Identification of the Azaserine Biosynthetic Gene Cluster Implicates Hydrazine as an Intermediate to the Diazo Moiety

Structural Basis for the Catalytic Mechanism of ATP-Dependent Diazotase CmaA6

Although several diazotases have been recently reported, the details of the reaction mechanism are not yet understood. In this study, we investigated the mechanism of CmaA6, an ATP-dependent diazotase, which catalyzes the diazotization of 3-aminocoumaric acid using nitrous acid. X-ray crystallography and cryogenic electron microscopy-single particle analysis revealed CmaA6 structures in the substrate-free and AMP-binding states. Kinetic analysis suggested that CmaA6 catalyzes diazotization via a sequential reaction mechanism in which three substrates (nitrous acid, ATP, and 3-aminocoumaric acid) are simultaneously bound in the reaction pocket. The nitrous acid and 3-aminocoumaric acid binding sites were predicted based on the AMP-binding state and confirmed by site-directed mutagenesis. In addition, computational analysis revealed a tunnel for 3-aminocoumaric acid to enter the reaction pocket, which was advantageous for the sequential reaction mechanism. This study provides important insights into the catalytic mechanism of diazotization in natural product biosynthesis.

Revision of the Formycin A and Pyrazofurin Biosynthetic Pathways Reveals Specificity for d-Glutamic Acid and a Cryptic N-Acylation Step During Pyrazole Core Formation

Formycin A and pyrazofurin are two naturally occurring pyrazole-derived C-nucleosides with antibacterial and antiviral activities. While earlier studies have established the chemistry of C-glycosidic bond formation as well as the subsequent steps in the biosynthesis of formycin A and pyrazofurin, how the pyrazole ring itself is constructed remains elusive. While N-N bond formation in the pyrazole ring was previously reported to involve coupling of N6-hydroxylated l-lysine and l-glutamic acid catalyzed by the hydrazine synthetase PyfG, herein PyfG and its homologue ForJ are shown instead to recognize d-glutamate instead of l-glutamate. The hydrazine product of ForJ/PyfG catalysis then releases α-hydrazino d-glutamic acid upon processing by the NAD-dependent oxidoreductase ForL. Furthermore, N-acylation of α-hydrazino d-glutamate with an amino acid catalyzed by the ATP-grasp ligase ForM/PyfJ is indispensable for recognition by the FAD-dependent oxidoreductase ForR/PyfK to perform dehydrogenation of the Cα-N bond and thereby form a hydrazone intermediate. This work not only demonstrates that d-glutamic acid is the correct substrate for hydrazine biosynthesis but also reveals a cryptic N-acylation step in the assembly of the pyrazole core. These results thus provide significant insights into the biosynthesis of pyrazole rings that are rarely seen in natural products.

Chemical Logic of Peptide Branching by Iterative Nonlinear Nonribosomal Peptide Synthetases

Branch-point syntheses in nonribosomal peptide assembly are rare but useful strategies to generate tripodal peptides with advantageous hexadentate iron-chelating capabilities, as seen in siderophores. However, the chemical logic underlying the peptide branching by nonribosomal peptide synthetase (NRPS) often remains complex and elusive. Here, we review the common strategies for the biosynthesis of branched nonribosomal peptides (NRPs) and present our biochemical investigation on the NRPS-catalyzed assembly of fimsbactin A, a branched mixed-ligand siderophore produced by the human pathogenic strain Acinetobacter baumannii. We untangled the unusual branching mechanism of fimsbactin A biosynthesis through a combination of bioinformatics, site-directed mutagenesis, in vitro reconstitution, molecular modeling, and molecular dynamics simulation. Our findings clarify the roles of the fimsbactin NRPS enzymes, uncovering catalytically redundant domains and identifying the multifunctional nature of the FbsF cyclization (Cy) domain. We demonstrate the dynamic interplay between l-serine and 2,3-dihydroxybenzoic acid derived dipeptides, partitioning between amide and ester forms via a 1,2-N-to-O-acyl shift orchestrated by the noncanonical, multichannel FbsF Cy domain. The branching event occurs in a secondary condensation event facilitated by this Cy domain with two dipeptidyl intermediates, which generates a branched tetrapeptide thioester. Finally, the terminal condensation domain of FbsG recruits a soluble nucleophile to release the final product. This study advances our understanding of the intricate biosynthetic pathways and chemical logic employed by NRPSs, shedding light on the mechanisms underlying the synthesis of complex branched peptides.

