A Chemical Genetics Analysis of the Roles of Bypass Polymerase DinB and DNA Repair Protein AlkB in Processing N (2)-Alkylguanine Lesions In Vivo

DinB, the E. coli translesion synthesis polymerase, has been shown to bypass several N (2)-alkylguanine adducts in vitro, including N (2)-furfurylguanine, the structural analog of the DNA adduct formed by the antibacterial agent nitrofurazone. Recently, it was demonstrated that the Fe(II)- and α-ket...

Descripción completa

Detalles Bibliográficos
Autores principales: Shrivastav, Nidhi, Fedeles, Bogdan I., Li, Deyu, Delaney, James C., Frick, Lauren E., Foti, James J., Walker, Graham C., Essigmann, John M.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2014
Materias:
Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3986394/
https://www.ncbi.nlm.nih.gov/pubmed/24733044
http://dx.doi.org/10.1371/journal.pone.0094716
_version_ 1782311701760180224
author Shrivastav, Nidhi
Fedeles, Bogdan I.
Li, Deyu
Delaney, James C.
Frick, Lauren E.
Foti, James J.
Walker, Graham C.
Essigmann, John M.
author_facet Shrivastav, Nidhi
Fedeles, Bogdan I.
Li, Deyu
Delaney, James C.
Frick, Lauren E.
Foti, James J.
Walker, Graham C.
Essigmann, John M.
author_sort Shrivastav, Nidhi
collection PubMed
description DinB, the E. coli translesion synthesis polymerase, has been shown to bypass several N (2)-alkylguanine adducts in vitro, including N (2)-furfurylguanine, the structural analog of the DNA adduct formed by the antibacterial agent nitrofurazone. Recently, it was demonstrated that the Fe(II)- and α-ketoglutarate-dependent dioxygenase AlkB, a DNA repair enzyme, can dealkylate in vitro a series of N (2)-alkyguanines, including N (2)-furfurylguanine. The present study explored, head to head, the in vivo relative contributions of these two DNA maintenance pathways (replicative bypass vs. repair) as they processed a series of structurally varied, biologically relevant N (2)-alkylguanine lesions: N (2)-furfurylguanine (FF), 2-tetrahydrofuran-2-yl-methylguanine (HF), 2-methylguanine, and 2-ethylguanine. Each lesion was chemically synthesized and incorporated site-specifically into an M13 bacteriophage genome, which was then replicated in E. coli cells deficient or proficient for DinB and AlkB (4 strains in total). Biochemical tools were employed to analyze the relative replication efficiencies of the phage (a measure of the bypass efficiency of each lesion) and the base composition at the lesion site after replication (a measure of the mutagenesis profile of each lesion). The main findings were: 1) Among the lesions studied, the bulky FF and HF lesions proved to be strong replication blocks when introduced site-specifically on a single-stranded vector in DinB deficient cells. This toxic effect disappeared in the strains expressing physiological levels of DinB. 2) AlkB is known to repair N (2)-alkylguanine lesions in vitro; however, the presence of AlkB showed no relief from the replication blocks induced by FF and HF in vivo. 3) The mutagenic properties of the entire series of N (2)-alkyguanines adducts were investigated in vivo for the first time. None of the adducts were mutagenic under the conditions evaluated, regardless of the DinB or AlkB cellular status. Taken together, the data indicated that the cellular pathway to combat bulky N (2)-alkylguanine DNA adducts was DinB-dependent lesion bypass.
format Online
Article
Text
id pubmed-3986394
institution National Center for Biotechnology Information
language English
publishDate 2014
publisher Public Library of Science
record_format MEDLINE/PubMed
spelling pubmed-39863942014-04-15 A Chemical Genetics Analysis of the Roles of Bypass Polymerase DinB and DNA Repair Protein AlkB in Processing N (2)-Alkylguanine Lesions In Vivo Shrivastav, Nidhi Fedeles, Bogdan I. Li, Deyu Delaney, James C. Frick, Lauren E. Foti, James J. Walker, Graham C. Essigmann, John M. PLoS One Research Article DinB, the E. coli translesion synthesis polymerase, has been shown to bypass several N (2)-alkylguanine adducts in vitro, including N (2)-furfurylguanine, the structural analog of the DNA adduct formed by the antibacterial agent nitrofurazone. Recently, it was demonstrated that the Fe(II)- and α-ketoglutarate-dependent dioxygenase AlkB, a DNA repair enzyme, can dealkylate in vitro a series of N (2)-alkyguanines, including N (2)-furfurylguanine. The present study explored, head to head, the in vivo relative contributions of these two DNA maintenance pathways (replicative bypass vs. repair) as they