What question did this study set out to answer?

The study aims to investigate the diversity of ribonucleotide reductase genes encoded on plasmids and explore their origins.

February 28, 2026

Plasmid-Encoded Ribonucleotide Reductases: Unveiling the Hidden Diversity

Key Points

The study aims to investigate the diversity of ribonucleotide reductase genes encoded on plasmids and explore their origins.
Analysis of plasmid pKOS1-1-3 from Citrobacter portucalensis for nrdAB genes.
Phylogenetic comparison of RNR classes in plasmid and chromosomal contexts.
Meta-analysis of RNR genes across multiple bacterial lineages and plasmids.
Identification of 5568 RNR genes across 2903 plasmids.
Discovery of 1082 RNR genes predicted to be from phage-plasmids.
Evidence suggesting that plasmid RNR genes play a crucial role in the replication of phage-plasmids.

Abstract

Ribonucleotide reductase (RNR) catalyzes the synthesis of deoxyribonucleotides by reducing the corresponding ribonucleotides. Plasmid pKOS1-1-3 from multidrug-resistant Citrobacter portucalensis strain KOS1-1 contained the nrdAB genes for class Ia RNR. The C. portucalensis chromosome encodes a phylogenetically distant class 1a RNR. Plasmid pKOS1-1-3 contained both genes responsible for its replication and maintenance, as well as the genes for bacteriophage structural proteins, suggesting that it could be a phage-plasmid hybrid. Probably, pKOS1-1-3 uses its RNRs to increase the nucleotides pool, allowing for more active replication during lytic infection. Meta-analysis revealed 5568 RNR genes on 2903 plasmids in various bacterial lineages, and 1082 of these were predicted to be phage-plasmids. We propose that plasmid RNR genes are of phage origin and could be functionally important for phage-plasmids.

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Plasmid-Encoded Ribonucleotide Reductases: Unveiling the Hidden Diversity

Key Points

Abstract

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