Stoffwechselprodukte von Mikroorganismen: 105. Mitteilung, Arenaemycin E, D and C

Bacterial terpenome

Covering: up to mid-2020 Terpenoids, also called isoprenoids, are the largest and most structurally diverse family of natural products. Found in all domains of life, there are over 80 000 known compounds. The majority of characterized terpenoids, which include some of the most well known, pharmaceutically relevant, and commercially valuable natural products, are produced by plants and fungi. Comparatively, terpenoids of bacterial origin are rare. This is counter-intuitive to the fact that recent microbial genomics revealed that almost all bacteria have the biosynthetic potential to create the C5 building blocks necessary for terpenoid biosynthesis. In this review, we catalogue terpenoids produced by bacteria. We collected 1062 natural products, consisting of both primary and secondary metabolites, and classified them into two major families and 55 distinct subfamilies. To highlight the structural and chemical space of bacterial terpenoids, we discuss their structures, biosynthesis, and biological activities. Although the bacterial terpenome is relatively small, it presents a fascinating dichotomy for future research. Similarities between bacterial and non-bacterial terpenoids and their biosynthetic pathways provides alternative model systems for detailed characterization while the abundance of novel skeletons, biosynthetic pathways, and bioactivies presents new opportunities for drug discovery, genome mining, and enzymology.

Substitution of a Single Amino Acid Reverses the Regiospecificity of the Baeyer-Villiger Monooxygenase PntE in the Biosynthesis of the Antibiotic Pentalenolactone

In the biosynthesis of pentalenolactone (1), PenE and PntE, orthologous proteins from Streptomyces exfoliatus and S. arenae, respectively, catalyze the flavin-dependent Baeyer-Villiger oxidation of 1-deoxy-11-oxopentalenic acid (4) to the lactone pentalenolactone D (5), in which the less-substituted methylene carbon has migrated. By contrast, the paralogous PtlE enzyme from S. avermitilis catalyzes the oxidation of 4 to neopentalenolactone D (6), in which the more substituted methane substitution has undergone migration. We report the design and analysis of 13 single and multiple mutants of PntE mutants to identify the key amino acids that contribute to the regiospecificity of these two classes of Baeyer-Villiger monooxygenases. The L185S mutation in PntE reversed the observed regiospecificity of PntE such that all recombinant PntE mutants harboring this L185S mutation acquired the characteristic regiospecificity of PtlE, catalyzing the conversion of 4 to 6 as the major product. The recombinant PntE mutant harboring R484L exhibited reduced regiospecificity, generating a mixture of lactones containing more than 17% of 6. These in vitro results were corroborated by analysis of the complementation of the S. avermitilis ΔptlED double deletion mutant with pntE mutants, such that pntE mutants harboring L185S produced 6 as the major product, whereas complemention of the ΔptlED deletion mutant with pntE mutants carrying the R484L mutation gave 6 as more than 33% of the total lactone product mixture.

Genome mining in Streptomyces. Elucidation of the role of Baeyer-Villiger monooxygenases and non-heme iron-dependent dehydrogenase/oxygenases in the final steps of the biosynthesis of pentalenolactone and neopentalenolactone

The pentalenolactone biosynthetic gene clusters have been cloned and sequenced from two known producers of the sesquiterpenoid antibiotic pentalenolactone, Streptomyces exfoliatus UC5319 and Streptomyces arenae TÜ469. The recombinant enzymes PenE and PntE, from S. exfoliatus and S. arenae, respectively, catalyze the flavin-dependent Baeyer-Villiger oxidation of 1-deoxy-11-oxopentalenic acid (7) to pentalenolactone D (8). Recombinant PenD, PntD, and PtlD, the latter from Streptomyces avermitilis, each catalyze the Fe(2+)-α-ketoglutarate-dependent oxidation of pentalenolactone D (8) to pentalenolactone E (15) and pentalenolactone F (16). Incubation of PenD, PntD, or PtlD with the isomeric neopentalenolactone D (9) gave PL308 (12) and a compound tentatively identified as neopentalenolactone E (14). These results are corroborated by analysis of the ΔpenD and ΔpntD mutants of S. exfoliatus and S. arenae, respectively, both of which accumulate pentalenolactone D but are blocked in production of pentalenolactone as well as the precursors pentalenolactones E and F. Finally, complementation of the previously described S. avermitilis ΔptlE ΔptlD deletion mutant with either penE or pntE gave pentalenolactone D (8), while complemention of the ΔptlE ΔptlD double mutant with pntE plus pntD or penE plus pntD gave pentalenolactone F (16).

