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14/01/2018 · Edited By: Kenneth N

Global analysis of growth phase responsive gene expression and regulation of antibiotic biosynthetic pathways in ..

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fatty alcohols and aldehydes - Lipid

Recent genome sequencing efforts have led to the rapid accumulation of uncharacterized or "orphaned" secondary metabolic biosynthesis gene clusters (BGCs) in public databases. This increase in DNA-sequenced big data has given rise to significant challenges in the applied field of natural product genome mining, including (i) how to prioritize the characterization of orphan BGCs and (ii) how to rapidly connect genes to biosynthesized small molecules. Here, we show that by correlating putative antibiotic resistance genes that encode target-modified proteins with orphan BGCs, we predict the biological function of pathway specific small molecules before they have been revealed in a process we call target-directed genome mining. By querying the pan-genome of 86 Salinispora bacterial genomes for duplicated house-keeping genes colocalized with natural product BGCs, we prioritized an orphan polyketide synthase-nonribosomal peptide synthetase hybrid BGC (tlm) with a putative fatty acid synthase resistance gene. We employed a new synthetic double-stranded DNA-mediated cloning strategy based on transformation-associated recombination to efficiently capture tlm and the related Mu BGCs directly from genomic DNA and to heterologously express them in Streptomyces hosts. We show the production of a group of unusual thiotetronic acid natural products, including the well-known fatty acid synthase inhibitor thiolactomycin that was first described over 30 years ago, yet never at the genetic level in regards to biosynthesis and autoresistance. This finding not only validates the target-directed genome mining strategy for the discovery of antibiotic producing gene clusters without a priori knowledge of the molecule synthesized but also paves the way for the investigation of novel: enzymology involved in thiotetronic, acid natural product biosynthesis.

Elucidation of pathways for antibiotic biosynthesis in streptomyces coelicolor A3(2) Tools. Tools

AB - The biosynthesis of chloramphenicol requires a β-hydroxylation tailoring reaction of the precursor L-p-aminophenylalanine (L-PAPA). Here, it is shown that this reaction is catalyzed by the enzyme CmlA from an operon containing the genes for biosynthesis of L-PAPAand the nonribosomal peptide synthetase CmlP. EPR, Mössbauer, and optical spectroscopies reveal that CmlA contains an oxo-bridged dinuclear iron cluster, a metal center not previously associated with nonribosomal peptide synthetase chemistry. Single-turnover kinetic studies indicate that CmlA is functional in the diferrous state and that its substrate is L-PAPA covalently bound to CmlP. Analytical studies show that the product is hydroxylated L-PAPA and that O 2 is the oxygen source, demonstrating a monooxygenase reaction. The gene sequence of CmlA shows that it utilizes a lactamase fold, suggesting that the diiron cluster is in a protein environment not previously known to effect monooxygenase reactions. Notably, CmlA homologs are widely distributed in natural product biosynthetic pathways, including a variety of pharmaceutically important beta-hydroxylated antibiotics and cytostatics.

Natural Products - Compound Libraries

10/9/2011 · 1. Nat Chem Biol. 2011 Oct 9;7(11):843-52. doi: 10.1038/nchembio.671. Discovery of parallel pathways of kanamycin biosynthesis allows antibiotic manipulation.

The biosynthesis of chloramphenicol requires a β-hydroxylation tailoring reaction of the precursor L-p-aminophenylalanine (L-PAPA). Here, it is shown that this reaction is catalyzed by the enzyme CmlA from an operon containing the genes for biosynthesis of L-PAPAand the nonribosomal peptide synthetase CmlP. EPR, Mössbauer, and optical spectroscopies reveal that CmlA contains an oxo-bridged dinuclear iron cluster, a metal center not previously associated with nonribosomal peptide synthetase chemistry. Single-turnover kinetic studies indicate that CmlA is functional in the diferrous state and that its substrate is L-PAPA covalently bound to CmlP. Analytical studies show that the product is hydroxylated L-PAPA and that O 2 is the oxygen source, demonstrating a monooxygenase reaction. The gene sequence of CmlA shows that it utilizes a lactamase fold, suggesting that the diiron cluster is in a protein environment not previously known to effect monooxygenase reactions. Notably, CmlA homologs are widely distributed in natural product biosynthetic pathways, including a variety of pharmaceutically important beta-hydroxylated antibiotics and cytostatics.

