Diana Schulze scite author profile

The membrane-bound enzyme 4-hydroxybenzoic acid oligoprenyltransferase (ubiA) from E. coli is crucial for the production of ubiquinone, the essential electron carrier in prokaryotic and eukaryotic organisms. On the basis of previous modeling analyses, amino acids identified as important in two putative active sites (1 and 2) were selectively mutated. All mutants but one lost their ability to form geranylated hydroxybenzoate, irrespective of their being from active site 1 or 2. This suggests either that the two active sites are interrelated or that they are in fact only one site. With the aid of the experimental results and a new structure-based classification of prenylating enzymes, a relevant 3D model could be developed by threading. The new model explains the substrate specificities and is in complete agreement with the results of site-directed mutagenesis. The high similarity of the active fold of UbiA-transferase to that of 5-epi-aristolochene synthase (Nicotiana tabacum), despite a low homology, allows a hypothesis on a convergent evolution of these enzymes to be formed.

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Molecular and structural basis of metabolic diversity mediated by prenyldiphosphate converting enzymes

Brandt

Bräuer

Günnewich

et al. 2009

Phytochemistry

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Enzymatic C–C-Coupling Prenylation: Bioinformatics – Modelling – Mechanism – Protein-Redesign – Biocatalytic Application

Wessjohann¹,

Zakharova²,

Schulze³

et al. 2009

Chimia

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The functional role of isoprenoids and especially enzymatic prenylation in nature and human application is briefly covered, with the focus on bioinformatical, mechanistical and structural aspects of prenyltransferases and terpene synthases. These enzymes are as yet underrepresented but perspectively useful biocatalysts for C-C couplings of aromatic and isoprenoid substrates. Some examples of the successful use in chemoenzymatic synthesis are given including an application for the otherwise difficult synthesis of Kuhistanol A. Computational structure-based site-directed mutagenesis can be used for rational enzyme redesign to obtain altered substrate and product specificities, which is demonstrated for terpene cyclases.

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ChemInform Abstract: Molecular and Structural Basis of Metabolic Diversity Mediated by Prenyldiphosphate Converting Enzymes.

et al. 2010

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The membrane bound aromatic p-hydroxybenzoic acid oligoprenyltransferase (UbiA) - how iterative improvements lead to a realistic structure that offers new insights into functional aspects of prenyl transferases and terpene synthases

et al. 2010

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Diana Schulze

A Structural Model of the Membrane‐Bound Aromatic Prenyltransferase UbiA from E. coli

Molecular and structural basis of metabolic diversity mediated by prenyldiphosphate converting enzymes

Enzymatic C–C-Coupling Prenylation: Bioinformatics – Modelling – Mechanism – Protein-Redesign – Biocatalytic Application

ChemInform Abstract: Molecular and Structural Basis of Metabolic Diversity Mediated by Prenyldiphosphate Converting Enzymes.

The membrane bound aromatic p-hydroxybenzoic acid oligoprenyltransferase (UbiA) - how iterative improvements lead to a realistic structure that offers new insights into functional aspects of prenyl transferases and terpene synthases

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