Zhengan Zhang scite author profile

Thiopeptides are potent antibiotics that inhibit protein synthesis. They are made by a remarkable post-translational modification process that transforms a linear peptide into a polycyclic structure. We present here the in vitro biosynthesis of the core scaffold of thiomuracin catalyzed by six proteins. We show that cyclodehydration precedes dehydration, and that dehydration is catalyzed by two proteins in a tRNAGlu-dependent manner. The enzyme that generates the pyridine core from two dehydroalanines ejects the leader peptide as a C-terminal carboxamide. Mutagenesis studies of the enzyme TbtD identified important residues for a formal [4+2] cycloaddition process. The core structure of thiomuracin exhibits similar antimicrobial activity to other known congeners, illustrating that in vitro biosynthesis is a viable route to potent antibiotics that can be explored for the rapid and renewable generation of analogues.

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Use of a scaffold peptide in the biosynthesis of amino acid–derived natural products

Ting

Funk

Halaby

et al. 2019

Science

131

204

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Genome sequencing of environmental bacteria allows identification of biosynthetic gene clusters encoding unusual combinations of enzymes that produce unknown natural products. We identified a pathway in which a ribosomally synthesized small peptide serves as a scaffold for nonribosomal peptide extension and chemical modification. Amino acids are transferred to the carboxyl terminus of the peptide through adenosine triphosphate and amino acyl-tRNA–dependent chemistry that is independent of the ribosome. Oxidative rearrangement, carboxymethylation, and proteolysis of a terminal cysteine yields an amino acid–derived small molecule. Microcrystal electron diffraction demonstrates that the resulting product is isosteric to glutamate. We show that a similar peptide extension is used during the biosynthesis of the ammosamides, which are cytotoxic pyrroloquinoline alkaloids. These results suggest an alternative paradigm for biosynthesis of amino acid–derived natural products.

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Biosynthetic Timing and Substrate Specificity for the Thiopeptide Thiomuracin

et al. 2016

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The biosynthesis of the thiopeptide thiomuracin is a well-orchestrated process involving a multitude of posttranslational modifications. We show that six Cys residues of a precursor peptide are first cyclodehydrated and oxidized to thiazoles in an ordered, but non-linear fashion that is leader peptide-dependent. Then four alcohols are glutamylated and converted to alkenes in a C-to-N terminal directional process that is leader peptide-independent. Finally, two of these alkenes undergo a formal [4+2] cycloaddition to form a tri-thiazole-substituted pyridine macrocycle. We describe here the factors that govern the substrate specificity and order of biosynthetic events that turn a ribosomal peptide into a powerful antibiotic.

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Structural insights into enzymatic [4+2] aza -cycloaddition in thiopeptide antibiotic biosynthesis

Cogan

Hudson

Zhang

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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The [4+2] cycloaddition reaction is an enabling transformation in modern synthetic organic chemistry, but there are only limited examples of dedicated natural enzymes that can catalyze this transformation. Thiopeptides (or more formally thiazolyl peptides) are a class of thiazole-containing, highly modified, macrocyclic secondary metabolites made from ribosomally synthesized precursor peptides. The characteristic feature of these natural products is a six-membered nitrogenous heterocycle that is assembled via a formal [4+2] cycloaddition between two dehydroalanine (Dha) residues. This heteroannulation is entirely contingent on enzyme activity, although the mechanism of the requisite pyridine/dehydropiperidine synthase remains to be elucidated. The unusual -cylic product is distinct from the more common carbocyclic products of synthetic and biosynthetic [4+2] cycloaddition reactions. To elucidate the mechanism of cycloaddition, we have determined atomic resolution structures of the pyridine synthases involved in the biosynthesis of the thiopeptides thiomuracin (TbtD) and GE2270A (PbtD), in complex with substrates and product analogs. Structure-guided biochemical, mutational, computational, and binding studies elucidate active-site features that explain how orthologs can generate rigid macrocyclic scaffolds of different sizes. Notably, the pyridine synthases show structural similarity to the elimination domain of lanthipeptide dehydratases, wherein insertions of secondary structural elements result in the formation of a distinct active site that catalyzes different chemistry. Comparative analysis identifies other catalysts that contain a shared core protein fold but whose active sites are located in entirely different regions, illustrating a principle predicted from efforts in de novo protein design.

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Sensitive and Convenient Detection of microRNAs Based on Cascade Amplification by Catalytic DNAzymes

Tian

Xiao

Zhang

et al. 2012

Chemistry A European J

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On target: We have developed two cascade amplification strategies that combine duplex specific nuclease (DSN) amplicon with either G-quadruplex-based DNA peroxidase or 8-17 DNAzyme amplicon for miRNA detection. In this way, sensitive and convenient detection of miRNAs was achieved. In the DNA peroxidase-based system, a visual color change could be observed in the presence of target miRNAs (see scheme).

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Zhengan Zhang

In Vitro Biosynthesis of the Core Scaffold of the Thiopeptide Thiomuracin

Use of a scaffold peptide in the biosynthesis of amino acid–derived natural products

Biosynthetic Timing and Substrate Specificity for the Thiopeptide Thiomuracin

Structural insights into enzymatic [4+2] aza -cycloaddition in thiopeptide antibiotic biosynthesis

Sensitive and Convenient Detection of microRNAs Based on Cascade Amplification by Catalytic DNAzymes

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