03 Fakultät Chemie

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Institute: search.filters.UBSInstitut.Institut für Technische BiochemieAuthor: search.filters.author.Pleiss, JürgenStart date: 2004

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Now showing 1 - 6 of 6
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    Impact of remote mutations on metallo-beta-lactamase substrate specificity : implications for the evolution of antibiotic resistance
    (2005) Ölschläger, Peter; Mayo, Stephen L.; Pleiss, Jürgen
    Metallo-beta-lactamases have raised concerns due to their ability to hydrolyze a broad spectrum of beta-lactam antibiotics. The G262S point mutation distinguishing the metallo-beta-lactamase IMP 1 from IMP 6 has no effect on the hydrolysis of the drugs cephalothin and cefotaxime, but significantly improves catalytic efficiency toward cephaloridine, ceftazidime, benzylpenicillin, ampicillin, and imipenem. This change in specificity occurs even though residue 262 is remote from the active site. We investigated the substrate specificities of five other point mutants resulting from single nucleotide substitutions at positions near residue 262: G262A, G262V, S121G, F218Y and F218I. The results suggest two types of substrates: type I (nitrocefin, cephalothin and cefotaxime), which are converted equally well by IMP-6, IMP-1, and G262A, but even more efficiently by the other mutants, and type II (ceftazidime, benzylpenicillin, ampicillin, and imipenem), which are hydrolyzed much less efficiently by all the mutants, with IMP-1 being the most active. G262V, S121G, F218Y, and F218I improve conversion of type I substrates, whereas G262A and IMP-1 improve conversion of type II substrates, indicating two distinct evolutionary adaptations from IMP-6. Substrate structure may explain the catalytic efficiencies observed. Type I substrates have R2 electron donors, which may stabilize the substrate intermediate in the binding pocket and lead to enhanced activity. In contrast, the absence of these stabilizing interactions with type II substrates may result in poor conversion and increased sensitivity to mutations. This observation may assist future drug design. As the G262A and F218Y mutants confer effective resistance to Escherichia coli BL21(DE3) cells (high minimal inhibitory concentrations), they are likely to evolve naturally.
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    How to find soluble proteins : a comprehensive analysis of alpha/beta hydrolases for recombinant expression in E. coli
    (2005) Koschorreck, Markus; Fischer, Markus; Barth, Sandra; Pleiss, Jürgen
    Background: In screening of libraries derived by expression cloning, expression of active proteinsin E. coli can be limited by formation of inclusion bodies. In these cases it would be desirable to enrich gene libraries for coding sequences with soluble gene products in E. coli and thus to improve the efficiency of screening. Previously Wilkinson and Harrison showed that solubility can be predicted from amino acid composition (Biotechnology 1991, 9(5):443-448). We have applied this analysis to members of the alpha/beta hydrolase fold family to predict their solubility in E. coli. alpha/beta hydrolases are a highly diverse family with more than 1800 proteins which have been grouped into homologous families and superfamilies. Results: The predicted solubility in E. coli depends on hydrolase size, phylogenetic origin of the host organism, the homologous family and the superfamily, to which the hydrolase belongs. In general small hydrolases are predicted to be more soluble than large hydrolases, and eukaryotic hydrolases are predicted to be less soluble in E. coli than prokaryotic ones. However, combining phylogenetic origin and size leads to more complex conclusions. Hydrolases from prokaryotic, fungal and metazoan origin are predicted to be most soluble if they are of small, medium and large size, respectively. We observed large variations of predicted solubility between hydrolases from different homologous families and from different taxa. Conclusion: A comprehensive analysis of all alpha/beta hydrolase sequences allows more efficient screenings for new soluble alpha/beta hydrolases by the use of libraries which contain more soluble gene products. Screening of hydrolases from families whose members are hard to express as soluble proteins in E. coli should first be done in coding sequences of organisms from phylogenetic groups with the highest average of predicted solubility for proteins of this family. The tools developed here can be used to identify attractive target genes for expression using protein sequences published in databases. This analysis also directs the design of degenerate, family- specific primers to amplify new members from homologous families or superfamilies with a high probability of soluble alpha/beta hydrolases.
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    Molecular modelling of family GH16 glycoside hydrolases : potential roles for xyloglucan endotransglucosylases/hydrolases in cell wall modification in the Poaceae
    (2004) Strohmeier, Marco; Hrmova, Maria; Fischer, Markus; Harvey, Andrew J.; Pleiss, Jürgen; Fincher, Geoffrey B.