N2 - The biosynthesis of chloramphenicol requires a β-hydroxylation tailoring reaction of the precursor L-p-aminophenylalanine (L-PAPA). Here, it is shown that this reaction is catalyzed by the enzyme CmlA from an operon containing the genes for biosynthesis of L-PAPAand the nonribosomal peptide synthetase CmlP. EPR, Mössbauer, and optical spectroscopies reveal that CmlA contains an oxo-bridged dinuclear iron cluster, a metal center not previously associated with nonribosomal peptide synthetase chemistry. Single-turnover kinetic studies indicate that CmlA is functional in the diferrous state and that its substrate is L-PAPA covalently bound to CmlP. Analytical studies show that the product is hydroxylated L-PAPA and that O 2 is the oxygen source, demonstrating a monooxygenase reaction. The gene sequence of CmlA shows that it utilizes a lactamase fold, suggesting that the diiron cluster is in a protein environment not previously known to effect monooxygenase reactions. Notably, CmlA homologs are widely distributed in natural product biosynthetic pathways, including a variety of pharmaceutically important beta-hydroxylated antibiotics and cytostatics.

Quinones are growth factors for the human gut …

3EGE: Crystal structure of Putative methyltransferase from antibiotic biosynthesis pathway (YP_324569.1) from ANABAENA VARIABILIS ATCC 29413 at 2.40 A resolution

Although phenylpropanoids and flavonoids are common plant natural products, these major classes of biologically active secondary metabolites are largely absent from bacteria. The ubiquitous plant enzymes phenylalanine ammonia-lyase (PAL) and chalcone synthase (CHS) are key biosynthetic catalysts in phenylpropanoid and flavonoid assembly, respectively. Until recently, few bacterial counterparts were known, thus reflecting the dearth of these plant natural products in bacteria. This review highlights our progress on the biochemical and genetic characterization of recently identified streptomycete biosynthetic pathways to benzoic acid and type III polyketide synthase (PKS)-derived products. The sediment-derived bacterium “” produces benzoyl-CoA in a plant-like manner from phenylalanine involving a PAL-mediated reaction through cinnamic acid during the biosynthesis of the polyketide antibiotic enterocin. All but one of the genes encoding benzoyl-CoA biosynthesis in “” have been cloned, sequenced, and inactivated, providing a model for benzoate biosynthesis not only in this bacterium, but in plants where benzoic acid is an important constituent of many products. The recent discovery that bacteria harbor homodimeric PKSs belonging to the plant CHS superfamily of condensing enzymes has further linked the biosynthetic capabilities of plants and bacteria. A bioinformatics approach led to the prediction that the model actinomycete A3(2) contains up to three type III PKSs. Biochemical analysis of one of the recombinant type III PKSs from demonstrated activity as a 1,3,6,8-tetrahydroxynaphthalene synthase (THNS). A homology model of THNS based upon the known three-dimensional structure of CHS was constructed to explore the structural and mechanistic details of this new subclass of bacterial PKSs.

-Digitoxose and -boivinose are both 2,6--DOHs with an axial C-3 hydroxyl group, but they differ in the configuration of the hydroxyl group at C-4: equatorial in the former and axial in the latter (Fig. ). -Digitoxose is well known as a constituent of plant cardiac and other steroidal glycosides (, ). -Boivinose is an unusual DOH. As far as we know, it has been described only as a component of two flavone C-glycosides from Zea mays with glycation-inhibitory activities (). As a constituent of antibiotic or antitumour compounds, -digitoxose is present in the apoptosis inducer ammocidin produced by Saccharothrix sp. () and in the antibacterial saccharomicin produced by Saccharotrix espanaensis (, ). Very recently, a gene cluster for the biosynthesis of TDP--digitoxose was identified (). However, no gene cluster for the biosynthesis of TDP--boivinose has been identified in antibiotic-producing microorganisms. We anticipated that a pathway for the biosynthesis of 2,6--DOH with a hydroxyl group at C-3 in axial configuration would require the same enzymatic steps needed to synthesize -olivose and -oliose but involving a TylC1-like ketoreductase to render the sugar intermediate TDP-2,6-dideoxy--glycero--glycero-4-hexulose (Fig. ). Consequently, we decided to test this hypothesis.

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