Recent Developments and Challenges in the Enzymatic Formation of Nitrogen-Nitrogen Bonds

The biological formation of nitrogen-nitrogen (N-N) bonds represents intriguing reactions that have attracted much attention in the past decade. This interest has led to an increasing number of N-N bond-containing natural products (NPs) and related enzymes that catalyze their formation (referred to in this review as NNzymes) being elucidated and studied in greater detail. While more detailed information on the biosynthesis of N-N bond-containing NPs, which has only become available in recent years, provides an unprecedented source of biosynthetic enzymes, their potential for biocatalytic applications has been minimally explored. With this review, we aim not only to provide a comprehensive overview of both characterized NNzymes and hypothetical biocatalysts with putative N-N bond forming activity, but also to highlight the potential of NNzymes from a biocatalytic perspective. We also present and compare conventional synthetic approaches to linear and cyclic hydrazines, hydrazides, diazo- and nitroso-groups, triazenes, and triazoles to allow comparison with enzymatic routes via NNzymes to these N-N bond-containing functional groups. Moreover, the biosynthetic pathways as well as the diversity and reaction mechanisms of NNzymes are presented according to the direct functional groups currently accessible to these enzymes.

Production of Phenyldiazene Derivatives Using the Biosynthetic Pathway of an Aromatic Diazo Group-Containing Natural Product from an Actinomycete

The diazo group is an important functional group in organic synthesis because it confers high reactivity to the compounds and has been applied in various chemical reactions, such as the Sandmeyer reaction, Wolff rearrangement, cyclopropanation, and C-N bond formation with active methylene compounds. Previously, we revealed that 3-diazoavenalumic acid (3-DAA), which is potentially produced by several actinomycete species and contains an aromatic diazo group, is a biosynthetic intermediate of avenalumic acid. In this study, we aimed to construct a production system for phenyldiazene derivatives by adding several active methylene compounds to the culture of a 3-DAA-producing recombinant actinomycete. First, acetoacetanilide and its derivatives, which have an active methylene and are raw materials for arylide yellow dyes, were individually added to the culture of a 3-DAA-producing actinomycete. When their metabolites were analyzed, each expected compound with a phenyldiazenyl moiety was detected in the culture extract. Moreover, we established a one-pot in vitro enzymatic production system for the same phenyldiazene derivatives using a highly reactive diazotase, CmaA6. These results showed that the diazo group of natural products is an attractive tool for expanding the structural diversity of natural products both in vivo and in vitro.

Discovery of a Bacterial Hydrazine Transferase That Constructs the N-Aminolactam Pharmacophore in Albofungin Biosynthesis

Structural motifs containing nitrogen-nitrogen (N-N) bonds are prevalent in a large number of clinical drugs and bioactive natural products. Hydrazine (N2H4) serves as a widely utilized building block for the preparation of these N-N-containing molecules in organic synthesis. Despite its common use in chemical processes, no enzyme has been identified to catalyze the incorporation of free hydrazine in natural product biosynthesis. Here, we report that a hydrazine transferase catalyzes the condensation of N2H4 and an aromatic polyketide pathway intermediate, leading to the formation of a rare N-aminolactam pharmacophore in the biosynthesis of broad-spectrum antibiotic albofungin. These results expand the current knowledge on the biosynthetic mechanism for natural products with N-N units and should facilitate future development of biocatalysts for the production of N-N-containing chemicals.

Bacterial Hydrazine Biosynthetic Pathways Featuring Cupin/Methionyl tRNA Synthetase-like Enzymes

Nitrogen-Nitrogen (N-N) bond-containing functional groups in natural products and synthetic drugs play significant roles in exerting biological activities. The mechanisms of N-N bond formation in natural organic molecules have garnered increasing attention over the decades. Recent advances have illuminated various enzymatic and nonenzymatic strategies, and our understanding of natural N-N bond construction is rapidly expanding. A group of didomain proteins with zinc-binding cupin/methionyl-tRNA synthetase (MetRS)-like domains, also known as hydrazine synthetases, generates amino acid-based hydrazines, which serve as key biosynthetic precursors of diverse N-N bond-containing functionalities such as hydrazone, diazo, triazene, pyrazole, and pyridazinone groups. In this review, we summarize the current knowledge on hydrazine synthetase mechanisms and the various pathways employing this unique bond-forming machinery.

