Systematic identification of synthetic lethal mutations with reduced-genome Escherichia coli : synthetic genetic interactions among yoaA, xthA and holC related to survival from MMS exposure

Reduced-genome Escherichia coli strains lacking up to 38.9% of the parental chromosome have been constructed by combining large-scale chromosome deletion mutations. Functionally redundant genes involved in essential processes can be systematically identified using these reduced-genome strains. One l...

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Bibliographic Details
Published in:Genes & Genetic Systems 2016-06, Vol.91 (3), p.183-188
Main Authors: Keisuke Watanabe, Kento Tominaga, Maiko Kitamura, Jun-ichi Kato
Format: Article
Language:Japanese
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Summary:Reduced-genome Escherichia coli strains lacking up to 38.9% of the parental chromosome have been constructed by combining large-scale chromosome deletion mutations. Functionally redundant genes involved in essential processes can be systematically identified using these reduced-genome strains. One large-scale chromosome deletion mutation could be introduced into the wild-type strain but not into the largest reduced-genome strain, suggesting a synthetic lethal interaction between genes removed by the deletion and those already absent in the reduced-genome strain. Thus, introduction of the deletion mutation into a series of reduced-genome mutants could allow the identification of other chromosome deletion mutations responsible for the synthetic lethal phenotype. We identified a synthetic lethality caused by disruption of nfo and xthA, two genes encoding apurinic/apyrimidinic (AP) endonucleases involved in the DNA base excision repair pathway, and two other large-scale chromosome deletions. We constructed temperature-sensitive mutants harboring quadruple-deletion mutations in the affected genes/chromosome regions. Using these mutants, we identified two multi-copy suppressors : holC, encoding the chi subunit of DNA polymerase III, and yoaA, encoding a putative DNA helicase. Addition of the yoaA disruption increased the methyl methanesulfonate (MMS) sensitivity of xthA single-deletion or xthA nfo double-deletion mutants. This increased MMS sensitivity was not suppressed by the presence of multi-copy holC. These results indicate that yoaA is involved in MMS sensitivity and suggest that YoaA functions together with HolC.
ISSN:1341-7568