Disclosing biosynthetic connections and functions of atypical angucyclinones with a fragmented C-ring

Polyketide Origin of the Indole Ring during the Biosynthesis of Indole Alkaloid Coprisidins

Coprisidins, a new class of indole alkaloids, feature a 1,4-naphthoquinone moiety attached to C-3 of 2-oxindole. Heterologous expression of a type II polyketide synthase-containing gene cluster resulted in the generation of three coprisidins. Gene disruption and isotope feeding studies suggested that the 2-oxindole moieties of coprisidins originate from a tetracyclic aromatic polyketide through oxidative rearrangements. This represents a novel biosynthetic route for the synthesis of indole rings in nature.

Biosynthesis of Atypical Angucyclines Unveils New Ring Rearrangement Reactions Catalyzed by Flavoprotein Monooxygenases

Six new angucycline structures, including spirocyclione A (1), which contains an unusual oxaspiro[5.5]undecane architecture, and its ring-A-cleaved product spirocyclione B (2), were discovered by heterologous expression of a type II polyketide biosynthetic gene cluster captured from a marine actinomycete strain Streptomyces sp. HDN155000. Three flavoprotein monooxygenases are confirmed to be responsible for the oxidative carbon skeleton rearrangements in the biosynthesis of compounds 1 and 2. The obtained compounds showed promising cytotoxicity against different types of cancer cells.

Divergence of Classical and C-Ring-Cleaved Angucyclines: Elucidation of Early Tailoring Steps in Lugdunomycin and Thioangucycline Biosynthesis

Angucyclines are an important group of microbial natural products that display tremendous chemical diversity. Classical angucyclines are composed of a tetracyclic benz[a]anthracene scaffold with one ring attached at an angular orientation. However, in atypical angucyclines, the polyaromatic aglycone is cleaved at A-, B-, or C-rings, leading to structural rearrangements and enabling further chemical variety. Here, we have elucidated the branching points in angucycline biosynthesis leading toward cleavage of the C-ring in lugdunomycin and thioangucycline biosynthesis. We showed that 12-hydroxylation and 6-ketoreduction of UWM6 are shared steps in classical and C-ring-cleaved angucycline pathways, although the bifunctional 6-ketoreductase LugOIIred harbors additional unique 1-ketoreductase activity. We identified formation of the key intermediate 8-O-methyltetrangomycin by the LugN methyltransferase as the branching point toward C-ring-cleaved angucyclines. The final common step in lugdunomycin and thioangucycline biosynthesis is quinone reduction, catalyzed by the 7-ketoreductases LugG and TacO, respectively. In turn, the committing step toward thioangucyclines is 12-ketoreduction catalyzed by TacA, for which no orthologous protein exists on the lugdunomycin pathway. Our results confirm that quinone reductions are early tailoring steps and, therefore, may be mechanistically important for subsequent C-ring cleavage. Finally, many of the tailoring enzymes harbored broad substrate promiscuity, which we utilized in combinatorial enzymatic syntheses to generate the angucyclines SM 196 A and hydranthomycin. We propose that enzyme promiscuity and the competition of many of the enzymes for the same substrates lead to a branching biosynthetic network and formation of numerous shunt products typical for angucyclines rather than a canonical linear metabolic pathway.

Angucyclinones with IDO and TDO inhibitory activities isolated from the actinomycetes Umezawaea beigongshangensis

Four previously undescribed angucyclinones umezawaones A-D (1-4) were isolated from the liquid cultures of Umezawaea beigongshangensis. Their structures were determined by spectroscopic analyses, single crystal X-ray diffraction, quantum chemical 13C NMR and electronic circular dichroism calculations. All compounds displayed strong inhibitory activities against indoleamine 2,3-dioxygenase and tryptophan-2,3-dioxygenase in enzymatic assay, especially compound 2.

Unravelling key enzymatic steps in C-ring cleavage during angucycline biosynthesis

Angucyclines are type II polyketide natural products, often characterized by unusual structural rearrangements through B- or C-ring cleavage of their tetracyclic backbone. While the enzymes involved in B-ring cleavage have been extensively studied, little is known of the enzymes leading to C-ring cleavage. Here, we unravel the function of the oxygenases involved in the biosynthesis of lugdunomycin, a highly rearranged C-ring cleaved angucycline derivative. Targeted deletion of the oxygenase genes, in combination with molecular networking and structural elucidation, showed that LugOI is essential for C12 oxidation and maintaining a keto group at C6 that is reduced by LugOII, resulting in a key intermediate towards C-ring cleavage. An epoxide group is then inserted by LugOIII, and stabilized by the novel enzyme LugOV for the subsequent cleavage. Thus, for the first time we describe the oxidative enzymatic steps that form the basis for a wide range of rearranged angucycline natural products.