Genome mining in streptomyces. Discovery of an unprecedented P450-catalyzed oxidative rearrangement that is the final step in the biosynthesis of pentalenolactone

The penM and pntM genes from the pentalenolactone biosynthetic gene clusters of Streptomyces exfoliatus UC5319 and Streptomyces arenae TÜ469 were predicted to encode orthologous cytochrome P450s, CYP161C3 and CYP161C2, responsible for the final step in the biosynthesis of the sesquiterpenoid antibiotic pentalenolactone (1). Synthetic genes optimized for expression in Escherichia coli were used to obtain recombinant PenM and PntM, each carrying an N-terminal His(6)-tag. Both proteins showed typical reduced-CO UV maxima at 450 nm, and each bound the predicted substrate, pentalenolactone F (4), with K(D) values of 153 ± 14 and 126 ± 11 μM for PenM and PntM, respectively, as determined by UV shift titrations. PenM and PntM both catalyzed the oxidative rearrangement of 4 to 1 when incubated in the presence of NADPH, spinach ferredoxin, ferredoxin reductase, and O(2). The steady-state kinetic parameters were k(cat) = 10.5 ± 1.7 min(-1) and K(m) = 340 ± 100 μM 4 for PenM and k(cat) = 8.8 ± 0.9 min(-1) and K(m) = 430 ± 100 μM 4 for PntM. The in vivo function of both gene products was confirmed by the finding that the corresponding deletion mutants S. exfoliatus/ΔpenM ZD22 and S. arenae/ΔpntM ZD23 no longer produced pentalenolactone but accumulated the precursor pentalenolactone F. Complementation of each deletion mutant with either penM or pntM restored production of antibiotic 1. Pentalenolactone was also produced by an engineered strain of Streptomyces avermitilis that had been complemented with pntE, pntD, and either pntM or penM, as well as the S. avermitilis electron-transport genes for ferredoxin and ferrodoxin reductase, fdxD and fprD.

Pentalenic acid is a shunt metabolite in the biosynthesis of the pentalenolactone family of metabolites: hydroxylation of 1-deoxypentalenic acid mediated by CYP105D7 (SAV_7469) of Streptomyces avermitilis

Pentalenic acid (1) has been isolated from many Streptomyces sp. as a co-metabolite of the sesquiterpenoid antibiotic pentalenolactone and related natural products. We have previously reported the identification of a 13.4-kb gene cluster in the genome of Streptomyces avermitilis implicated in the biosynthesis of the pentalenolactone family of metabolites consisting of 13 open reading frames. Detailed molecular genetic and biochemical studies have revealed that at least seven genes are involved in the biosynthesis of the newly discovered metabolites, neopentalenoketolactone, but no gene specifically dedicated to the formation of pentalenic acid (1) was evident in the same gene cluster. The wild-type strain of S. avermitilis, as well as its derivatives, mainly produce pentalenic acid (1), together with neopentalenoketolactone (9). Disruption of the sav7469 gene encoding a cytochrome P450 (CYP105D7), members of which class are associated with the hydroxylation of many structurally different compounds, abolished the production of pentalenic acid (1). The sav7469-deletion mutant derived from SUKA11 carrying pKU462∷ptl-clusterΔptlH accumulated 1-deoxypentalenic acid (5), but not pentalenic acid (1). Reintroduction of an extra-copy of the sav7469 gene to SUKA11 Δsav7469 carrying pKU462∷ptl-clusterΔptlH restored the production of pentalenic acid (1). Recombinant CYP105D7 prepared from Escherichia coli catalyzed the oxidative conversion of 1-deoxypentalenic acid (5) to pentalenic acid (1) in the presence of the electron-transport partners, ferredoxin (Fdx) and Fdx reductase, both in vivo and in vitro. These results unambiguously demonstrate that CYP105D7 is responsible for the conversion of 1-deoxypentalenic acid (5) to pentalenic acid (1), a shunt product in the biosynthesis of the pentalenolactone family of metabolites.

Genome mining in Streptomyces avermitilis: A biochemical Baeyer-Villiger reaction and discovery of a new branch of the pentalenolactone family tree

Incubation of 1-deoxy-11-oxopentalenic acid (12) with recombinant PtlE protein from Streptomyces avermitilis in the presence of NADPH and catalytic FAD gave the Baeyer-Villiger oxidation product, the previously unknown compound neopentalenolactone D (13), representing a new branch of the pentalenolactone biosynthetic pathway. The structure and stereochemistry of the derived neopentalenolactone D methyl ester (13-Me) were fully assigned by a combination of GC-MS and NMR analysis and confirmed by X-ray crystallography. Neopentalenolactone D (13) was also isolated from engineered cultures of S. avermitilis from which the ptlD gene within the 13.4-kb (neo)-ptl biosynthetic gene cluster had been deleted. The DeltaptlEDeltaptlD double deletion mutant accumulated 12, the substrate for the ptlE gene product, while the corresponding single DeltaptlE mutant produced 12 as well as the related oxidation products 14 and 15. Engineered strains of S. avermitilis, SUKA5 and pKU462::ermRp-ptl cluster, harboring the complete (neo)ptl cluster produced the oxidized lactone 18 and the closely related seco acid hydrolysis products 16 and 17.

