One-pot synthesis of 2,5-diketopiperazine with high titer and versatility using adenylation enzyme.

2,5-Diketopiperazine (DKP) is a cyclic peptide composed of two amino acids and has been recently reported to exhibit various biological activities. DKPs have been synthesized using various methods. In chemical synthesis, a multi-step reaction requiring purification and racemization is problematic. Although enzymatic synthesis can overcome these problems, there has been no example of a general-purpose synthesis of DKPs with high titers. Therefore, we propose a chemoenzymatic method that can synthesize DKPs in a general-purpose manner with high efficiency under mild conditions. The adenylation domain of tyrocidine synthetase A (TycA-A) catalyzes the adenylation reaction of amino acids, and various amides can be synthesized by a nucleophilic substitution reaction with any amine. On the other hand, DKPs can be produced via intramolecular cyclization reactions from dipeptide esters. Based on these observations, we expected a one-pot synthesis of DKPs via dipeptide ester synthesis by TycA-A and cyclization reactions. This method enabled the synthesis of more than 128 types of DKPs without racemization. Importantly, the intramolecular cyclization reaction proceeded largely depending on the pH. In particular, the cyclization reaction proceeded well in the pH range of 6.5-9.5. Based on these results, we constructed a bioreactor with pH-stat for purified enzyme reaction; cyclo(L-Trp-L-Pro) was produced at 4.07 mM by controlling the reaction pH over time using this reactor. The DKPs obtained using this method will provide deeper insights into their structures and functions in future studies. KEY POINTS: • Adenylation enzyme enabled one-pot synthesis of arbitrary 2,5-diketopiperazine. • Little or no racemization occurred during 2,5-diketopiperazine synthesis. • Bioreactor with pH-stat for purified enzymes improved the reaction rate.

Structural basis of jasmonate-amido synthetase FIN219 in complex with glutathione S-transferase FIP1 during the JA signal regulation.

Far-red (FR) light-coupled jasmonate (JA) signaling is necessary for plant defense and development. FR insensitive 219 (FIN219) is a member of the Gretchen Hagen 3 (GH3) family of proteins in Arabidopsis and belongs to the adenylate-forming family of enzymes. It directly controls biosynthesis of jasmonoyl-isoleucine in JA-mediated defense responses and interacts with FIN219-interacting protein 1 (FIP1) under FR light conditions. FIN219 and FIP1 are involved in FR light signaling and are regulators of the interplay between light and JA signaling. However, how their interactions affect plant physiological functions remains unclear. Here, we demonstrate the crystal structures of FIN219-FIP1 while binding with substrates at atomic resolution. Our results show an unexpected FIN219 conformation and demonstrate various differences between this protein and other members of the GH3 family. We show that the rotated C-terminal domain of FIN219 alters ATP binding and the core structure of the active site. We further demonstrate that this unique FIN219-FIP1 structure is crucial for increasing FIN219 activity and determines the priority of substrate binding. We suggest that the increased FIN219 activity resulting from the complex form, a conformation for domain switching, allows FIN219 to switch to its high-affinity mode and thereby enhances JA signaling under continuous FR light conditions.

Structural basis of the nonribosomal codes for nonproteinogenic amino acid selective adenylation enzymes in the biosynthesis of natural products.

Nonproteinogenic amino acids are the unique building blocks of nonribosomal peptides (NRPs) and hybrid nonribosomal peptide-polyketides (NRP-PKs) and contribute to their diversity of chemical structures and biological activities. In the biosynthesis of NRPs and NRP-PKs, adenylation enzymes select and activate an amino acid substrate as an aminoacyl adenylate, which reacts with the thiol of the holo form of the carrier protein to afford an aminoacyl thioester as the electrophile for the condensation reaction. Therefore, the substrate specificity of adenylation enzymes is a key determinant of the structure of NRPs and NRP-PKs. Here, we focus on nonproteinogenic amino acid selective adenylation enzymes, because understanding their unique selection mechanisms will lead to accurate functional predictions and protein engineering toward the rational biosynthesis of designed molecules containing amino acids. Based on recent progress in the structural analysis of adenylation enzymes, we discuss the nonribosomal codes of nonproteinogenic amino acid selective adenylation enzymes.

