Biosynthetic Gene Cluster of a d‐Tryptophan‐Containing Lasso Peptide,MS‐271

MS‐271, produced by Streptomyces sp. M‐271, is a lasso peptide natural product comprising 21 amino acid residues with a d ‐tryptophan at its C terminus. Because lasso peptides are ribosomal peptides, the biosynthesis of MS‐271, especially the mechanism of d ‐Trp introduction, is of great interest. The MS‐271 biosynthetic gene cluster was identified by draft genome sequencing of the MS‐271 producer, and it was revealed that the precursor peptide contains all 21 amino acid residues including the C‐terminal tryptophan. This suggested that the d ‐Trp residue is introduced by epimerization. Genes for modification enzymes such as a macrolactam synthetase (mslC), precursor peptide recognition element (mslB1), cysteine protease (mslB2), disulfide oxidoreductases (mslE, mslF), and a protein of unknown function (mslH) were found in the flanking region of the precursor peptide gene. Although obvious epimerase genes were absent in the cluster, heterologous expression of the putative MS‐271 cluster in Streptomyces lividans showed that it contains all the necessary genes for MS‐271 production including a gene for a new peptide epimerase. Furthermore, a gene‐deletion experiment indicated that MslB1, ‐B2, ‐C and ‐H were indispensable for MS‐271 production and that some interactions of the biosynthetic enzymes were essential for the biosynthesis of MS‐271.     

Characterization of a Dehydratase and Methyltransferase in the Biosynthesis of Ribosomally Synthesized and Post-translationally Modified Peptides in Lachnospiraceae

As a result of the exponential increase in genomic data, discovery of novel ribosomally synthesized and post-translationally modified peptide natural products (RiPPs) has progressed rapidly in the past decade. The lanthipeptides are a major subset of RiPPs. Through genome mining we identified a novel lanthipeptide biosynthetic gene cluster (lah) from Lachnospiraceae bacterium C6A11, an anaerobic bacterium that is a member of the human microbiota and which is implicated in the development of host disease states such as type 2 diabetes and resistance to Clostridium difficile colonization. The lah cluster encodes at least seven putative precursor peptides and multiple post-translational modification (PTM) enzymes. Two unusual class II lanthipeptide synthetases LahM1/M2 and a substrate-tolerant S-adenosyl-l -methionine (SAM)-dependent methyltransferase LahS_B are biochemically characterized in this study. We also present the crystal structure of LahS_B in complex with product S-adenosylhomocysteine. This study sets the stage for further exploration of the final products of the lah pathway as well as their potential physiological functions in human/animal gut microbiota.     

Biosynthesis of the Fluorinated Natural Product Nucleocidin in Streptomyces calvus Is Dependent on the bldA‐Specified Leu‐tRNAUUA Molecule

Nucleocidin is one of the very few natural products known to contain fluorine. Mysteriously, the nucleocidin producer Streptomyces calvus ATCC 13382 has not been observed to synthesize the compound since its discovery in 1956. Here, we report that complementation of S. calvus ATCC 13382 with a functional bldA‐encoded Leu‐tRNA^UUA molecule restores the production of nucleocidin. Nucleocidin was detected in culture extracts by ¹⁹F NMR spectroscopy, HPLC‐ESI‐MS, and HPLC‐continuum source molecular absorption spectroscopy for fluorine‐specific detection. The molecule was purified from a large‐scale culture and definitively characterized by NMR spectroscopy and high‐resolution MS. The nucleocidin biosynthetic gene cluster was identified by the presence of genes encoding the 5′‐O‐sulfamate moiety and confirmed by gene disruption. Two of the genes within the nucleocidin biosynthetic gene cluster contain TTA codons, thus explaining the dependence on bldA and resolving a 60‐year‐old mystery.     