N-Carboxamido-staurosporine and Selina-4(14),7(11)-diene-8,9-diol, New Metabolites from a Marine Streptomyces sp

In our screening of micro-organisms for novel bioactive natural products, a new staurosporinone, N-carboxamido-staurosporine (1c), and a new sesquiterpene, (5S,8S,9R, 10S)-selina-4(14),7(11)-diene-8,9-diol (2a), were isolated from the culture broth of the marine-derived Streptomyces sp. QD518. Their structures were determined by spectroscopic methods and by comparison of the NMR data with those of structurally related known natural products, which were isolated from the same strain.

Pentalenolactone-insensitive glyceraldehyde-3-phosphate dehydrogenase from Streptomyces arenae is closely related to GAPDH from thermostable eubacteria and plant chloroplasts

Streptomyces arenae produces the antibiotic pentalenolactone, a highly specific inhibitor of glyceraldehyde-3-phosphate dehydrogenase (GAPDH). During the phase of pentalenolactone production, S. arenae expresses a pentalenolactone-insensitive GAPDH isoform; otherwise, a pentalenolactone-sensitive form is expressed. The gene of the pentalenolactone-insensitive GAPDH was cloned and sequenced. Regulatory elements typical for genes encoding antibiotic resistance and production are localized upstream and downstream of the open reading frame. No expression of pentalenolactone-insensitive GAPDH was detected in Streptomyces lividans transformed with the gene. In Escherichia coli, the gene was expressed from an induced lac promoter. Amino-terminal sequencing of the heterologously expressed GAPDH proved its identity with pentalenolactone-insensitive GAPDH from S. arenae. Sequence comparisons with GAPDH from other organisms showed a close relationship to GAPDH of plant chloroplasts, of other gram-positive bacteria, and of thermophilic gram-negative bacteria. Pentalenolactone-insensitive GAPDH differs from all closely related GAPDHs only in a few residues, none of which are directly involved in catalysis or substrate binding. The total amino acid composition is more similar to GAPDH of thermophilic species than to that of mesophilic species. The purified enzyme was moderately thermotolerant, which could be a side effect of the structural changes causing pentalenolactone-resistance.

Characterization of two glyceraldehyde-3-phosphate dehydrogenase isoenzymes from the pentalenolactone producer Streptomyces arenae

Pentalenolactone (PL) irreversibly inactivates the enzyme glyceraldehyde-3-phosphate dehydrogenase [D-glyceraldehyde-3-phosphate:NAD+ oxidoreductase (phosphorylating)] (EC 1.2.1.12) and thus is a potent inhibitor of glycolysis in both procaryotic and eucaryotic cells. We showed that PL-producing strain Streptomyces arenae TU469 contains a PL-insensitive glyceraldehyde-3-phosphate dehydrogenase under conditions of PL production. In complex media no PL production was observed, and a PL-sensitive glyceraldehyde-3-phosphate dehydrogenase, rather than the insensitive enzyme, could be detected. The enzymes had the same substrate specificity but different catalytic and molecular properties. The apparent Km values of the PL-insensitive and PL-sensitive enzymes for glyceraldehyde-3-phosphate were 100 and 250 microM, respectively, and the PL-sensitive enzyme was strongly inhibited by PL under conditions in which the PL-insensitive enzyme was not inhibited. The physical properties of the PL-insensitive enzyme suggest that the protein is an octamer, whereas the PL-sensitive enzyme, like other glyceraldehyde-3-phosphate dehydrogenases, appears to be a tetramer.

Specific inactivation of glucose metabolism from eucaryotic cells by pentalenolactone

Pentalenolactone, an antibiotic related to the class of the sesquiterpene-lactones and produced by the strain Streptomyces arenae Tü-469, inhibits specifically the glucose metabolism by inactivation of the enzyme glyceraldehyde-3-phosphate dehydrogenase (D-glyceraldehyde-3-phosphate: NAD oxidoreductase (phosphorylating) ED 1.2.1.1.2). The sensitivity of several eucaryotic cell-systems for pentalenolactone was shown under in vivo conditions. The glycolytic as well as the gluconeogenetic pathway of mammalian cells can be completely inhibited with low concentrations of the antibiotic. In all cases, the minimum inhibitory concentration is dependent on cell density. The inhibitory effect in vivo and in vitro does not seem to be species-specific. In erythrocytes from rats, in Ehrlich-ascites tumor cells and in Plasmodium vinckei infected erythrocytes from mice glycolysis can be inhibited with concentrations of 18--90 micrometers pentalenolactone. In hepatocytes, glycolysis as well as gluconeogenesis in prevented by the same concentrations. In contrast to these results, in yeast the inhibition depends on growth conditions. The inhibition in glucose medium is cancelled by precultivation on acetate-containing medium.