Sinefungin is a potent nucleoside antimetabolite of S-adenosylmethionine (SAM), yet its biosynthesis has remained unclear for decades. Here we detail the identification and characterization of the complete sinefungin biosynthetic gene cluster (BGC) from Streptomyces incarnatus NRRL 8089. In vitro and in vivo analyses demonstrate that the defining carbon-carbon (C-C) bond is formed not by the long-hypothesized PLP-dependent process, but by a vitamin B12-dependent radical SAM enzyme. Using isotope-labeled cofactors and substrates, we provide evidence that the adenosyl group of sinefungin atypically originates from adenosylcobalamin via a homolytic SH2 substitution, establishing a rare instance where adenosylcobalamin is enzymatically consumed during the reaction. Furthermore, the pathway utilizes a cryptic phosphorylation-dephosphorylation strategy to control intermediate processing and substrate recognition. We also characterize two peptide aminoacyl-tRNA ligases (PEARLs) that append alanines onto the nucleoside scaffold using tRNA-activated amino acids. The PEARLs act directly on small molecules rather than macromolecular substrates, with one PEARL capable of iterative elongation. Finally, we leverage these enzymes in a reduced multi-enzyme cascade to biosynthesize sinefungin. Together, these findings redefine radical-mediated C-C bond formation and pearlin enzyme versatility, unlocking biocatalytic possibilities to produce amino acid-nucleoside conjugates.
Crisis support teams’ technological openness and learning attitudes toward the AI based virtual patient system crisis support VR
BackgroundAgainst the backdrop of escalating global humanitarian crises, innovative didactic simulations are becoming increasingly important. A promising alternative to traditional classroom-based didactics for learning psychological