Abstract
C-Analogues of the canonical N-nucleosides have considerable importance in medicinal chemistry and are promising building blocks of xenobiotic nucleic acids (XNA) in synthetic biology. Although well established for synthesis of N-nucleosides, biocatalytic methods are lacking in C-nucleoside synthetic chemistry. Here, we identify pseudouridine monophosphate C-glycosidase for selective 5-β-C-glycosylation of uracil and derivatives thereof from pentose 5-phosphate (d-ribose, 2-deoxy-d-ribose, d-arabinose, d-xylose) substrates. Substrate requirements of the enzymatic reaction are consistent with a Mannich-like addition between the pyrimidine nucleobase and the iminium intermediate of enzyme (Lys166) and open-chain pentose 5-phosphate. β-Elimination of the lysine and stereoselective ring closure give the product. We demonstrate phosphorylation-glycosylation cascade reactions for efficient, one-pot synthesis of C-nucleoside phosphates (yield: 33 – 94%) from unprotected sugar and nucleobase. We show incorporation of the enzymatically synthesized C-nucleotide triphosphates into nucleic acids by RNA polymerase. Collectively, these findings implement biocatalytic methodology for C-nucleotide synthesis which can facilitate XNA engineering for synthetic biology applications.
Highlights
C-Analogues of the canonical N-nucleosides have considerable importance in medicinal chemistry and are promising building blocks of xenobiotic nucleic acids (XNA) in synthetic biology
We considered the 5phosphates of 2-amino-2-deoxy- and 3-amino-3-deoxy-D-ribose, L-arabinose, D-lyxose, and L-xylose (Supplementary Fig. 3), but enzymatic phosphorylation of these pentoses from ATP proved not possible
We here demonstrate the reverse reaction of ΨMP C-glycosidase for efficient biocatalytic synthesis of C-nucleoside monophosphates
Summary
C-Analogues of the canonical N-nucleosides have considerable importance in medicinal chemistry and are promising building blocks of xenobiotic nucleic acids (XNA) in synthetic biology. We show incorporation of the enzymatically synthesized C-nucleotide triphosphates into nucleic acids by RNA polymerase These findings implement biocatalytic methodology for C-nucleotide synthesis which can facilitate XNA engineering for synthetic biology applications. Synthesized Ψ and derivatives thereof are important building blocks for study of C-nucleoside biology as well as for numerous synthetic biology applications based on xenobiotic nucleic acids (XNA)[29,30,31,32,33,34,35,36]. Formally a reversion of hydrolysis, the overall enzymatic conversion benefits from the favorable thermodynamics of its central catalytic step, a carbon-carbon bond-forming (Mannichlike) addition It proceeds with excellent synthetic yields (≥90%), even in water. Our study implements biocatalytic methodology for C-nucleotide synthesis, which can facilitate XNA engineering for synthetic biology applications and establish new routes to natural product C-glycosides
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