Activation of a silent phenazine biosynthetic gene cluster reveals a novel natural product and a new resistance mechanism against phenazines

Activation of a silent phenazine biosynthetic gene cluster reveals a novel natural product and a new resistance mechanism against phenazines

The activation of silent biosynthetic gene clusters is a principal challenge for genome mining strategies in drug discovery. In the present study, a phenazine biosynthetic gene cluster was discovered in the Gram-positive bacterium Streptomyces tendaeTue1028. This gene cluster remained silent under a...

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Veröffentlicht in:MedChemComm 2012-08, Vol.3 (8), p.1009-1019
Hauptverfasser: Saleh, Orwah, Bonitz, Tobias, Flinspach, Katrin, Kulik, Andreas, Burkard, Nadja, Mühlenweg, Agnes, Vente, Andreas, Polnick, Stefan, Lämmerhofer, Michael, Gust, Bertolt, Fiedler, Hans-Peter, Heide, Lutz
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container_issue 8
container_start_page 1009
container_title MedChemComm
container_volume 3
creator Saleh, Orwah
Bonitz, Tobias
Flinspach, Katrin
Kulik, Andreas
Burkard, Nadja
Mühlenweg, Agnes
Vente, Andreas
Polnick, Stefan
Lämmerhofer, Michael
Gust, Bertolt
Fiedler, Hans-Peter
Heide, Lutz
description The activation of silent biosynthetic gene clusters is a principal challenge for genome mining strategies in drug discovery. In the present study, a phenazine biosynthetic gene cluster was discovered in the Gram-positive bacterium Streptomyces tendaeTue1028. This gene cluster remained silent under a multitude of cultivation conditions, both in the genuine producer strain and in a heterologous expression strain. However, introduction of a constitutive promoter upstream of the phenazine biosynthesis genes led to the production of phenazine-1-carboxylic acid (PCA) and of a new derivative thereof, i.e.a conjugate of PCA and l-glutamine. The linkage of PCA to l-glutamine by amide bond formation was catalyzed by enzymes of the heterologous expression host Streptomyces coelicolorM512. PCA showed a strong antibiotic effect, but PCA-Gln did not. Glutamination of PCA therefore appears to represent a resistance mechanism against the antibiotic PCA, which can be produced in significant quantities in soil by Pseudomonasstrains. The gene cluster also contained genes for all enzymes of the mevalonate pathway and for an aromatic prenyltransferase, thereby resembling gene clusters for prenylated phenazines. However, purification and biochemical investigation of the prenyltransferase proved that it does not prenylate phenazines but hydroxynaphthalene substrates, showing very similar properties as NphB of naphterpin biosynthesis (Kuzuyma et al., Nature, 2005, 435, 983-987.).
doi_str_mv 10.1039/c2md20045g
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subjects Streptomyces
title Activation of a silent phenazine biosynthetic gene cluster reveals a novel natural product and a new resistance mechanism against phenazines
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