chain flexibility

The macromolecular conformation of the constituent polysaccharides in lignocellulosic biomass influences their supramolecular interactions, and therefore their function in plants and their performance in technical products. The flexibility of glycosidic linkages from the backbone of hemicelluloses was studied by evaluating the conformational freedom of the φ and ψ dihedral angles using molecular dynamic simulations, additionally selected molecules were correlated with experimental data by nuclear magnetic resonance spectroscopy. Three types of β‐(1→4) glycosidic linkages involving the monosaccharides (Glcp, Xylp and Manp) present in the backbone of hemicelluloses were defined. Different di‐ and tetrasaccharides with combinations of such sugar monomers from hemicelluloses were simulated, and free energy maps of the φ – ψ space and hydrogen‐bonding patterns were obtained. The glycosidic linkage between Glc‐Glc or Glc‐Man (C‐type) was the stiffest with mainly one probable conformation; the linkage from Man‐Man or Man‐Glc (M‐type) was similar but with an increased probability for an alternative conformation making it more flexible, and the linkage between two Xyl‐units (X‐type) was the most flexible with two almost equally populated conformations. Glycosidic linkages of the same type showed essentially the same conformational space in both disaccharides and in the central region of tetrasaccharides. Different probabilities of glycosidic linkage conformations in the backbone of hemicelluloses can be directly estimated from the free energy maps, which to a large degree affect the overall macromolecular conformations of these polymers. The information gained contributes to an increased understanding of the function of hemicelluloses both in the cell wall and in technical products.     

Methodological approaches and insights on protein aggregation in biological systems

Introduction: The proper folding of native proteins is critical and dynamic, but inherently unstable. Therefore, proteins eventually end up adopting misfolded conformations which compromise their function and may even trigger aggregation. Risk factors for neurodegenerative, metabolic and heart diseases compromise cellular protein quality-control systems, promoting protein aggregation. Multiple protein post-translational modifications dynamically regulate protein aggregation and disaggregation in a very complex, intricate and delicate balance.

Areas covered: Herein, we overview the more promising techniques and approaches for the elucidation of the biological implications of protein aggregation. The particular insights provided by different techniques were discriminated and several examples of post-translational modifications together with their targets were pooled and critically discussed, representing promising future therapeutic targets.

Expert commentary: In the years to come, differences between physiological and pathological protein aggregation will certainly become easier to determine. Techniques such as hydrogen/deuterium exchange, circular dichroism spectroscopy and novel mass spectrometry-based approaches are being optimized and are expected to introduce inhibitors of protein aggregation into the clinic. However, protein aggregation is not an isolated phenomenon, but rather influenced by multiple cellular components which complete knowledge is still far.     

The Database of Ribosomal Cross-links: an update.

The Database of Ribosomal Cross-links (DRC) was created in 1997. Here we describe new data incorporated into this database and several new features of the DRC. The DRC is freely available via World Wide Web at http://visitweb.com/database/ or http://www. mpimg-berlin-dahlem.mpg.de/ approximately ag_ribo/ag_brimacombe/drc/     

dbSWEET: An Integrated Resource for SWEET Superfamily to Understand,Analyze and Predict the Function of Sugar Transporters in Prokaryotes and Eukaryotes

SWEET (Sweet Will Eventually be Exported Transporter) proteins have been recently discovered and form one of the three major families of sugar transporters. Homologs of SWEET are found in both prokaryotes and eukaryotes. Bacterial SWEET homologs have three transmembrane segments forming a triple-helical bundle and the functional form is dimers. Eukaryotic SWEETs have seven transmembrane helical segments forming two triple-helical bundles with a linker helix. Members of SWEET homologs have been shown to be involved in several important physiological processes in plants. However, not much is known regarding the biological significance of SWEET homologs in prokaryotes and in mammals. We have collected more than 2000 SWEET homologs from both prokaryotes and eukaryotes. For each homolog, we have modeled three different conformational states representing outward open, inward open and occluded states. We have provided details regarding substrate-interacting residues and residues forming the selectivity filter for each SWEET homolog. Several search and analysis options are available. The users can generate a phylogenetic tree and structure-based sequence alignment for selected set of sequences. With no metazoan SWEETs functionally characterized, the features observed in the selectivity filter residues can be used to predict the potential substrates that are likely to be transported across the metazoan SWEETs. We believe that this database will help the researchers to design mutational experiments and simulation studies that will aid to advance our understanding of the physiological role of SWEET homologs. This database is freely available to the scientific community at http://bioinfo.iitk.ac.in/bioinfo/dbSWEET/Home.     

COPS--cis/trans peptide bond conformation prediction of amino acids on the basis of secondary structure information

SUMMARY: COPS predicts for all 20 naturally occurring amino acids whether the peptide bond in a protein is in cis or trans conformation. The algorithm is based only on secondary structure information of amino acid triplets without considering the amino acid sequence information. Conformation parameters are derived from solved 3D structures deposited in the PDB and led to propensities based on modified Chou-Fasman parameters. COPS analyses amino acid triplets taking only their respective secondary structure into consideration and upon application of a set of rules utilizing the conformation parameters, the N-terminal peptide bond conformation of the middle residue is predicted. COPS was tested on a random selection of protein datasets. AVAILABILITY: The COPS program and further information are freely available from the FMP website at http://www.fmp-berlin.de/nmr/cops CONTACT: labudde@fmp-berlin.de.     

GLYCO-FRAGMENT: A web tool to support the interpretation of mass spectra of complex carbohydrates

Mass spectrometry is frequently used to analyze complex oligosaccharides and glycopeptides. The spectra of glycans can be complicated and difficult to interpret without reference data. Unfortunately, no libraries of suitably pure and homogeneous standards have so far been compiled. The web-based tool GLYCO-FRAGMENT allows the generation of all theoretically possible MS relevant fragments of oligosaccharides as defined using the extended IUPAC nomenclature. The main focus of GLYCO-FRAGMENT is to support the manual assignment of all peaks contained in mass spectra of complex carbohydrates. The service is available at http://www.dkfz.de/spec/projekte/fragments/.