ABSTRACT
Methanobactins are ribosomally synthesized and post-translationally modified peptidic (RiPP) natural products that are known for their ability to chelate copper ions. Crucial for their high copper affinity is a pair of bidentate ligands comprising a nitrogen-containing heterocycle and an adjacent thioamide or enethiol group. The previously uncharacterized proteins MbnB and MbnC were recently shown to synthesize these groups. In this chapter, we describe the methods that were used to determine that MbnB and MbnC are the core biosynthetic enzymes in methanobactin biosynthesis. The two proteins form a heterodimeric complex (MbnBC) which, through a dioxygen-dependent four-electron oxidation of the precursor peptide (MbnA), modifies a cysteine residue in order to install the oxazolone and thioamide moieties. This overview covers the heterologous expression and purification of MbnBC, characterization of the iron cluster found in MbnB, and characterization of the modification installed on MbnA. While this chapter is specific to MbnBC, the methods outlined here can be broadly applied to the enzymology of other proteins that install similar groups as well as enzyme pairs related to MbnB and MbnC.