Aryl Polyenes,a Highly Abundant Class of Bacterial Natural Products,Are Functionally Related to Antioxidative Carotenoids

Bacterial pigments of the aryl polyene type are structurally similar to the well‐known carotenoids with respect to their polyene systems. Their biosynthetic gene cluster is widespread in taxonomically distant bacteria, and four classes of such pigments have been found. Here we report the structure elucidation of the aryl polyene/dialkylresorcinol hybrid pigments of Variovorax paradoxus B4 by HPLC‐UV‐MS, MALDI‐MS and NMR. Furthermore, we show for the first time that this pigment class protects the bacterium from reactive oxygen species, similarly to what is known for carotenoids. An analysis of the distribution of biosynthetic genes for aryl polyenes and carotenoids in bacterial genomes is presented; it shows a complementary distribution of these protective pigments in bacteria.     

New Aminocoumarins from the Rare Actinomycete Catenulispora acidiphila DSM 44928: Identification,Structure Elucidation,and Heterologous Production

Genome mining led to the discovery of a novel aminocoumarin gene cluster in the rare actinomycete Catenulispora acidiphila DSM 44928. Sequence analysis revealed the presence of genes putatively involved in export/resistance, regulation, and biosynthesis of the aminocoumarin moiety and its halogenation, as well as several genes with so far unknown function. Two new aminocoumarins, cacibiocin A and B, were identified in the culture broth of C. acidiphila. Heterologous expression of the putative gene cluster in Streptomyces coelicolor M1152 confirmed that this cluster is responsible for cacibiocin biosynthesis. Furthermore, total production levels of cacibiocins could be increased by heterologous expression and screening of different culture media from an initial yield of 4.9 mg L ^?1 in C. acidiphila to 60 mg L ^?1 in S. coelicolor M1152. By HR‐MS and NMR analysis, cacibiocin A was found to contain a 3‐amino‐4,7‐dihydroxycoumarin moiety linked by an amide bond to a pyrrole‐2,5‐dicarboxylic acid. The latter structural motif has not been identified previously in any natural compound. Additionally, cacibiocin B contains two chlorine atoms at positions 6′ and 8′ of the aminocoumarin moiety.     

Aromatic Polyketide GTRI‐02 is a Previously Unidentified Product of the act Gene Cluster in Streptomyces coelicolor A3(2)

The biosynthesis of aromatic polyketides derived from type II polyketide synthases (PKSs) is complex, and it is not uncommon that highly similar gene clusters give rise to diverse structural architectures. The act biosynthetic gene cluster (BGC) of the model actinomycete Streptomyces coelicolor A3(2) is an archetypal type II PKS. Here we show that the act BGC also specifies the aromatic polyketide GTRI‐02 ( 1 ) and propose a mechanism for the biogenesis of its 3,4‐dihydronaphthalen‐1(2H)‐one backbone. Polyketide 1 was also produced by Streptomyces sp. MBT76 after activation of the act‐like qin gene cluster by overexpression of the pathway‐specific activator. Mining of this strain also identified dehydroxy‐GTRI‐02 ( 2 ), which most likely originated from dehydration of 1 during the isolation process. This work shows that even extensively studied model gene clusters such as act of S. coelicolor can still produce new chemistry, offering new perspectives for drug discovery.     

Rhabdopeptides as Insect‐Specific Virulence Factors from Entomopathogenic Bacteria

Six novel linear peptides, named “rhabdopeptides”, have been identified in the entomopathogenic bacterium Xenorhabdus nematophila after the discovery of the corresponding rdp gene cluster by using a promoter trap strategy for the detection of insect‐inducible genes. The structures of these rhabdopeptides were deduced from labeling experiments combined with detailed MS analysis. Detailed analysis of an rdp mutant revealed that these compounds participate in virulence towards insects and are produced upon bacterial infection of a suitable insect host. Furthermore, two additional rhabdopeptide derivatives produced by Xenorhabdus cabanillasii were isolated, these showed activity against insect hemocytes thereby confirming the virulence of this novel class of compounds.     

