Characterization of a Citrulline 4‐Hydroxylase from Nonribosomal Peptide GE81112 Biosynthesis and Engineering of Its Substrate Specificity for the Chemoenzymatic Synthesis of Enduracididine

Biosynthesis of Glidomides and Elucidation of Different Mechanisms for Formation of β-OH Amino Acid Building Blocks

Nonribosomal peptide synthetases (NRPSs) can incorporate nonproteinogenic amino acids into peptidyl backbones to increase structural diversity. Genome mining of Schlegelella brevitalea led to the identification of a class of linear lipoheptapeptides, glidomides, featuring two unusual residues: threo-β-OH-L-His and threo-β-OH-D-Asp. The β-hydroxylation of Asp and His is catalyzed by the nonheme Fe^II /α-ketoglutarate-dependent β-hydroxylases GlmD and GlmF, respectively. GlmD independently catalyzes the hydroxylation of L-Asp to primarily produce threo-β-OH-L-Asp on the thiolation domain, and then undergoes epimerization to form threo-β-OH-D-Asp in the final products. However, β-hydroxylation of His requires the concerted action of GlmF and the interface (I) domain, a novel condensation domain family clade. The key sites of I domain for interaction with GlmF were identified, suggesting that the mechanism for hydroxylation of His depends on the collaboration between hydroxylase and NRPS.

What Determines the Selectivity of Arginine Dihydroxylation by the Nonheme Iron Enzyme OrfP?

The nonheme iron enzyme OrfP reacts with l-Arg selectively to form the 3R,4R-dihydroxyarginine product, which in mammals can inhibit the nitric oxide synthase enzymes involved in blood pressure control. To understand the mechanisms of dioxygen activation of l-Arg by OrfP and how it enables two sequential oxidation cycles on the same substrate, we performed a density functional theory study on a large active site cluster model. We show that substrate binding and positioning in the active site guides a highly selective reaction through C³ -H hydrogen atom abstraction. This happens despite the fact that the C³ -H and C⁴ -H bond strengths of l-Arg are very similar. Electronic differences in the two hydrogen atom abstraction pathways drive the reaction with an initial C³ -H activation to a low-energy ⁵ σ-pathway, while substrate positioning destabilizes the C⁴ -H abstraction and sends it over the higher-lying ⁵ π-pathway. We show that substrate and monohydroxylated products are strongly bound in the substrate binding pocket and hence product release is difficult and consequently its lifetime will be long enough to trigger a second oxygenation cycle.