Your search keyword '"Schulz, F"' showing total 11 results

1. Polyether Cyclization Cascade Alterations in Response to Monensin Polyketide Synthase Mutations.

Author

Heinrich S, Grote M, Sievers S, Kushnir S, and Schulz F

Subjects

Anti-Infective Agents pharmacology, Chromatography, High Pressure Liquid methods, Chromatography, Reverse-Phase, Crystallography, X-Ray, Cyclization, Microbial Sensitivity Tests, Molecular Structure, Monensin analogs & derivatives, Monensin pharmacology, Nuclear Magnetic Resonance, Biomolecular methods, Tandem Mass Spectrometry, Ethers chemistry, Monensin chemistry, Point Mutation, Polyketide Synthases genetics

Abstract

The targeted manipulation of polyketide synthases has in recent years led to numerous new-to-nature polyketides. For type I polyketide synthases the response of post-polyketide synthases (PKS) processing enzymes onto the most frequently polyketide backbone manipulations is so far insufficiently studied. In particular, complex processes such as the polyether cyclisation in the biosynthesis of ionophores such as monensin pose interesting objects of research. We present here a study of the substrate promiscuity of the polyether cyclisation cascade enzymes in monensin biosynthesis in the conversion of redox derivatives of the nascent polyketide chain. LC-HRMS/MS 2 -based studies revealed a remarkable flexibility of the post-PKS enzymes. They acted on derivatized polyketide backbones based on the three possible polyketide redox states within two different modules and gave rise to an altered polyether structure. One of these monensin derivatives was isolated and characterized by 2D-NMR spectroscopy, crystallography, and bioactivity studies., (© 2021 Wiley-VCH GmbH.)

Published

2022

2. Identification of crucial bottlenecks in engineered polyketide biosynthesis.

Author

Grote M, Kushnir S, Pryk N, Möller D, Erver J, Ismail-Ali A, and Schulz F

Subjects

Polyketides chemistry, Protein Conformation, Polyketide Synthases metabolism, Polyketides metabolism, Protein Engineering

Abstract

The concept of combinatorial biosynthesis promises access to compound libraries based on privileged natural scaffolds. Ever since the elucidation of the biosynthetic pathway towards the antibiotic erythromycin A in 1990, the predictable manipulation of type I polyketide synthase megaenzymes was investigated. However, this goal was rarely reached beyond simplified model systems. In this study, we identify the intermediates in the biosynthesis of the polyether monensin and numerous mutated variants using a targeted metabolomics approach. We investigate the biosynthetic flow of intermediates and use the experimental setup to reveal the presence of selectivity filters in polyketide synthases. These obstruct the processing of non-native intermediates in the enzymatic assembly line. Thereby we question the concept of a truly modular organization of polyketide synthases and highlight obstacles in substrate channeling along the cascade. In the search for the molecular origin of a selectivity filter, we investigate the role of different thioesterases in the monensin gene cluster and the connection between ketosynthase sequence motifs and incoming substrate structures. Furthermore, we demonstrate that the selectivity filters do not apply to new-to-nature side-chains in nascent polyketides, showing that the acceptance of these is not generally limited by downstream modules.

Published

2019

3. Exploring the Promiscuous Enzymatic Activation of Unnatural Polyketide Extender Units in Vitro and in Vivo for Monensin Biosynthesis.