Identification of a New Diterpene Biosynthetic Gene Cluster that Produces O‐Methylkolavelool in Herpetosiphon aurantiacus

Diterpenoids are usually found in plants and fungi, but are rare in bacteria. We have previously reported new diterpenes, named tuberculosinol and isotuberculosinol, which are generated from the Mycobacterium tuberculosis gene products Rv3377c and Rv3378c. No homologous gene was found at that time, but we recently found highly homologous proteins in the Herpetosiphon aurantiacus ATCC 23779 genome. Haur_2145 was a class II diterpene cyclase responsible for the conversion of geranylgeranyl diphosphate into kolavenyl diphosphate. Haur_2146, homologous to Rv3378c, synthesized (+)‐kolavelool through the nucleophilic addition of a water molecule to the incipient cation formed after the diphosphate moiety was released. Haur_2147 afforded (+)‐O‐methylkolavelool from (+)‐kolavelool, so this enzyme was an O‐methyltransferase. This new diterpene was indeed detected in H. aurantiacus cells. This is the first report of the identification of a (+)‐O‐methylkolavelool biosynthetic gene cluster.     

New Nocobactin Derivatives with Antimuscarinic Activity,Terpenibactins A–C,Revealed by Genome Mining of Nocardia terpenica IFM 0406

We report a genomics-guided exploration of the metabolic potential of the brasilicardin producer strain Nocardia terpenica IFM 0406. Bioinformatics analysis of the whole genome sequence revealed the presence of a biosynthetic gene cluster presumably responsible for the generation of formerly unknown nocobactin derivatives. Mass spectrometry-assisted isolation led to the identification of three new siderophores, terpenibactins A ( 1 ), B ( 2 ) and C ( 3 ), which belong to the class of nocobactins. Their structures were elucidated by employing spectroscopic techniques. Compounds 1 – 3 demonstrated inhibitory activity towards the muscarinic M3 receptor, while exhibiting only a low cytotoxicity.     

Identification of the Verruculogen Prenyltransferase FtmPT3 by a Combination of Chemical,Bioinformatic and Biochemical Approaches

Previous studies showed that verruculogen is the end product of a biosynthetic gene cluster for fumitremorgin‐type alkaloids in Aspergillus fumigatus and Neosartorya fischeri. In this study, we isolated fumitremorgin A from N. fischeri. This led to the identification of the responsible gene, ftmPT3, for O‐prenylation of an aliphatic hydroxy group in verruculogen. This gene was found at a different location in the genome of N. fischeri than the identified cluster. The coding sequence of ftmPT3 was amplified by fusion PCR and overexpressed in Escherichia coli. The enzyme product of the soluble His₈‐FtmPT3 with verruculogen and dimethylallyl diphosphate (DMAPP) was identified unequivocally as fumitremorgin A by NMR and MS analyses. K_M values of FtmPT3 were determined for verruculogen and DMAPP at 5.7 and 61.5 μM , respectively. Average turnover number (k_cat) was calculated from kinetic parameters of verruculogen and DMAPP to be 0.069 s^?1. FtmPT3 also accepted biosynthetic precursors of fumitremorgin A, for example, fumitremorgin B and 12,13‐dihydroxyfumitremorgin C, as substrates and catalyses their prenylation.     

A Single Gene Cluster for Chalcomycins and Aldgamycins: Genetic Basis for Bifurcation of Their Biosynthesis

Aldgamycins are 16‐membered macrolide antibiotics with a rare branched‐chain sugar d ‐aldgarose or decarboxylated d ‐aldgarose at C‐5. In our efforts to clone the gene cluster for aldgamycins from a marine‐derived Streptomyces sp. HK‐2006‐1 capable of producing both aldgamycins and chalcomycins, we found that both are biosynthesized from a single gene cluster. Whole‐genome sequencing combined with gene disruption established the entire gene cluster of aldgamycins: nine new genes are incorporated with the previously identified chalcomycin gene cluster. Functional analysis of these genes revealed that almDI/almDII, (encoding α/β subunits of pyruvate dehydrogenase) triggers the biosynthesis of aldgamycins, whereas almCI (encoding an oxidoreductase) initiates chalcomycins biosynthesis. This is the first report that aldgamycins and chalcomycins are derived from a single gene cluster and of the genetic basis for bifurcation in their biosynthesis.     

