Zoie Sadler scite author profile

Zoie Sadler

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Virginia Tech

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

et al. 2022

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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 k cat = 14.3 s–1 and a K m = 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.

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Lysine‐2,3‐aminomutase and a newly discovered glutamate‐2,3‐aminomutase produce β‐amino acids to overcome salt stress in methanogenic archaea

et al. 2022

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Many methanogenic archaea synthesize N ε ‐acetyl‐β‐lysine and/or β‐glutamate as osmolytes that allow survival in high salinity environments. Methanococcus maripaludis C7 contains two genes, MmarC7_0106 and MmarC7_1783, encoding radical S‐adenosylmethionine(SAM) enzymes with sequence similarity to lysine‐2,3‐aminomutase (KAM). MmarC7_0106 is immediately upstream of an acetyltransferase and was expected to be the KAM involved in the biosynthesis of N ε ‐acetyl‐β‐lysine. To confirm this, the gene was cloned and expressed with a hexahistidine tag in E. coli, followed by anaerobic purification and biochemical characterization. Although the bacterial KAMs involved in lysine degradation in Clostridium subterminale and a post‐translational modification of elongation factor P in E. coli have been well‐characterized, the archaeal KAM involved in compatible solute biosynthesis had never been studied in vitro before. In the presence of L‐lysine, SAM, and dithionite at 37°C, this archaeal KAM had a k cat = 0.42 s ‐1 and a K m = 17.8 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. The archaeal KAM was highly specific for L‐lysine, with no activity observed with D‐lysine or most other amino acids. However, low aminomutase activity was observed with L‐arginine. We further report the function of MmarC7_1783, a putative radical SAM aminomutase with a ~160 amino acid extension at its N‐terminus. Bioinformatic analysis of 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. Finally, we investigated the differences in amino acid compatible solute usage amongst M. maripaludis C7 (contains both aminomutase genes) and M. maripaludis S2 (contains only the canonical KAM gene) in different salt concentrations. Taken together, this work defines the biosynthetic routes for β‐amino acids in methanogenic archaea and expands the importance and diversity of radical SAM enzymes in all domains of life.

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Zoie Sadler

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

Lysine‐2,3‐aminomutase and a newly discovered glutamate‐2,3‐aminomutase produce β‐amino acids to overcome salt stress in methanogenic archaea

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