The scientific revolution that unraveled the astonishing DNA repair capacity of the Deinococcaceae : 40 years on

The family exhibits exceptional radiation resistance and possesses all the necessary traits for surviving in radiation-exposed environments. Their survival strategy involves the coupling of metabolic and DNA repair functions, resulting in an extraordinarily efficient homologous repair of DNA double-...

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Bibliographic Details
Published inCanadian journal of microbiology Vol. 69; no. 10; pp. 369 - 386
Main Author Daly, Michael J
Format Journal Article
LanguageEnglish
Published Canada NRC Research Press 01.10.2023
Canadian Science Publishing NRC Research Press
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Summary:The family exhibits exceptional radiation resistance and possesses all the necessary traits for surviving in radiation-exposed environments. Their survival strategy involves the coupling of metabolic and DNA repair functions, resulting in an extraordinarily efficient homologous repair of DNA double-strand breaks (DSBs) caused by radiation or desiccation. The keys to their survival lie in the hyperaccumulation of manganous (Mn )-metabolite antioxidants that protect their DNA repair proteins under extreme oxidative stress and the persistent structural linkage by Holliday junctions of their multiple genome copies per cell that facilitates DSB repair. This coupling of metabolic and DNA repair functions has made polyploid bacteria a useful tool in environmental biotechnology, radiobiology, aging, and planetary protection. The review highlights the groundbreaking contributions of the late Robert G.E. Murray to the field of research and the emergent paradigm-shifting discoveries that revolutionized our understanding of radiation survivability and oxidative stress defense, demonstrating that the proteome, rather than the genome, is the primary target responsible for survivability. These discoveries have led to the commercial development of irradiated vaccines using Mn-peptide antioxidants and have significant implications for various fields.
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ISSN:0008-4166
1480-3275
DOI:10.1139/cjm-2023-0059