Phylogeny-guided Characterization of Bacterial Hydrazine Biosynthesis Mediated by Cupin/methionyl tRNA Synthetase-like Enzymes

Cupin/methionyl-tRNA synthetase (MetRS)-like didomain enzymes catalyze nitrogen-nitrogen (N-N) bond formation between Nω-hydroxylamines and amino acids to generate hydrazines, key biosynthetic intermediates of various natural products containing N-N bonds. While the combination of these two building blocks leads to the creation of diverse hydrazine products, the full extent of their structural diversity remains largely unknown. To explore this, we herein conducted phylogeny-guided genome-mining of related hydrazine biosynthetic pathways consisting of two enzymes: flavin-dependent Nω-hydroxylating monooxygenases (NMOs) that produce Nω-hydroxylamine precursors and cupin/MetRS-like enzymes that couple the Nω-hydroxylamines with amino acids via N-N bonds. A phylogenetic analysis identified the largely unexplored sequence spaces of these enzyme families. The biochemical characterization of NMOs demonstrated their capabilities to produce various Nω-hydroxylamines, including those previously not known as precursors of N-N bonds. Furthermore, the characterization of cupin/MetRS-like enzymes identified five new hydrazine products with novel combinations of building blocks, including one containing non-amino acid building blocks: 1,3-diaminopropane and putrescine. This study substantially expanded the variety of N-N bond forming pathways mediated by cupin/MetRS-like enzymes.

Reconstitution of the Final Steps in the Biosynthesis of Valanimycin Reveals the Origin of Its Characteristic Azoxy Moiety

Valanimycin is an azoxy-containing natural product isolated from the fermentation broth of Streptomyces viridifaciens MG456-hF10. While the biosynthesis of valanimycin has been partially characterized, how the azoxy group is constructed remains obscure. Herein, the membrane protein VlmO and the putative hydrazine synthetase ForJ from the formycin biosynthetic pathway are demonstrated to catalyze N-N bond formation converting O-(l-seryl)-isobutyl hydroxylamine into N-(isobutylamino)-l-serine. Subsequent installation of the azoxy group is shown to be catalyzed by the non-heme diiron enzyme VlmB in a reaction in which the N-N single bond in the VlmO/ForJ product is oxidized by four electrons to yield the azoxy group. The catalytic cycle of VlmB appears to begin with a resting μ-oxo diferric complex in VlmB, as supported by Mössbauer spectroscopy. This study also identifies N-(isobutylamino)-d-serine as an alternative substrate for VlmB leading to two azoxy regioisomers. The reactions catalyzed by the kinase VlmJ and the lyase VlmK during the final steps of valanimycin biosynthesis are established as well. The biosynthesis of valanimycin was thus fully reconstituted in vitro using the enzymes VlmO/ForJ, VlmB, VlmJ and VlmK. Importantly, the VlmB-catalyzed reaction represents the first example of enzyme-catalyzed azoxy formation and is expected to proceed by an atypical mechanism.

Conserved Enzymatic Cascade for Bacterial Azoxy Biosynthesis

Azoxy compounds exhibit a wide array of biological activities and possess distinctive chemical properties. Although there has been considerable interest in the biosynthetic mechanisms of azoxy metabolites, the enzymatic basis responsible for azoxy bond formation has remained largely enigmatic. In this study, we unveil the enzyme cascade that constructs the azoxy bond in valanimycin biosynthesis. Our research demonstrates that a pair of metalloenzymes, comprising a membrane-bound hydrazine synthase and a nonheme diiron azoxy synthase, collaborate to convert an unstable pathway intermediate to an azoxy product through a hydrazine-azo-azoxy pathway. Additionally, by characterizing homologues of this enzyme pair from other azoxy metabolite pathways, we propose that this two-enzyme cascade could represent a conserved enzymatic strategy for azoxy bond formation in bacteria. These findings provide significant mechanistic insights into biological N-N bond formation and should facilitate the targeted isolation of bioactive azoxy compounds through genome mining.

Hot off the press

A personal selection of 32 recent papers is presented, covering various aspects of current developments in bioorganic chemistry and novel natural products, such as clavirolide L from Clavularia viridis.