Characterization of the Nocardiopsin Biosynthetic Gene Cluster Reveals Similarities to and Differences from the Rapamycin and FK‐506 Pathways

Macrolide‐pipecolate natural products, such as rapamycin ( 1 ) and FK‐506 ( 2 ), are renowned modulators of FK506‐binding proteins (FKBPs). The nocardiopsins, from Nocardiopsis sp. CMB‐M0232, are the newest members of this structural class. Here, the biosynthetic pathway for nocardiopsins A–D ( 4 – 7 ) is revealed by cloning, sequencing, and bioinformatic analyses of the nsn gene cluster. In vitro evaluation of recombinant NsnL revealed that this lysine cyclodeaminase catalyzes the conversion of L ‐lysine into the L ‐pipecolic acid incorporated into 4 and 5 . Bioinformatic analyses supported the conjecture that a linear nocardiopsin precursor is equipped with the hydroxy group required for macrolide closure in a previously unobserved manner by employing a P450 epoxidase (NsnF) and limonene epoxide hydrolase homologue (NsnG). The nsn cluster also encodes candidates for tetrahydrofuran group biosynthesis. The nocardiopsin pathway provides opportunities for engineering of FKBP‐binding metabolites and for probing new enzymology in nature's polyketide tailoring arsenal.     

Functional Characterization of MpaG′, the O‐Methyltransferase Involved in the Biosynthesis of Mycophenolic Acid

Mycophenolic acid (MPA, 1 ) is a clinically important immunosuppressant. In this report, a gene cluster mpa′ responsible for the biosynthesis of 1 was identified from Penicillium brevicompactum NRRL 864. The S‐adenosyl‐L ‐methionine‐dependent (SAM‐dependent) O‐methyltransferase encoded by the mpaG′ gene was functionally and kinetically characterized in vitro. MpaG′ catalyzes the methylation of demethylmycophenolic acid (DMMPA, 6 ) to form 1 . It also showed significant substrate flexibility by methylating two structural derivatives of 6 prepared by organic synthesis.     

Characterization of the Gene Cluster CYP264B1‐geoA from Sorangium cellulosum So ce56: Biosynthesis of (+)‐Eremophilene and Its Hydroxylation

Terpenoids can be found in almost all forms of life; however, the biosynthesis of bacterial terpenoids has not been intensively studied. This study reports the identification and functional characterization of the gene cluster CYP264B1–geoA from Sorangium cellulosum So ce56. Expression of the enzymes and synthesis of their products for NMR analysis and X‐ray diffraction were carried out by employing an Escherichia coli whole‐cell conversion system that provides the geoA substrate farnesyl pyrophosphate through simultaneous overexpression of the mevalonate pathway genes. The geoA product was identified as a novel sesquiterpene, and assigned NMR signals unambiguously proved that geoA is an (+)‐eremophilene synthase. The very tight binding of (+)‐eremophilene (～0.40 μM ), which is also available in S. cellulosum So ce56, and its oxidation by CYP264B1 suggest that the CYP264B1–geoA gene cluster is required for the biosynthesis of (+)‐eremophilene derivatives.     

Post‐translational Modification in Microviridin Biosynthesis

Cyanobacteria are prolific producers of bioactive natural products that mostly belong to the nonribosomal peptide and polyketide classes. We show here how a linear precursor peptide of microviridin K, a new member of the microviridin class of peptidase inhibitors, is processed to become the mature tricyclic peptidase inhibitor. The microviridin (mvd) biosynthetic gene cluster of P. agardhii comprises six genes encoding microviridin K, an apparently unexpressed second microviridin, two RimK homologues, an acetyltransferase, and an ABC transporter. We have over‐expressed three enzymes of this pathway and have demonstrated their biochemical function in vitro through chemical degradation and mass spectrometry. We show that a prepeptide undergoes post‐translational modification through cross‐linking by ester and amide bond formation by the RimK homologues MvdD and MvdC, respectively. In silico analysis of the mvd gene cluster suggests the potential for widespread occurrence of microviridin‐like compounds in a broad range of bacteria.     