Acidonemycins A-C, Glycosylated Angucyclines with Antivirulence Activity Produced by the Acidic Culture of Streptomyces indonesiensis

The genome of Streptomyces indonesiensis is highly enriched with cryptic biosynthetic gene clusters (BGCs). The majority of these cryptic BGCs are transcriptionally silent in normal laboratory culture conditions as determined by transcriptome analysis. When cultured in acidic pH (pH 5.4), this strain has been shown to produce a set of new metabolites that were not observed in cultures of neutral pH (pH 7.4). The organic extract of the acidic culture displayed an antivirulence activity against methicillin-resistant Staphylococcus aureus (MRSA). Here, we report the structures of new glycosylated aromatic polyketides, named acidonemycins A-C (1-3), belonging to the family of angucyclines. Type II polyketide synthase BGC responsible for the production of 1-3 was identified by a transcriptome comparison between acidic (pH 5.4) and neutral (pH 7.4) cultures and further confirmed by heterologous expression in Streptomyces albus J1074. Of the three new compounds, acidonemycins A and B (1 and 2) displayed antivirulence activity against MRSA. The simultaneous identification of both antivirulent compounds and their BGC provides a starting point for the future effort of combinatorial biosynthesis.

Characterization of a novel natural tetracenomycin reveals crucial role of 4-hydroxy group in ribosome binding

The aromatic polyketides tetracenomycins were recently found to be potent inhibitors of protein synthesis. Their binding site is located in a unique locus within the tunnel of the large ribosomal subunit. Here we report the isolation and structure elucidation of a novel natural tetracenomycin congener - O⁴-Me-tetracenomycin C (O⁴-Me-TcmC). This compound is isomeric to tetracenomycin X (TcmX), however, in contrast to TcmX, O⁴-Me-TcmC exhibited no antimicrobial activity and was unable to inhibit protein synthesis in vitro. Structural alignment of tetracenomycins to the binding locus from cryo-EM TcmX-70S ribosome data revealed the crucial role of the 4-hydroxyl group. These findings are important for further development of semi-synthetic tetracenomycins as potential antibacterials.

Racemic Total Synthesis of Elmonin and Pratenone A, from Streptomyces, Using a Common Intermediate Prepared by peri-Directed C-H Functionalization

The first total synthesis of elmonin and pratenone A, two complex rearranged angucyclinones from Streptomyces, is reported. Using peri-directed C-H functionalization, the key naphthalene fragment present in both synthetic targets was efficiently prepared. Coupling to two anisole-derived fragments gave access to the natural products, in which elmonin was prepared using a biomimetic spiro-ketalization.

Atypical Angucyclinones with Ring Expansion and Cleavage from a Marine Streptomyces sp

A unique ring C-expanded angucyclinone, oxemycin A (1), and seven new ring-cleavage derivatives (2-5 and 9-11) were isolated from the marine actinomycete Streptomyces pratensis KCB-132, together with eight known analogues (6-8 and 12-16). Their structures were elucidated by spectroscopic analyses, single-crystal X-ray diffractions, and NMR and ECD calculations. Among these atypical angucyclinones, compound 1 represented the first seven-membered ketoester in the angucyclinone family, which sheds light on the origin of fragmented angucyclinones with C-ring cleavage at C-12/C-12a in the Baeyer-Villiger hypothesis, such as 2-4, while the related "nonoxidized" analogues 5-8 seem to originate from a diverse pathway within the Grob fragmentation hypothesis. Additionally, we have succeeded in the challenging separation of elmenols E and F (12) into their four stereoisomers, which remained stable in aprotic solvents but rapidly racemized under protic conditions. Furthermore, the absolute configurations of LS1924 and its isomers (14 and 15) were assigned by ECD calculations for the first time. Surprisingly, these two bicyclic acetals are susceptible to hydrolysis in solution, resulting in fragmented derivatives 17 and 18 with C-ring cleavage between C-6a and C-7. Compared with ring C-modified angucyclinones, ring A-cleaved 11 was more active to multiple resistant "ESKAPE" pathogens with MIC values ranging from 4.7 to 37.5 μg/mL.

