A47934

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Category Antibiotics
Catalog number BBF-03151
CAS 90039-80-8
Molecular Weight 1313.43
Molecular Formula C58H44Cl3N7O21S

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Description

A47934 is a glycopeptide antibiotic produced by Streptomyces toyocaensis NRRL15009. Activity against gram-positive bacteria.

Specification

Synonyms A-47934 Antibiotic; Antibiotic A 47934
IUPAC Name (1S,2R,19S,22R,34S,37R,40R,52R)-22-amino-5,15,43-trichloro-2,31,44,47,49,64-hexahydroxy-21,35,38,54,56,59-hexaoxo-26-sulfooxy-7,13,28-trioxa-20,36,39,53,55,58-hexazaundecacyclo[38.14.2.23,6.214,17.219,34.18,12.123,27.129,33.141,45.010,37.046,51]hexahexaconta-3,5,8,10,12(64),14,16,23(61),24,26,29(60),30,32,41(57),42,44,46(51),47,49,62,65-henicosaene-52-carboxylic acid
Canonical SMILES C1C2C(=O)NC(C3=CC(=CC(=C3)OC4=C(C=CC(=C4)C(C(=O)N2)N)OS(=O)(=O)O)O)C(=O)NC5C6=CC(=C(C(=C6)OC7=C(C=C(C=C7)C(C8C(=O)NC(C9=C(C(=CC(=C9)O)O)C2=C(C(=CC(=C2)C(C(=O)N8)NC5=O)Cl)O)C(=O)O)O)Cl)O)OC2=C(C=C1C=C2)Cl
InChI InChI=1S/C58H44Cl3N7O21S/c59-31-7-20-1-4-36(31)87-40-15-25-16-41(51(40)74)88-37-5-3-22(12-32(37)60)49(72)48-57(80)67-47(58(81)82)29-18-27(70)19-35(71)42(29)30-11-24(13-33(61)50(30)73)45(56(79)68-48)65-55(78)46(25)66-54(77)44-23-9-26(69)17-28(10-23)86-39-14-21(2-6-38(39)89-90(83,84)85)43(62)53(76)63-34(8-20)52(75)64-44/h1-7,9-19,34,43-49,69-74H,8,62H2,(H,63,76)(H,64,75)(H,65,78)(H,66,77)(H,67,80)(H,68,79)(H,81,82)(H,83,84,85)/t34-,43+,44-,45+,46+,47+,48-,49+/m0/s1
InChI Key HRGFAEUWEMDRRZ-RIZHWKQXSA-N

Properties

Antibiotic Activity Spectrum Gram-positive bacteria
Density 1.6±0.1 g/cm3

Reference Reading

1. More than just recruitment: the X-domain influences catalysis of the first phenolic coupling reaction in A47934 biosynthesis by Cytochrome P450 StaH
Veronika Ulrich, Madeleine Peschke, Clara Brieke, Max J Cryle Mol Biosyst. 2016 Oct 20;12(10):2992-3004. doi: 10.1039/c6mb00373g. Epub 2016 Aug 1.
Glycopeptide antibiotic biosynthesis involves a complex cascade of reactions centred on a non-ribosomal peptide synthetase and modifiying proteins acting in trans, such as Cytochrome P450 enzymes. These P450s are responsible for cyclisation of the peptide via cross-linking aromatic amino acid side chains, which are a hallmark of the glycopeptide antibiotics. Here, we analysed the first cyclisation reaction in the biosynthesis of the glycopeptide antibiotic A47934. Our results demonstrate that the P450 StaH is recruited to the NRPS machinery through interaction with the X-domain present in the last A47934 NRPS module. We determined the crystal structure of StaH and showed that it is responsible for the first cyclisation in A47934 biosynthesis and additionally exhibits flexible substrate specificity. Our results further point out that the X-domain has an impact on the efficiency of the in vitro cyclisation reaction: hybrid PCP-X constructs obtained by domain exchange between A47934 and teicoplanin biosynthesis NRPS modules reveal that the X-domain from A47934 leads to decreased P450 activity and alternate stereochemical preference for the substrate peptide. We determined that a tight interaction between StaH and the A47934 X-domain correlates with decreased in vitro P450 activity: this highlights the need for glycopeptide antibiotic cyclisation to be a dynamic system, with an overly tight interaction interfering with substrate turnover in vitro.
2. Trichlorination of a Teicoplanin-Type Glycopeptide Antibiotic by the Halogenase StaI Evades Resistance
Grace Yim, Wenliang Wang, Andrew C Pawlowski, Gerard D Wright Antimicrob Agents Chemother. 2018 Nov 26;62(12):e01540-18. doi: 10.1128/AAC.01540-18. Print 2018 Dec.
Glycopeptide antibiotics (GPAs) include clinically important drugs used for the treatment of infections caused by Gram-positive pathogens. These antibiotics are specialized metabolites produced by several genera of actinomycete bacteria. While many GPAs are highly chemically modified, A47934 is a relatively unadorned GPA lacking sugar or acyl modifications, common to other members of the class, but which is chlorinated at three distinct sites. The biosynthesis of A47934 is encoded by a 68-kb gene cluster in Streptomyces toyocaensis NRRL 15009. The cluster includes all necessary genes for the synthesis of A47934, including two predicted halogenase genes, staI and staK In this study, we report that only one of the halogenase genes, staI, is necessary and essential for A47934 biosynthesis. Chlorination of the A47934 scaffold is important for antibiotic activity, as assessed by binding affinity for the target N-acyl-d-Ala-d-Ala. Surprisingly, chlorination is also vital to avoid activation of enterococcal and Streptomyces VanB-type GPA resistance through induction of resistance genes. Phenotypic assays showed stronger induction of GPA resistance by the dechlorinated compared to the chlorinated GPA. Correspondingly, the relative expression of the enterococcal vanA resistance gene was shown to be increased by the dechlorinated compared to the chlorinated compound. These results provide insight into the biosynthesis of GPAs and the biological function of GPA chlorination for this medically important class of antibiotic.
3. Biochemical and structural characterisation of the second oxidative crosslinking step during the biosynthesis of the glycopeptide antibiotic A47934
Veronika Ulrich, Clara Brieke, Max J Cryle Beilstein J Org Chem. 2016 Dec 27;12:2849-2864. doi: 10.3762/bjoc.12.284. eCollection 2016.
The chemical complexity and biological activity of the glycopeptide antibiotics (GPAs) stems from their unique crosslinked structure, which is generated by the actions of cytochrome P450 (Oxy) enzymes that affect the crosslinking of aromatic side chains of amino acid residues contained within the GPA heptapeptide precursor. Given the crucial role peptide cyclisation plays in GPA activity, the characterisation of this process is of great importance in understanding the biosynthesis of these important antibiotics. Here, we report the cyclisation activity and crystal structure of StaF, the D-O-E ring forming Oxy enzyme from A47934 biosynthesis. Our results show that the specificity of StaF is reduced when compared to Oxy enzymes catalysing C-O-D ring formation and that this activity relies on interactions with the non-ribosomal peptide synthetase via the X-domain. Despite the interaction of StaF with the A47934 X-domain being weaker than for the preceding Oxy enzyme StaH, StaF retains higher levels of in vitro activity: we postulate that this is due to the ability of the StaF/X-domain complex to allow substrate reorganisation after initial complex formation has occurred. These results highlight the importance of testing different peptide/protein carrier constructs for in vitro GPA cyclisation assays and show that different Oxy homologues can display significantly different catalytic propensities despite their overall similarities.

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