Author

Grote M and Schulz F

Subjects

Acyltransferases chemistry, Acyltransferases metabolism, Monensin analogs & derivatives, Protein Domains, Streptomyces enzymology, Substrate Specificity, Bacterial Proteins metabolism, Coenzyme A Ligases metabolism, Monensin biosynthesis, Polyketide Synthases metabolism

Abstract

The incorporation of new-to-nature extender units into polyketide synthesis is an important source for diversity yet is restricted by limited availability of suitably activated building blocks in vivo. We here describe a straightforward workflow for the biogenic activation of commercially available new-to-nature extender units. Firstly, the substrate scope of a highly flexible malonyl co-enzyme A synthetase from Streptomyces cinnamonensis was characterized. The results were matched by in vivo experiments in which the said extender units were accepted by both the polyketide synthase and the accessory enzymes of the monensin biosynthetic pathway. The experiments gave rise to a series of predictable monensin derivatives by the exploitation of the innate substrate promiscuity of an acyltransferase and downstream enzyme functions., (© 2019 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2019

4. Flexible enzymatic activation of artificial polyketide extender units by Streptomyces cinnamonensis into the monensin biosynthetic pathway.

Author

Möller D, Kushnir S, Grote M, Ismail-Ali A, Koopmans KRM, Calo F, Heinrich S, Diehl B, and Schulz F

Subjects

Bacterial Proteins genetics, Biosynthetic Pathways, Enzyme Activation, Fermentation, Polyketide Synthases genetics, Streptomyces enzymology, Streptomyces genetics, Anti-Bacterial Agents biosynthesis, Bacterial Proteins metabolism, Monensin biosynthesis, Polyketide Synthases metabolism, Streptomyces metabolism

Abstract

Streptomyces cinnamonensis A495 is a variant of the monensin producer which instead of the native polyether antibiotic gives rise to antibiotic and anti-tumour shunt-product premonensin. Through the supplementation of the fermentation medium with suitable precursors, premonensin can be derivatized via the incorporation of new-to-nature extender units into the biosynthetic machinery. Polyketide extender units require activation, typically in form of coenzyme A-thioesters. These are membrane impermeable and thus in the past an artificial mimic was employed. Here, we show the use and preliminary characterization of a highly substrate promiscuous new enzyme for the endogenous thioester formation in a Streptomyces strain. These intracellularly activated alternative extender units are significantly better incorporated into premonensin than the synthetically activated counterparts., Significance and Impact of the Study: Polyketide natural products are of enormous relevance in medicine. The hit-rate in finding active compounds for the potential treatment of various diseases among this substance family of microbial origin is high. However, most polyketides require derivatization to render them suitable for the application. Of relevance in this field is the incorporation of artificial substances into the biogenesis of polyketides, hampered by both the microbial metabolism and the complexity of the enzymes involved. This manuscript describes the straightforward and selective biosynthetic incorporation of synthetic substances into a reduced polyketide and showcases a promising new enzyme to aid this purpose., (© 2018 The Society for Applied Microbiology.)

Published

2018

5. Biosynthesis-driven structure-activity relationship study of premonensin-derivatives.

Author

Ismail-Ali A, Fansa EK, Pryk N, Yahiaoui S, Kushnir S, Pflieger M, Wittinghofer A, and Schulz F

Subjects

Humans, Polyketide Synthases chemistry, Polyketides chemistry, Proto-Oncogene Proteins p21(ras) chemistry, Proto-Oncogene Proteins p21(ras) metabolism, Structure-Activity Relationship, Polyketide Synthases metabolism, Polyketides metabolism

Abstract

The controlled derivatization of natural products is of great importance for their use in drug discovery. The ideally rapid generation of compound libraries for structure-activity relationship studies is of particular concern. We here use modified biosynthesis for the generation of such a library of reduced polyketides to interfere with the oncogenic KRas pathway. The polyketide is derivatized via side chain alteration, and variations in its redox pattern and in its backbone chain length through manipulation in the corresponding polyketide synthase. Structural and biophysical analyses revealed the nature of the interaction between the polyketides and KRas-interacting protein PDE6δ. Non-natural polyketides with low nanomolar affinity to PDE6δ were identified.

Published

2016

6. Predicted incorporation of non-native substrates by a polyketide synthase yields bioactive natural product derivatives.