Kumemicinones A-G, Cytotoxic Angucyclinones from a Deep Sea-Derived Actinomycete of the Genus Actinomadura

Chemical investigation of the fermentation products of a deep sea water-derived actinomycete, Actinomadura sp. KD439, identified seven new angucyclinones, designated as kumemicinones A-G (1-7), together with the known SF2315B and miaosporone E. NMR and MS spectroscopic analyses, combined with X-ray crystallography and quantum chemical calculations of NMR chemical shifts and electronic circular dichroism (ECD) spectra, uncovered the structures of new angucyclinones as regioisomers of SF2315B at the allyl alcohol unit (1 and 2), an epoxy ring-opened γ-hydroxy enone isomer (3), a B/C-ring-rearranged product (4), or dimers with a new mode of bridging (5-7), adding new structural variation to this antibiotic group. The absolute configuration of SF2315B was also determined by comparison of ECD spectra with those of 1 and 2. All the angucyclinones exhibited cytotoxicity against P388 murine leukemia cells, with IC₅₀ values ranging from 1.8 to 53 μM.

Genome-Guided Discovery of Highly Oxygenated Aromatic Polyketides, Saccharothrixins D-M, from the Rare Marine Actinomycete Saccharothrix sp. D09

Angucyclines and angucyclinones are aromatic polyketides with intriguing structures and therapeutic value. Genome mining of the rare marine actinomycete Saccharothrix sp. D09 led to the identification of a type II polyketide synthase biosynthetic gene cluster, sxn, which encodes several distinct subclasses of oxidoreductases, implying that this strain has the potential to produce novel polycyclic aromatic polyketides with unusual redox modifications. The "one strain-many compounds" (OSMAC) strategy and comparative metabolite analysis facilitated the discovery of 20 angucycline derivatives from the D09 strain, including six new highly oxygenated saccharothrixins D-I (1-6), four new glycosylated saccharothrixins J-M (7-10), and 10 known analogues (11-20). Their structures were elucidated based on detailed HRESIMS, NMR spectroscopic, and X-ray crystallographic analysis. With the help of gene disruption and heterologous expression, we proposed their plausible biosynthetic pathways. In addition, compounds 3, 4, and 8 showed antibacterial activity against Helicobacter pylori with MIC values ranging from 16 to 32 μg/mL. Compound 3 also revealed anti-inflammatory activity by inhibiting the production of NO with an IC₅₀ value of 28 μM.

Biological evaluation and spectral characterization of a novel tetracenomycin X congener

The aromatic polyketide tetracenomycin X (TcmX) was recently found to be a potent inhibitor of protein synthesis; its binding site is located in a unique locus within the tunnel of the large ribosomal subunit. The distinct mode of action makes this relatively narrow class of aromatic polyketides promising for drug development in the quest to prevent the spread of drug-resistant pathogens. Here we report the isolation and structure elucidation of a novel natural tetracenomycin X congener - 6-hydroxytetraceonomycin X (6-OH-TcmX). In contrast to TcmX, 6-OH-TcmX exhibited lower antimicrobial and cytotoxic activity, but comparable in vitro protein synthesis inhibition ability. A survey on spectral properties of tetracenomycins revealed profound differences in both UV-absorption and fluorescence spectra between TcmX and 6-OH-TcmX, suggesting a significant influence of 6-hydroxylation on the tetracenomycin X chromophore. Nonetheless, characteristic spectral properties of tetracenomycins make them suitable candidates for semi-synthetic drug development (e.g., for targeted delivery, chemical biology, or cell imaging).

Discovery of a new asymmetric dimer nenestatin B and implications of a dimerizing enzyme in a deep sea actinomycete

Benzofluorene-containing atypical angucyclines are an important family of natural products with a broad spectrum of antibacterial and cytotoxic properties. Interestingly, symmetric and asymmetric dimers showed better activity than the monomer in this class of compounds. Herein, we reported the isolation of a new asymmetric dimer nenestatin B (2) from the deep sea actinomycete Micromonospora echinospora SCSIO 04089 and a monomer nenestatin C (3) from an NmrA family regulatory protein coding gene nes18 inactivated mutant. The structural elucidation of 3 indicated the essential role of Nes18 in the biosynthetic pathway of 2, specifically in dimerization via C-C bond formation.