Comparative investigation into formycin A and pyrazofurin A biosynthesis reveals branch pathways for the construction of<i>C</i>-nucleoside scaffolds

Zhang, Meng; Zhang, Peichao; Xu, Guanghua; Zhou, Wenting; Gao, Yang; Gong, Rong; Cai, Yuanfeng; Cong, Hengjiang; Deng, Zixin; Price, Neil P. J.; Mao, Xiangzhao; Chen, Wenqing

doi:10.1101/728154

Cited by 5 publications

(6 citation statements)

References 28 publications

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“…Their biosynthetic gene clusters were identified recently and both clusters contain spb38/spb40/ spb39 relevant genes forK/forJ/forL and pyrM/pyrN/pyrL (also called as prfK/prfJ/prfL) indicating similar hydrazineformation pathways. 81,85,86 Previous feeding studies of pyrazomycin 86 and formycin 87 have revealed nitrogen N1 in pyrazole from the N6 of L-lysine, consistent with the occurrence of pyrM and pyrN, and C1-4 carbons are derived from L-glutamate 87 (Fig. 17A).…”

Section: Biosynthesis Of Linear Hydrazines and Pyrazolessupporting

confidence: 70%

Synthetic and biosynthetic routes to nitrogen–nitrogen bonds

Niikura

et al. 2022

Chem. Soc. Rev.

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Section: Biosynthesis Of Linear Hydrazines and Pyrazolessupporting

confidence: 70%

Synthetic and biosynthetic routes to nitrogen–nitrogen bonds

Niikura

et al. 2022

Chem. Soc. Rev.

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“…To connect two nitrogen atoms together, nature has devised different strategies. The most frequently used precursors for N-N bond formation are hydroxylamines (such as L-N 5 -OH-Ornthine in piperazate pathway 9 , N-isobutylhydrdoxylamine in valanimycin pathway 37 , and L-N 6 -OH-lysine in the pathways of s56-p1 14 , pyrazomycin 16 and formycin 17,38 ) and nitric acid, which derives from the α-amine of L-aspartic acid by the enzyme pair CreE and CreD 10 . The flavin monooxygenase CreE and nitrosuccinate lyase CreD were first characterized in the cremeomycin pathway, and their homologs were subsequently identified in the pathways of fosfazinomycin, and kinamycin, triacsins and alanosine 15,[21][22][23] .…”

Section: Discussionmentioning

confidence: 99%

Nitric oxide as a source for bacterial triazole biosynthesis

et al. 2020

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The heterocycle 1,2,3-triazole is among the most versatile chemical scaffolds and has been widely used in diverse fields. However, how nature creates this nitrogen-rich ring system remains unknown. Here, we report the biosynthetic route to the triazole-bearing antimetabolite 8-azaguanine. We reveal that its triazole moiety can be assembled through an enzymatic and non-enzymatic cascade, in which nitric oxide is used as a building block. These results expand our knowledge of the physiological role of nitric oxide synthase in building natural products with a nitrogen-nitrogen bond, and should also inspire the development of synthetic biology approaches for triazole production.

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“…Insights into the biosynthetic origins of bioactive C-nucleosides have resulted from the identification of the gene clusters encoding a number of these secondary metabolites [19][20][21][22][23][24][25][26][27][28]. In broad terms, the cellular pathways to these natural products use three distinct chemical strategies to make the key C-C bond (electronic supplementary material, figure S1).…”

Section: Introductionmentioning

confidence: 99%

“…Reattachment of the nucleobase to the ribose via a C-C bond then follows rotation of the base within the active site [26,27]. In the third strategy, formycin A and pyrazofurin A arise from direct coupling of a small heteroaromatic dicarboxylic acid to 5 0 -phosphoribose-1 0 -pyrophosphate (PRPP) with concomitant decarboxylation [22,30].…”

Section: Introductionmentioning

confidence: 99%

Experimental and computational snapshots of C-C bond formation in a C-nucleoside synthase

Girt

Radadiya

et al. 2023

Open Biol.

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The biosynthetic enzyme, ForT, catalyses the formation of a C-C bond between 4-amino-1 H -pyrazoledicarboxylic acid and MgPRPP to produce a C-nucleoside precursor of formycin A. The transformation catalysed by ForT is of chemical interest because it is one of only a few examples in which C-C bond formation takes place via an electrophilic substitution of a small, aromatic heterocycle. In addition, ForT is capable of discriminating between the aminopyrazoledicarboxylic acid and an analogue in which the amine is replaced by a hydroxyl group; a remarkable feat given the steric and electronic similarities of the two molecules. Here we report biophysical measurements, structural biology and quantum chemical calculations that provide a detailed molecular picture of ForT-catalysed C-C bond formation and the conformational changes that are coupled to catalysis. Our findings set the scene for employing engineered ForT variants in the biocatalytic production of novel, anti-viral C-nucleoside and C-nucleotide analogues.

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Comparative investigation into formycin A and pyrazofurin A biosynthesis reveals branch pathways for the construction ofC-nucleoside scaffolds

Cited by 5 publications

References 28 publications

Synthetic and biosynthetic routes to nitrogen–nitrogen bonds

Synthetic and biosynthetic routes to nitrogen–nitrogen bonds

Nitric oxide as a source for bacterial triazole biosynthesis

Experimental and computational snapshots of C-C bond formation in a C-nucleoside synthase

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