    Family GH16 glycoside hydrolases can be assigned to five sub-groups according to their substrate specificities, including xyloglucan endotransglucosylases/hydrolases (XTHs), (1,3)-β- galactanases, (1,4)-β-galactanases/κ-carrageenases, “non-specific” (1,3/1,3;1,4)-β-D-glucan endohydrolases and (1,3;1,4)-β-D-glucan endohydrolases. A structured family GH16 glycoside hydrolase database has been constructed (http://www.ghdb.uni-stuttgart.de) and provides multiple sequence alignments with functionally annotated amino acid residues and phylogenetic trees. The database has been used for homology modelling of seven family GH16 glycoside hydrolases, based on structural coordinates for (1,3;1,4)-β-D-glucan endohydrolases and a κ-carrageenase. In combination with multiple sequence alignments, the models predict the three-dimensional dispositions of amino acid residues in the substrate-binding and catalytic sites of XTHs and (1,3/1,3;1,4)-β-D-glucan endohydrolases, for which no structural information is available. Furthermore, they reveal similarities with the active sites of family GH11 (1,4)-β-D-xylan endohydrolases. From a biological viewpoint, the classification and molecular modelling establish structural and evolutionary connections between XTHs, (1,3;1,4)-β-D-glucan endohydrolases and xylan endohydrolases, and raise the possibility that XTHs from higher plants could be active not only on cell wall xyloglucans, but also on (1,3;1,4)-β-D-glucans and arabinoxylans, which are major components of walls in grasses. A role for XTHs in (1,3;1,4)-β-D-glucan and arabinoxylan modification would be consistent with the apparent over-representation of XTH sequences in cereal EST databases.
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    Sequence and structure of epoxide hydrolases : a systematic analysis
    (2004) Barth, Sandra; Fischer, Markus; Schmid, Rolf D.; Pleiss, Jürgen
    Epoxide hydrolases (EC 3.3.2.3) are ubiquitous enzymes which catalyze the hydrolysis of epoxides to the corresponding vicinal diols. Over 100 epoxide hydrolases (EH) have been identified or predicted, 3 structures are available. Although they catalyze the same chemical reaction, sequence similarity is low. To identify conserved regions, all EHs were aligned. Phylogenetic analysis identified 12 homologous families, which were grouped into 2 major superfamilies: the microsomal EH superfamily, which includes the homologous families of Mammalian, Insect, Fungal, and Bacterial EHs, and the cytosolic EH superfamily, which includes Mammalian, Plant, and Bacterial EHs. Bacterial EHs show a high sequence diversity. Based on structure comparison of 3 known structures from Agrobacterium radiobacter AD1 (cytosolic EH), Aspergillus niger (microsomal EH), and Mus musculus (cytosolic EH), and multisequence alignment and phylogenetic analysis of 95 EHs, the modular architecture of this enzyme family was analyzed. While core and cap domain are highly conserved, the structural differences between the EHs are restricted to only 2 loops: the NC-loop connecting the core and the cap and the cap-loop which is inserted into the cap domain. EHs were assigned to either of 3 clusters based on loop length. Using this classification, core and cap region of all EHs, NC-loops and cap-loops of 78% and 89% of all EHs, respectively, could be modeled. Representative models are available from the Lipase Engineering Database, http://www.led.uni-stuttgart.de.
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    Structure and dynamics of Candida rugosa lipase : the role of organic solvent
    (2004) Tejo, Bimo Ario; Abu Bakar Salleh; Pleiss, Jürgen
    The effect of organic solvent to structure and dynamics of proteins was investigated by multiple molecular dynamics simulations (1 ns each) of Candida rugosa lipase in water and in carbon tetrachloride. The choice of solvent had only a minor structural effect. For both solvents the open and the closed conformation of the lipase were near to their experimental X-ray structures (Cα rms deviation 1-1.3 Å). However, the solvents had a highly specific effect on the flexibility of solvent-exposed side chains: polar side chains were more flexible in water, but less flexible in organic solvent. In contrast, hydrophobic residues were more flexible in organic solvent, but less flexible in water. As a major effect solvent changed the dynamics of the lid, a mobile element involved in activation of the lipase, which fluctuated as rigid body about its average position. While in water the deviations were about 1.6 Å, organic solvent reduced flexibility to 0.9 Å. This increase rigidity was caused by two salt bridges (Lys85-Asp284, Lys75-Asp79) and a stable hydrogen bond (Lys75-Asn 292) in organic solvent. Thus organic solvents stabilize the lid but render the side chains in the hydrophobic substrate binding site more mobile.
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    The database of epoxide hydrolases and haloalkane dehalogenases: one structure, many functions
    (2004) Barth, Sandra; Fischer, Markus; Schmid, Rolf D.; Pleiss, Jürgen
    The epoxide hydrolases and haloalkane dehalogenase database (EH/HD) integrates sequence and structure of a highly diverse protein family including mainly the Asp-hydrolases of EHs and HDs but also proteins like the Ser-hydrolases non-heme peroxidases, prolyl iminopetidases or 2-hydroxymuconic semialdehyde hydrolases. These proteins have a highly conserved structure, but display a remarkable diversity in sequence and function. 305 protein entries were assigned to 14 homologous families, forming two superfamilies. Annotated multisequence alignments and phylogenetic trees are provided for each homologous family and superfamily. Experimentally derived structures of 19 proteins are superposed and consistently annotated. Sequence and structure of all 305 proteins were systematically analysed. Thus, deeper insight is gained into the role of a highly conserved sequence motifs and structural elements. The EH/HD database is available at http://www.led.uni-stuttgart.de.