Ferroverdin
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Category | Enzyme inhibitors |
Catalog number | BBF-00920 |
CAS | |
Molecular Weight | 863.60 |
Molecular Formula | C45H33FeN3O12 |
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Description
Ferroverdin A is a cholesteryl ester transfer protein (CETP) inhibitor produced by Streptomyces sp. WK-5344. It inhibits human CETP with an IC50 of 21 μg/ml.
Specification
Related CAS | 26671-45-4 (sodium salt) |
IUPAC Name | (4-ethenylphenyl) 4-hydroxy-3-nitrosobenzoate;iron(2+) |
Canonical SMILES | C=CC1=CC=C(C=C1)OC(=O)C2=CC(=C(C=C2)O)N=O.C=CC1=CC=C(C=C1)OC(=O)C2=CC(=C(C=C2)O)N=O.C=CC1=CC=C(C=C1)OC(=O)C2=CC(=C(C=C2)O)N=O.[Fe+2] |
InChI | InChI=1S/3C15H11NO4.Fe/c3*1-2-10-3-6-12(7-4-10)20-15(18)11-5-8-14(17)13(9-11)16-19;/h3*2-9,17H,1H2;/q;;;+2 |
InChI Key | MDOZWQQLJFPFCI-UHFFFAOYSA-N |
Properties
Appearance | Green Powder |
Reference Reading
1. A Single Biosynthetic Gene Cluster Is Responsible for the Production of Bagremycin Antibiotics and Ferroverdin Iron Chelators
Loïc Martinet, Aymeric Naômé, Benoit Deflandre, Marta Maciejewska, Déborah Tellatin, Elodie Tenconi, Nicolas Smargiasso, Edwin de Pauw, Gilles P van Wezel, Sébastien Rigali mBio. 2019 Aug 13;10(4):e01230-19. doi: 10.1128/mBio.01230-19.
Biosynthetic gene clusters (BGCs) are organized groups of genes involved in the production of specialized metabolites. Typically, one BGC is responsible for the production of one or several similar compounds with bioactivities that usually only vary in terms of strength and/or specificity. Here we show that the previously described ferroverdins and bagremycins, which are families of metabolites with different bioactivities, are produced from the same BGC, whereby the fate of the biosynthetic pathway depends on iron availability. Under conditions of iron depletion, the monomeric bagremycins are formed, representing amino-aromatic antibiotics resulting from the condensation of 3-amino-4-hydroxybenzoic acid with p-vinylphenol. Conversely, when iron is abundantly available, the biosynthetic pathway additionally produces a molecule based on p-vinylphenyl-3-nitroso-4-hydroxybenzoate, which complexes iron to form the trimeric ferroverdins that have anticholesterol activity. Thus, our work shows a unique exception to the concept that BGCs should only produce a single family of molecules with one type of bioactivity and that in fact different bioactive molecules may be produced depending on the environmental conditions.IMPORTANCE Access to whole-genome sequences has exposed the general incidence of the so-called cryptic biosynthetic gene clusters (BGCs), thereby renewing their interest for natural product discovery. As a consequence, genome mining is the often first approach implemented to assess the potential of a microorganism for producing novel bioactive metabolites. By revealing a new level of complexity of natural product biosynthesis, we further illustrate the difficulty of estimation of the panel of molecules associated with a BGC based on genomic information alone. Indeed, we found that the same gene cluster is responsible for the production of compounds which differ in terms of structure and bioactivity. The production of these different compounds responds to different environmental triggers, which suggests that multiplication of culture conditions is essential for revealing the entire panel of molecules made by a single BGC.
2. Structure of New Ferroverdins Recruiting Unconventional Ferrous Iron Chelating Agents
Loïc Martinet, Dominique Baiwir, Gabriel Mazzucchelli, Sébastien Rigali Biomolecules. 2022 May 26;12(6):752. doi: 10.3390/biom12060752.
Ferroverdins are ferrous iron (Fe2+)-nitrosophenolato complexes produced by a few Streptomyces species as a response to iron overload. Previously, three ferroverdins were identified: ferroverdin A, in which three molecules of p-vinylphenyl-3-nitroso-4-hydroxybenzoate (p-vinylphenyl-3,4-NHBA) are recruited to bind Fe2+, and Ferroverdin B and Ferroverdin C, in which one molecule of p-vinylphenyl-3,4-NHBA is substituted by hydroxy-p-vinylphenyl-3,4-NHBA, and by carboxy-p-vinylphenyl-3,4-NHBA, respectively. These molecules, especially ferroverdin B, are potent inhibitors of the human cholesteryl ester transfer protein (CETP) and therefore candidate hits for the development of drugs that increase the serum concentration of high-density lipoprotein cholesterol, thereby diminishing the risk of atherosclerotic cardiovascular disease. In this work, we used high-resolution mass spectrometry combined with tandem mass spectrometry to identify 43 novel ferroverdins from the cytosol of two Streptomyces lunaelactis species. For 13 of them (designated ferroverdins C2, C3, D, D2, D3, E, F, G, H, CD, DE, DF, and DG), we could elucidate their structure, and for the other 17 new ferroverdins, ambiguity remains for one of the three ligands. p-formylphenyl-3,4-NHBA, p-benzoic acid-3,4-NHBA, 3,4-NHBA, p-phenylpropionate-3,4-NHBA, and p-phenyacetate-3,4-NHBA were identified as new alternative chelators for Fe2+-binding, and two compounds (C3 and D3) are the first reported ferroverdins that do not recruit p-vinylphenyl-3,4-NHBA. Our work thus uncovered putative novel CETP inhibitors or ferroverdins with novel bioactivities.
3. On the Risks of Phylogeny-Based Strain Prioritization for Drug Discovery: Streptomyces lunaelactis as a Case Study
Loïc Martinet, Aymeric Naômé, Dominique Baiwir, Edwin De Pauw, Gabriel Mazzucchelli, Sébastien Rigali Biomolecules. 2020 Jul 10;10(7):1027. doi: 10.3390/biom10071027.
Strain prioritization for drug discovery aims at excluding redundant strains of a collection in order to limit the repetitive identification of the same molecules. In this work, we wanted to estimate what can be unexploited in terms of the amount, diversity, and novelty of compounds if the search is focused on only one single representative strain of a species, taking Streptomyces lunaelactis as a model. For this purpose, we selected 18 S. lunaelactis strains taxonomically clustered with the archetype strain S. lunaelactis MM109T. Genome mining of all S. lunaelactis isolated from the same cave revealed that 54% of the 42 biosynthetic gene clusters (BGCs) are strain specific, and five BGCs are not present in the reference strain MM109T. In addition, even when a BGC is conserved in all strains such as the bag/fev cluster involved in bagremycin and ferroverdin production, the compounds produced highly differ between the strains and previously unreported compounds are not produced by the archetype MM109T. Moreover, metabolomic pattern analysis uncovered important profile heterogeneity, confirming that identical BGC predisposition between two strains does not automatically imply chemical uniformity. In conclusion, trying to avoid strain redundancy based on phylogeny and genome mining information alone can compromise the discovery of new natural products and might prevent the exploitation of the best naturally engineered producers of specific molecules.
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