Identification of the Fluvirucin B2 (Sch 38518) Biosynthetic Gene Cluster from Actinomadura fulva subsp. indica ATCC 53714: substrate Specificity of the ß-Amino Acid Selective Adenylating Enzyme FlvN.

Fluvirucins are 14-membered macrolactam polyketides that show antifungal and antivirus activities. Fluvirucins have the ß-alanine starter unit at their polyketide skeletons. To understand the construction mechanism of the ß-alanine moiety in fluvirucin biosyntheses, we have identified the biosynthetic cluster of fluvirucin B2 produced from Actinomadura fulva subsp. indica ATCC 53714. The identified gene cluster contains three polyketide synthases, four characteristic ß-amino acid-carrying enzymes, one decarboxylase, and one amidohydrolase. We next investigated the activity of the adenylation enzyme FlvN, which is a key enzyme for the selective incorporation of a ß-amino acid substrate. FlvN showed strong preference for l-aspartate over other amino acids such as ß-alanine. Based on these results, we propose a biosynthetic pathway for fluvirucin B2.

The crystal structure of the adenylation enzyme VinN reveals a unique ß-amino acid recognition mechanism.

Adenylation enzymes play important roles in the biosynthesis and degradation of primary and secondary metabolites. Mechanistic insights into the recognition of α-amino acid substrates have been obtained for α-amino acid adenylation enzymes. The Asp residue is invariant and is essential for the stabilization of the α-amino group of the substrate. In contrast, the ß-amino acid recognition mechanism of adenylation enzymes is still unclear despite the importance of ß-amino acid activation for the biosynthesis of various natural products. Herein, we report the crystal structure of the stand-alone adenylation enzyme VinN, which specifically activates (2S,3S)-3-methylaspartate (3-MeAsp) in vicenistatin biosynthesis. VinN has an overall structure similar to that of other adenylation enzymes. The structure of the complex with 3-MeAsp revealed that a conserved Asp(230) residue is used in the recognition of the ß-amino group of 3-MeAsp similar to α-amino acid adenylation enzymes. A mutational analysis and structural comparison with α-amino acid adenylation enzymes showed that the substrate-binding pocket of VinN has a unique architecture to accommodate 3-MeAsp as a ß-amino acid substrate. Thus, the VinN structure allows the first visualization of the interaction of an adenylation enzyme with a ß-amino acid and provides new mechanistic insights into the selective recognition of ß-amino acids in this family of enzymes.

Functional and structural characterization of IdnL7, an adenylation enzyme involved in incednine biosynthesis.

Adenylation enzymes play an important role in the selective incorporation of the cognate carboxylate substrates in natural product biosynthesis. Here, the biochemical and structural characterization of the adenylation enzyme IdnL7, which is involved in the biosynthesis of the macrolactam polyketide antibiotic incednine, is reported. Biochemical analysis showed that IdnL7 selects and activates several small amino acids. The structure of IdnL7 in complex with an L-alanyl-adenylate intermediate mimic, 5'-O-[N-(L-alanyl)sulfamoyl]adenosine, was determined at 2.1 Šresolution. The structure of IdnL7 explains the broad substrate specificity of IdnL7 towards small L-amino acids.

Refactoring the Cryptic Streptophenazine Biosynthetic Gene Cluster Unites Phenazine, Polyketide, and Nonribosomal Peptide Biochemistry.

The disconnect between the genomic prediction of secondary metabolite biosynthetic potential and the observed laboratory production profile of microorganisms is well documented. While heterologous expression of biosynthetic gene clusters (BGCs) is often seen as a potential solution to bridge this gap, it is not immune to many challenges including impaired regulation, the inability to recruit essential building blocks, and transcriptional and/or translational silence of the biosynthetic genes. Here we report the discovery, cloning, refactoring, and heterologous expression of a cryptic hybrid phenazine-type BGC (spz) from the marine actinomycete Streptomyces sp. CNB-091. Overexpression of the engineered spz pathway resulted in increased production and chemical diversity of phenazine natural products belonging to the streptophenazine family, including bioactive members containing an unprecedented N-formylglycine attachment. An atypical discrete adenylation enzyme in the spz cluster is required to introduce the formylglycine moiety and represents a phylogenetically distinct class of adenylation proteins.