Author

Bravo-Rodriguez K, Ismail-Ali AF, Klopries S, Kushnir S, Ismail S, Fansa EK, Wittinghofer A, Schulz F, and Sanchez-Garcia E

Subjects

Acyltransferases chemistry, Computational Biology, Escherichia coli metabolism, Fermentation, Malonates chemistry, Models, Molecular, Monensin pharmacology, Protein Conformation, Streptomyces enzymology, Substrate Specificity, Biological Products chemical synthesis, Monensin analogs & derivatives, Monensin chemical synthesis, Polyketide Synthases chemistry

Abstract

The polyether ionophore monensin is biosynthesized by a polyketide synthase that delivers a mixture of monensins A and B by the incorporation of ethyl- or methyl-malonyl-CoA at its fifth module. Here we present the first computational model of the fifth acyltransferase domain (AT5mon ) of this polyketide synthase, thus affording an investigation of the basis of the relaxed specificity in AT5mon , insights into the activation for the nucleophilic attack on the substrate, and prediction of the incorporation of synthetic malonic acid building blocks by this enzyme. Our predictions are supported by experimental studies, including the isolation of a predicted derivative of the monensin precursor premonensin. The incorporation of non-native building blocks was found to alter the ratio of premonensins A and B. The bioactivity of the natural product derivatives was investigated and revealed binding to prenyl-binding protein. We thus show the potential of engineered biosynthetic polyketides as a source of ligands for biological macromolecules., (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2014

7. Enzyme-directed mutasynthesis: a combined experimental and theoretical approach to substrate recognition of a polyketide synthase.

Author

Sundermann U, Bravo-Rodriguez K, Klopries S, Kushnir S, Gomez H, Sanchez-Garcia E, and Schulz F

Subjects

Acyltransferases chemistry, Acyltransferases genetics, Acyltransferases metabolism, Biological Products chemistry, Biological Products metabolism, Erythromycin metabolism, Malonates metabolism, Models, Molecular, Molecular Dynamics Simulation, Molecular Structure, Polyketide Synthases chemistry, Saccharopolyspora genetics, Saccharopolyspora metabolism, Substrate Specificity, Point Mutation, Polyketide Synthases genetics, Polyketide Synthases metabolism, Protein Engineering

Abstract

Acyltransferase domains control the extender unit recognition in Polyketide Synthases (PKS) and thereby the side-chain diversity of the resulting natural products. The enzyme engineering strategy presented here allows the alteration of the acyltransferase substrate profile to enable an engineered biosynthesis of natural product derivatives through the incorporation of a synthetic malonic acid thioester. Experimental sequence-function correlations combined with computational modeling revealed the origins of substrate recognition in these PKS domains and enabled a targeted mutagenesis. We show how a single point mutation was able to direct the incorporation of a malonic acid building block with a non-native functional group into erythromycin. This approach, introduced here as enzyme-directed mutasynthesis, opens a new field of possibilities beyond the state of the art for the combination of organic chemistry and biosynthesis toward natural product analogues.

Published

2013

8. Minimally invasive mutagenesis gives rise to a biosynthetic polyketide library.

Author

Kushnir S, Sundermann U, Yahiaoui S, Brockmeyer A, Janning P, and Schulz F

Subjects

Magnetic Resonance Spectroscopy, Mutagenesis, Oxidation-Reduction, Polyketides chemistry, Polyketide Synthases genetics, Polyketide Synthases metabolism, Polyketides chemical synthesis

Abstract

Not in the public domain: Site-directed mutagenesis of megasynthases was the key to the generation of a library of polyketides in bacteria. Redox derivatizations are used to change the bioactivity profile of the compounds., (Copyright © 2012 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2012

9. The stereochemistry of complex polyketide biosynthesis by modular polyketide synthases.

Author

Kwan DH and Schulz F

Subjects

Acyltransferases metabolism, Molecular Structure, Stereoisomerism, Macrolides chemistry, Macrolides metabolism, Polyketide Synthases metabolism

