DNA double-strand break repair at--15{degrees}C

The survival of microorganisms in ancient glacial ice and permafrost has been ascribed to their ability to persist in a dormant, metabolically inert state. An alternative possibility, supported by experimental data, is that microorganisms in frozen matrices are able to sustain a level of metabolic f...

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Published in:Applied and Environmental Microbiology
Main Authors: Dieser, Markus, Battista, John R, Christner, Brent C
Format: Text
Language:unknown
Published: LSU Digital Commons 2013
Subjects:
Ice
permafrost
Online Access:https://digitalcommons.lsu.edu/biosci_pubs/4092
https://doi.org/10.1128/AEM.02845-13
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spelling ftlouisianastuir:oai:digitalcommons.lsu.edu:biosci_pubs-5098 2023-06-11T04:12:34+02:00 DNA double-strand break repair at--15{degrees}C Dieser, Markus Battista, John R Christner, Brent C 2013-12-01T08:00:00Z https://digitalcommons.lsu.edu/biosci_pubs/4092 https://doi.org/10.1128/AEM.02845-13 unknown LSU Digital Commons https://digitalcommons.lsu.edu/biosci_pubs/4092 doi:10.1128/AEM.02845-13 Faculty Publications text 2013 ftlouisianastuir https://doi.org/10.1128/AEM.02845-13 2023-05-28T18:51:31Z The survival of microorganisms in ancient glacial ice and permafrost has been ascribed to their ability to persist in a dormant, metabolically inert state. An alternative possibility, supported by experimental data, is that microorganisms in frozen matrices are able to sustain a level of metabolic function that is sufficient for cellular repair and maintenance. To examine this experimentally, frozen populations of Psychrobacter arcticus 273-4 were exposed to ionizing radiation (IR) to simulate the damage incurred from natural background IR sources in the permafrost environment from over ∼225 kiloyears (ky). High-molecular-weight DNA was fragmented by exposure to 450 Gy of IR, which introduced an average of 16 double-strand breaks (DSBs) per chromosome. During incubation at -15°C for 505 days, P. arcticus repaired DNA DSBs in the absence of net growth. Based on the time frame for the assembly of genomic fragments by P. arcticus, the rate of DNA DSB repair was estimated at 7 to 10 DSBs year(-1) under the conditions tested. Our results provide direct evidence for the repair of DNA lesions, extending the range of complex biochemical reactions known to occur in bacteria at frozen temperatures. Provided that sufficient energy and nutrient sources are available, a functional DNA repair mechanism would allow cells to maintain genome integrity and augment microbial survival in icy terrestrial or extraterrestrial environments. Text Ice permafrost LSU Digital Commons (Louisiana State University) Applied and Environmental Microbiology 79 24 7662 7668
institution Open Polar
collection LSU Digital Commons (Louisiana State University)
op_collection_id ftlouisianastuir
language unknown
description The survival of microorganisms in ancient glacial ice and permafrost has been ascribed to their ability to persist in a dormant, metabolically inert state. An alternative possibility, supported by experimental data, is that microorganisms in frozen matrices are able to sustain a level of metabolic function that is sufficient for cellular repair and maintenance. To examine this experimentally, frozen populations of Psychrobacter arcticus 273-4 were exposed to ionizing radiation (IR) to simulate the damage incurred from natural background IR sources in the permafrost environment from over ∼225 kiloyears (ky). High-molecular-weight DNA was fragmented by exposure to 450 Gy of IR, which introduced an average of 16 double-strand breaks (DSBs) per chromosome. During incubation at -15°C for 505 days, P. arcticus repaired DNA DSBs in the absence of net growth. Based on the time frame for the assembly of genomic fragments by P. arcticus, the rate of DNA DSB repair was estimated at 7 to 10 DSBs year(-1) under the conditions tested. Our results provide direct evidence for the repair of DNA lesions, extending the range of complex biochemical reactions known to occur in bacteria at frozen temperatures. Provided that sufficient energy and nutrient sources are available, a functional DNA repair mechanism would allow cells to maintain genome integrity and augment microbial survival in icy terrestrial or extraterrestrial environments.
format Text
author Dieser, Markus
Battista, John R
Christner, Brent C
spellingShingle Dieser, Markus
Battista, John R
Christner, Brent C
DNA double-strand break repair at--15{degrees}C
author_facet Dieser, Markus
Battista, John R
Christner, Brent C
author_sort Dieser, Markus
title DNA double-strand break repair at--15{degrees}C
title_short DNA double-strand break repair at--15{degrees}C
title_full DNA double-strand break repair at--15{degrees}C
title_fullStr DNA double-strand break repair at--15{degrees}C
title_full_unstemmed DNA double-strand break repair at--15{degrees}C
title_sort dna double-strand break repair at--15{degrees}c
publisher LSU Digital Commons
publishDate 2013
url https://digitalcommons.lsu.edu/biosci_pubs/4092
https://doi.org/10.1128/AEM.02845-13
genre Ice
permafrost
genre_facet Ice
permafrost
op_source Faculty Publications
op_relation https://digitalcommons.lsu.edu/biosci_pubs/4092
doi:10.1128/AEM.02845-13
op_doi https://doi.org/10.1128/AEM.02845-13
container_title Applied and Environmental Microbiology
container_volume 79
container_issue 24
container_start_page 7662
op_container_end_page 7668
_version_ 1768388521785032704

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