Regulation of SOS Mutagenesis by Proteolysis

DNA damage-inducible mutagenesis in Escherichia coli is largely dependent upon the activity of the UmuD (UmuD$^{\prime}$) and UmuC proteins. The intracellular level of these proteins is tightly regulated at both the transcriptional and the posttranslational levels. Such regulation presumably allows...

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Published inProceedings of the National Academy of Sciences - PNAS Vol. 93; no. 19; pp. 10291 - 10296
Main Authors Frank, Ekaterina G., Ennis, Don G., Gonzalez, Martin, Levine, Arthur S., Woodgate, Roger
Format Journal Article
LanguageEnglish
Published United States National Academy of Sciences of the United States of America 17.09.1996
National Acad Sciences
National Academy of Sciences
Subjects
Adenosine Triphosphatases - metabolism
ATPases Associated with Diverse Cellular Activities
Bacterial Proteins - biosynthesis
Bacterial Proteins - metabolism
Dimers
DNA
DNA Damage
DNA-Directed DNA Polymerase
Endopeptidase Clp
Enzymes
Escherichia coli
Escherichia coli - genetics
Escherichia coli - radiation effects
Escherichia coli Proteins
Gene expression regulation
Gene Expression Regulation, Bacterial
Genes, Bacterial
Genetic mutation
Genetics
Genotype
Molecular Chaperones
Mutagenesis
Phenotypes
Physiological regulation
Plasmids
Protein Processing, Post-Translational
Protein synthesis
Proteins
Restriction Mapping
SOS Response (Genetics)
Transcription, Genetic
Ultraviolet Rays
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Summary:DNA damage-inducible mutagenesis in Escherichia coli is largely dependent upon the activity of the UmuD (UmuD$^{\prime}$) and UmuC proteins. The intracellular level of these proteins is tightly regulated at both the transcriptional and the posttranslational levels. Such regulation presumably allows cells to deal with DNA damage via error-free repair pathways before being committed to error-prone pathways. We have recently discovered that as part of this elaborate regulation, both the UmuD and the UmuC proteins are rapidly degraded in vivo. We report here that the enzyme responsible for their degradation is the ATP-dependent serine protease, Lon. In contrast, UmuD$^{\prime}$ (the posttranslational product and mutagenically active form of UmuD) is degraded at a much reduced rate by Lon, but is instead rapidly degraded by another ATP-dependent protease, ClpXP. Interestingly, UmuD$^{\prime}$ is rapidly degraded by ClpXP only when it is in a heterodimeric complex with UmuD. Formation of UmuD/UmuD$^{\prime}$ heterodimers in preference to UmuD$^{\prime}$ homodimers therefore targets UmuD$^{\prime}$ protein for proteolysis. Such a mechanism allows cells to reduce the intracellular levels of the mutagenically active Umu proteins and thereby return to a resting state once error-prone DNA repair has occurred. The apparent half-life of the heterodimeric UmuD/D$^{\prime}$ complex is greatly increased in the clpX$::$Kan and clpP$::$Kan strains and these strains are correspondingly rendered virtually UV nonmutable. We believe that these phenotypes are consistent with the suggestion that while the UmuD/D$^{\prime}$ heterodimer is mutagenically inactive, it still retains the ability to interact with UmuC, and thereby precludes the formation of the mutagenically active UmuD$^{\prime}{}_{2}$C complex.
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ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.93.19.10291