Abstract

Polyketides are a diverse class of medically important natural products whose biosynthesis is catalysed by polyketide synthases (PKSs), in a fashion highly analogous to fatty acid biosynthesis. In modular PKSs, the polyketide chain is assembled by the successive condensation of activated carboxylic acid-derived units, where chain extension occurs with the intermediates remaining covalently bound to the enzyme, with the growing polyketide tethered to an acyl carrier domain (ACP). Carboxylated acyl-CoA precursors serve as activated donors that are selected by the acyltransferase domain (AT) providing extender units that are added to the growing chain by condensation catalysed by the ketosynthase domain (KS). The action of ketoreductase (KR), dehydratase (DH), and enoylreductase (ER) activities can result in unreduced, partially reduced, or fully reduced centres within the polyketide chain depending on which of these enzymes are present and active. The PKS-catalysed assembly process generates stereochemical diversity, because carbon-carbon double bonds may have either cis- or trans- geometry, and because of the chirality of centres bearing hydroxyl groups (where they are retained) and branching methyl groups (the latter arising from use of propionate extender units). This review shall cover the studies that have determined the stereochemistry in many of the reactions involved in polyketide biosynthesis by modular PKSs.

Published

2011

10. Insights into the stereospecificity of ketoreduction in a modular polyketide synthase.

Author

Kwan DH, Tosin M, Schläger N, Schulz F, and Leadlay PF

Subjects

Catalytic Domain, Ketones metabolism, Kinetics, Molecular Structure, Mutation, Oxidation-Reduction, Saccharopolyspora genetics, Stereoisomerism, Ketones chemistry, Polyketide Synthases metabolism, Saccharopolyspora enzymology

Abstract

Ketoreductase enzymes are responsible for the generation of hydroxyl stereocentres during the biosynthesis of complex polyketide natural products. Previous studies of isolated polyketide ketoreductases have shown that the stereospecificity of ketoreduction can be switched by mutagenesis of selected active site amino acids. We show here that in the context of the intact polyketide synthase multienzyme the same changes do not alter the stereochemical outcome in the same way. These findings point towards additional factors that govern ketoreductase stereospecificity on intact multienzymes in vivo.

Published

2011

11. Prediction and manipulation of the stereochemistry of enoylreduction in modular polyketide synthases.

Author

Kwan DH, Sun Y, Schulz F, Hong H, Popovic B, Sim-Stark JC, Haydock SF, and Leadlay PF

Subjects

Amino Acid Sequence, Catalytic Domain, Cell Wall metabolism, Fatty Acids metabolism, Molecular Sequence Data, Mutagenesis, Site-Directed, Mycobacterium cytology, Oxidoreductases Acting on CH-CH Group Donors metabolism, Polyketide Synthases metabolism, Propionates metabolism, Protein Structure, Tertiary, Sequence Alignment, Sequence Homology, Amino Acid, Stereoisomerism, Oxidoreductases Acting on CH-CH Group Donors chemistry, Oxidoreductases Acting on CH-CH Group Donors genetics, Polyketide Synthases chemistry, Polyketide Synthases genetics, Protein Engineering methods, Saccharopolyspora enzymology

Abstract

When an enoylreductase enzyme of a modular polyketide synthase reduces a propionate extender unit that has been newly added to the growing polyketide chain, the resulting methyl branch may have either S or R configuration. We have uncovered a correlation between the presence or absence of a unique tyrosine residue in the ER active site and the chirality of the methyl branch that is introduced. When this position in the active site is occupied by a tyrosine residue, the methyl branch has S configuration, otherwise it has R configuration. In a model PKS in vivo, a mutation (Tyr to Val) in an erythromycin PKS-derived ER caused a switch in the methyl branch configuration in the product from S to R. In contrast, alteration (Val to Tyr) at this position in a rapamycin-derived PKS ER was insufficient to achieve a switch from R to S, showing that additional residues also participate in stereocontrol of enoylreduction.

Published

2008