Regulation of the Biosynthesis of the Macrolide Antibiotic Spiramycin in
            <i>Streptomyces ambofaciens</i>

Karray, Fatma; Darbon, Emmanuelle; Nguyen, Hoang Chuong; Gagnat, Josette; Pernodet, Jean‐Luc

doi:10.1128/jb.00712-10

Cited by 30 publications

(18 citation statements)

References 46 publications

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“…TylR, a homologue of CSRs for carbomycin and spiramycin biosynthesis (205), is the direct activator of the tylosin biosynthetic genes. The expression of tylR requires the combined action of two SARPs, TylS and TylU (which is described as a "SARP helper").…”

Section: Antibiotic Biosynthesis Regulation: Cascades Feedback Contrmentioning

confidence: 99%

Molecular Regulation of Antibiotic Biosynthesis in Streptomyces

Liu

Chater

Chandra

et al. 2013

Microbiol Mol Biol Rev

594

536

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SUMMARY Streptomycetes are the most abundant source of antibiotics. Typically, each species produces several antibiotics, with the profile being species specific. Streptomyces coelicolor , the model species, produces at least five different antibiotics. We review the regulation of antibiotic biosynthesis in S. coelicolor and other, nonmodel streptomycetes in the light of recent studies. The biosynthesis of each antibiotic is specified by a large gene cluster, usually including regulatory genes (cluster-situated regulators [CSRs]). These are the main point of connection with a plethora of generally conserved regulatory systems that monitor the organism's physiology, developmental state, population density, and environment to determine the onset and level of production of each antibiotic. Some CSRs may also be sensitive to the levels of different kinds of ligands, including products of the pathway itself, products of other antibiotic pathways in the same organism, and specialized regulatory small molecules such as gamma-butyrolactones. These interactions can result in self-reinforcing feed-forward circuitry and complex cross talk between pathways. The physiological signals and regulatory mechanisms may be of practical importance for the activation of the many cryptic secondary metabolic gene cluster pathways revealed by recent sequencing of numerous Streptomyces genomes.

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Section: Antibiotic Biosynthesis Regulation: Cascades Feedback Contrmentioning

confidence: 99%

Molecular Regulation of Antibiotic Biosynthesis in Streptomyces

Liu

Chater

Chandra

et al. 2013

Microbiol Mol Biol Rev

594

536

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show abstract

“…S3 in the supplemental material), indicating that srm42 and srm43 are not involved in the reduction of the platenolide I C-9 keto group or in spiramycin biosynthesis. Thus, the srm gene cluster, previously delimited at srm43 (26), most likely ends with srm41.…”

Section: Resultsmentioning

confidence: 99%

Post-PKS Tailoring Steps of the Spiramycin Macrolactone Ring in Streptomyces ambofaciens

Nguyen

Darbon

Thaï

et al. 2013

Antimicrob Agents Chemother

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dSpiramycins are clinically important 16-member macrolide antibiotics produced by Streptomyces ambofaciens. Biosynthetic studies have established that the earliest lactonic intermediate in spiramycin biosynthesis, the macrolactone platenolide I, is synthesized by a type I modular polyketide synthase (PKS). Platenolide I then undergoes a series of post-PKS tailoring reactions yielding the final products, spiramycins I, II, and III. We recently characterized the post-PKS glycosylation steps of spiramycin biosynthesis in S. ambofaciens. We showed that three glycosyltransferases, Srm5, Srm29, and Srm38, catalyze the successive attachment of the three carbohydrates mycaminose, forosamine, and mycarose, respectively, with the help of two auxiliary proteins, Srm6 and Srm28. However, the enzymes responsible for the other tailoring steps, namely, the C-19 methyl group oxidation, the C-9 keto group reduction, and the C-3 hydroxyl group acylation, as well as the timing of the post-PKS tailoring reactions, remained to be established. In this study, we show that Srm13, a cytochrome P450, catalyzes the oxidation of the C-19 methyl group into a formyl group and that Srm26 catalyzes the reduction of the C-9 keto group, and we propose a timeline for spiramycin-biosynthetic post-PKS tailoring reactions.

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“…Some of the strains can be associated with contaminated soils, e.g., Lentzea with heavy-metal contaminated soils (Haferburg 2007). Others were reported for specifi c abilities to degrade some compounds, such as S. iakyrus and parathion (De Pasquale et al 2008) and S. albogriseolus and latex (Gallert 2000), to produce antibiotics such as S. achromogenes and streptozotocin, rubradirin (Maharjan et al 2003) and tomaymycin (Li et al 2009), S. ambofaciens and spiramycin (Karray et al 2010), S. lincolnensis and lyncomicine (Koběrská et al 2008) and to produce enzymes, such as S. fradie with keratolytic activity (Noval and Nickerson 1958). However to the best of our knowledge there are no reports in the literature about Streptomyces or Lentzea capacity to grow in soils or media with high concentrations of boron compounds.…”

Section: Final Remarksmentioning

confidence: 96%

— Cadmium Bioremediation by a Resistant Streptomyces Strain

Mauricio¹

2013

Actinobacteria

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Regulation of the Biosynthesis of the Macrolide Antibiotic Spiramycin in Streptomyces ambofaciens

Cited by 30 publications

References 46 publications

Molecular Regulation of Antibiotic Biosynthesis in Streptomyces

Molecular Regulation of Antibiotic Biosynthesis in Streptomyces

Post-PKS Tailoring Steps of the Spiramycin Macrolactone Ring in Streptomyces ambofaciens

— Cadmium Bioremediation by a Resistant Streptomyces Strain

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