Importance of aspartic acid side chain carboxylate-arginine interaction in substrate selection of arginine 2,3-aminomutase BlsG

The fungicide nucleoside blasticidin S features a β-arginine, a moiety seldom revealed in the structure of natural products. BlsG, a radical SAM arginine-2,3-aminomutase from the blasticidin S biosynthetic pathway, displayed promiscuous activity to three basic amino acids. Here in this study, we demonstrated that BlsG showed high preference toward its natural substrate arginine. The combined structural modeling, steady-state kinetics, and mutational analyses lead to the detailed understanding of the substrate recognition of BlsG. A single mutation of T340D changed the substrate preference of BlsG leading to a little more preference to lysine than arginine. On the basis of our understanding of the substrate selection of BlsG and bioinformatic analysis, we propose that the D…D motif locationally corresponding to D293 and D330 of KAM is characteristic of lysine 2,3-aminomutase while the corresponding D…T motif is characteristic of arginine 2,3-aminomutase. The study may provide a simple way to discern the arginine 2,3-aminomutase and thus lead to the discovery of new natural compounds with β-arginine moiety.

Lysine 2,3-Aminomutase and a Newly Discovered Glutamate 2,3-Aminomutase Produce β-Amino Acids Involved in Salt Tolerance in Methanogenic Archaea

Many methanogenic archaea synthesize β-amino acids as osmolytes that allow survival in high salinity environments. Here, we investigated the radical S-adenosylmethionine (SAM) aminomutases involved in the biosynthesis of Nε-acetyl-β-lysine and β-glutamate in Methanococcus maripaludis C7. Lysine 2,3-aminomutase (KAM), encoded by MmarC7_0106, was overexpressed and purified from Escherichia coli, followed by biochemical characterization. In the presence of l-lysine, SAM, and dithionite, this archaeal KAM had a kcat = 14.3 s-1 and a Km = 19.2 mM. The product was shown to be 3(S)-β-lysine, which is like the well-characterized Clostridium KAM as opposed to the E. coli KAM that produces 3(R)-β-lysine. We further describe the function of MmarC7_1783, a putative radical SAM aminomutase with a ∼160 amino acid extension at its N-terminus. Bioinformatic analysis of the possible substrate-binding residues suggested a function as glutamate 2,3-aminomutase, which was confirmed here through heterologous expression in a methanogen followed by detection of β-glutamate in cell extracts. β-Glutamate has been known to serve as an osmolyte in select methanogens for a long time, but its biosynthetic origin remained unknown until now. Thus, this study defines the biosynthetic routes for β-lysine and β-glutamate in M. maripaludis and expands the importance and diversity of radical SAM enzymes in all domains of life.

Glucuronyl C4 dehydrogenation by the radical SAM enzyme BlsE involved in blasticidin S biosynthesis

Here we report functional investigation of the radical S-adenosylmethionine enzyme BlsE by using cytosylglucuronamide (CGM), which is the amide analog of cytosylglucuronic acid (CGA), an intermediate involved in blasticidin S biosynthesis. We showed that, instead of decarboxylation of CGA reported previously, BlsE catalyzes C4'-dehydrogenation of CGM, and the resulting ketone is acted on by an aminotransferase BlsH to install the C4'-amino group, which uses L-Asp as the amino donor.

Radical S-Adenosyl Methionine Enzyme BlsE Catalyzes a Radical-Mediated 1,2-Diol Dehydration during the Biosynthesis of Blasticidin S

The biosynthesis of blasticidin S has drawn attention due to the participation of the radical S-adenosyl methionine (SAM) enzyme BlsE. The original assignment of BlsE as a radical-mediated, redox-neutral decarboxylase is unusual because this reaction appears to serve no biosynthetic purpose and would need to be reversed by a subsequent carboxylation step. Furthermore, with the exception of BlsE, all other radical SAM decarboxylases reported to date are oxidative in nature. Careful analysis of the BlsE reaction, however, demonstrates that BlsE is not a decarboxylase but instead a lyase that catalyzes the dehydration of cytosylglucuronic acid (CGA) to form cytosyl-4'-keto-3'-deoxy-d-glucuronic acid, which can rapidly decarboxylate nonenzymatically in vitro. Analysis of substrate isotopologs, fluorinated analogues, as well as computational models based on X-ray crystal structures of the BlsE·SAM (2.09 Å) and BlsE·SAM·CGA (2.62 Å) complexes suggests that BlsE catalysis likely proceeds via direct elimination of water from the CGA C4' α-hydroxyalkyl radical as opposed to 1,2-migration of the C3'-hydroxyl prior to dehydration. Biosynthetic and mechanistic implications of the revised assignment of BlsE are discussed.

Characterization and Mechanistic Study of the Radical SAM Enzyme ArsS Involved in Arsenosugar Biosynthesis

Arsenosugars are a group of arsenic-containing ribosides that are found predominantly in marine algae but also in terrestrial organisms. It has been proposed that arsenosugar biosynthesis involves a key intermediate 5'-deoxy-5'-dimethylarsinoyl-adenosine (DDMAA), but how DDMAA is produced remains elusive. Now, we report characterization of ArsS as a DDMAA synthase, which catalyzes a radical S-adenosylmethionine (SAM)-mediated alkylation (adenosylation) of dimethylarsenite (DMAs^III ) to produce DDMAA. This radical-mediated reaction is redox neutral, and multiple turnover can be achieved without external reductant. Phylogenomic and biochemical analyses revealed that DDMAA synthases are widespread in distinct bacterial phyla with similar catalytic efficiencies; these enzymes likely originated from cyanobacteria. This study reveals a key step in arsenosugar biosynthesis and also a new paradigm in radical SAM chemistry, highlighting the catalytic diversity of this superfamily of enzymes.

The conversion of L-lysine into L-β-lysine: the role of 5'-deoxyadenosyl radical and water-a DFT study

In the current study, we deal with the crucial role of 5'-deoxyadenosyl radical and water in the mechanism of the conversion of L-lysine into L-β-lysine. The DFT (density functional theory)-B3LYP method coupled with 6-31G(d) basis set has been performed to investigate the optimized structures of transition states (TSs) and intermediates (IMs) of two processes in water: (i) the attack of 5'-deoxyadenosyl radical to complex PLP-L-lysine and (ii) hydrolysis to liberate L-β-lysine. Meanwhile, M062X/6-311++g(3df,2p) level of theory is applied to compute the relative Gibbs energy ΔG. Procedure (i) has undergone various steps but includes two main structural aziridinyl rings TS2 (ΔG = 4.1 kcal/mol) and TS3 (ΔG = 2.3 kcal/mol). In stage (ii), hydroxy group of water would help to break the bond between β-NH₂ group of L-lysine and PLP better than that of Tyr389.