processed a series of structurally varied, biologically relevant N (2)-alkylguanine lesions: N (2)-furfurylguanine (FF), 2-tetrahydrofuran-2-yl-methylguanine (HF), 2-methylguanine, and 2-ethylguanine. Each lesion was chemically synthesized and incorporated site-specifically into an M13 bacteriophage genome, which was then replicated in E. coli cells deficient or proficient for DinB and AlkB (4 strains in total). Biochemical tools were employed to analyze the relative replication efficiencies of the phage (a measure of the bypass efficiency of each lesion) and the base composition at the lesion site after replication (a measure of the mutagenesis profile of each lesion). The main findings were: 1) Among the lesions studied, the bulky FF and HF lesions proved to be strong replication blocks when introduced site-specifically on a single-stranded vector in DinB deficient cells. This toxic effect disappeared in the strains expressing physiological levels of DinB. 2) AlkB is known to repair N (2)-alkylguanine lesions in vitro; however, the presence of AlkB showed no relief from the replication blocks induced by FF and HF in vivo. 3) The mutagenic properties of the entire series of N (2)-alkyguanines adducts were investigated in vivo for the first time. None of the adducts were mutagenic under the conditions evaluated, regardless of the DinB or AlkB cellular status. Taken together, the data indicated that the cellular pathway to combat bulky N (2)-alkylguanine DNA adducts was DinB-dependent lesion bypass. Public Library of Science 2014-04-14 /pmc/articles/PMC3986394/ /pubmed/24733044 http://dx.doi.org/10.1371/journal.pone.0094716 Text en © 2014 Shrivastav et al http://creativecommons.org/licenses/by/4.0/ This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are properly credited.
spellingShingle Research Article
Shrivastav, Nidhi
Fedeles, Bogdan I.
Li, Deyu
Delaney, James C.
Frick, Lauren E.
Foti, James J.
Walker, Graham C.
Essigmann, John M.
A Chemical Genetics Analysis of the Roles of Bypass Polymerase DinB and DNA Repair Protein AlkB in Processing N (2)-Alkylguanine Lesions In Vivo
title A Chemical Genetics Analysis of the Roles of Bypass Polymerase DinB and DNA Repair Protein AlkB in Processing N (2)-Alkylguanine Lesions In Vivo
title_full A Chemical Genetics Analysis of the Roles of Bypass Polymerase DinB and DNA Repair Protein AlkB in Processing N (2)-Alkylguanine Lesions In Vivo
title_fullStr A Chemical Genetics Analysis of the Roles of Bypass Polymerase DinB and DNA Repair Protein AlkB in Processing N (2)-Alkylguanine Lesions In Vivo
title_full_unstemmed A Chemical Genetics Analysis of the Roles of Bypass Polymerase DinB and DNA Repair Protein AlkB in Processing N (2)-Alkylguanine Lesions In Vivo
title_short A Chemical Genetics Analysis of the Roles of Bypass Polymerase DinB and DNA Repair Protein AlkB in Processing N (2)-Alkylguanine Lesions In Vivo
title_sort chemical genetics analysis of the roles of bypass polymerase dinb and dna repair protein alkb in processing n (2)-alkylguanine lesions in vivo
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3986394/
https://www.ncbi.nlm.nih.gov/pubmed/24733044
http://dx.doi.org/10.1371/journal.pone.0094716
work_keys_str_mv AT shrivastavnidhi achemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo
AT fedelesbogdani achemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo
AT lideyu achemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo
AT delaneyjamesc achemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo
AT fricklaurene achemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo
AT fotijamesj achemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo
AT walkergrahamc achemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo
AT essigmannjohnm achemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo
AT shrivastavnidhi chemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo
AT fedelesbogdani chemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo
AT lideyu chemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo
AT delaneyjamesc chemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo
AT fricklaurene chemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo
AT fotijamesj chemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo
AT walkergrahamc chemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo
AT essigmannjohnm chemicalgeneticsanalysisoftherolesofbypasspolymerasedinbanddnarepairproteinalkbinprocessingn2alkylguaninelesionsinvivo

Ejemplares similares