Biosynthetic Gene Cluster for Surugamide A Encompasses an Unrelated Decapeptide,Surugamide F

Genome mining is a powerful method for finding novel secondary metabolites. In our study on the biosynthetic gene cluster for the cyclic octapeptides surugamides A–E (inhibitors of cathepsin B), we found a putative gene cluster consisting of four successive non‐ribosomal peptide synthetase (NRPS) genes, surA, surB, surC, and surD. Prediction of amino acid sequence based on the NRPSs and gene inactivation revealed that surugamides A–E are produced by two NRPS genes, surA and surD, which were separated by two NRPS genes, surB and surC. The latter genes are responsible for the biosynthesis of an unrelated peptide, surugamide F. The pattern of intercalation observed in the sur genes is unprecedented. The structure of surugamide F, a linear decapeptide containing one 3‐amino‐2‐methylpropionic acid (AMPA) residue, was determined by spectroscopic methods and was confirmed by solid‐phase peptide synthesis.     

Structural Diversification of Lyngbyatoxin A by Host‐Dependent Heterologous Expression of the tleABC Biosynthetic Gene Cluster

Natural products have enormous structural diversity, yet little is known about how such diversity is achieved in nature. Here we report the structural diversification of a cyanotoxin—lyngbyatoxin A—and its biosynthetic intermediates by heterologous expression of the Streptomyces‐derived tleABC biosynthetic gene cluster in three different Streptomyces hosts: S. lividans, S. albus, and S. avermitilis. Notably, the isolated lyngbyatoxin derivatives, including four new natural products, were biosynthesized by crosstalk between the heterologous tleABC gene cluster and the endogenous host enzymes. The simple strategy described here has expanded the structural diversity of lyngbyatoxin A and its biosynthetic intermediates, and provides opportunities for investigation of the currently underestimated hidden biosynthetic crosstalk.     

Five‐Membered Cyclitol Phosphate Formation by a myo‐Inositol Phosphate Synthase Orthologue in the Biosynthesis of the Carbocyclic Nucleoside Antibiotic Aristeromycin

Aristeromycin is a unique carbocyclic nucleoside antibiotic produced by Streptomyces citricolor. In order to elucidate its intriguing carbocyclic formation, we used a genome‐mining approach to identify the responsible enzyme. In silico screening with known cyclitol synthases involved in primary metabolism, such as myo‐inositol‐1‐phosphate synthase (MIPS) and dehydroqunate synthase (DHQS), identified a unique MIPS orthologue (Ari2) encoded in the genome of S. citricolor. Heterologous expression of the gene cluster containing ari2 with a cosmid vector in Streptomyces albus resulted in the production of aristeromycin, thus indicating that the cloned DNA region (37.5 kb) with 33 open reading frames contains its biosynthetic gene cluster. We verified that Ari2 catalyzes the formation of a novel five‐membered cyclitol phosphate from d ‐fructose 6‐phosphate (F6P) with NAD⁺ as a cofactor. This provides insight into cyclitol phosphate synthase as a member of the MIPS family of enzymes. A biosynthetic pathway to aristeromycin is proposed based on bioinformatics analysis of the gene cluster.     

Genome Mining of the Hitachimycin Biosynthetic Gene Cluster: Involvement of a Phenylalanine‐2,3‐aminomutase in Biosynthesis

Hitachimycin is a macrolactam antibiotic with (S)‐β‐phenylalanine (β‐Phe) at the starter position of its polyketide skeleton. To understand the incorporation mechanism of β‐Phe and the modification mechanism of the unique polyketide skeleton, the biosynthetic gene cluster for hitachimycin in Streptomyces scabrisporus was identified by genome mining. The identified gene cluster contains a putative phenylalanine‐2,3‐aminomutase (PAM), five polyketide synthases, four β‐amino‐acid‐carrying enzymes, and a characteristic amidohydrolase. A hitA knockout mutant showed no hitachimycin production, but antibiotic production was restored by feeding with (S)‐β‐Phe. We also confirmed the enzymatic activity of the HitA PAM. The results suggest that the identified gene cluster is responsible for the biosynthesis of hitachimycin. A plausible biosynthetic pathway for hitachimycin, including a unique polyketide skeletal transformation mechanism, is proposed.