Mutations Affecting the Ability of the
            <i>Escherichia coli</i>
            UmuD′ Protein To Participate in SOS Mutagenesis

Ohta, Toshihiro; Sutton, Mark D.; Guzzo, Angelina; Cole, Shannon H.; Ferentz, Ann E.; Walker, Graham C.

doi:10.1128/jb.181.1.177-185.1999

Cited by 33 publications

(10 citation statements)

References 38 publications

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“…2). With the exception of UmuD′ E35K, which was found in another study (Ohta et al ., 1999), they constitute a distinct set from the UmuD′ and UmuC mutations previously found to reduce the ability of the UmuD′C complex to promote SOS mutagenesis (Woodgate et al ., 1994; McLenigan et al ., 1998; Ohta et al ., 1999). Four out of the five UmuD′[Rin ++ ] amino acid changes, G25D, S28T, P29L and E35K, are located in the NH 2 ‐terminal arm of UmuD′ as defined by Peat et al .…”

Section: Resultssupporting

confidence: 54%

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Specific amino acid changes enhance the anti‐recombination activity of the UmuD′C complex

Sommer

Coste

Bailone

2000

Molecular Microbiology

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In addition to being an essential component of trans‐lesion synthesis, the UmuD′C complex is an antagonist of RecA‐mediated homologous recombination. When constitutively expressed at an elevated concentration, the UmuD′C complex sensitizes recA+ bacteria to DNA damage, whereas it has no effect on bacteria expressing a RecA [UmuR] protein that overcomes recombination inhibition. Using as a genetic screen enhanced cell killing on mitomycin plates, we isolated novel umuD′ and umuC mutations that restored mitomycin sensitivity to recA D112G [UmuR] bacteria overproducing the UmuD′C complex. The mutations were named [Rin++] because a characterization in a recA+ as well in a recA D112G background showed that they enhanced UmuD′C‐promoted recombination inhibition in two assays, conjugational recombination and recombinational repair of palindrome‐containing DNA. The [Rin++] mutations affect five amino acids, G25D, S28T, P29L, E35K, and T95R, in UmuD′ and seven, F10L, Y270C, K277E, F287L, F287S, K342Q and F351I, in UmuC. These amino acids might play a key role in the UmuD′C anti‐recombination activity. None of the [Rin++] mutations enhanced UmuD′C‐promoted mutagenic bypass of UV lesions, in contrast, several lead to a defect in this process. In this study, we discuss a few molecular mechanisms that could account for the recombination and mutagenesis phenotypes of a mutant UmuD′C [Rin++] complex.

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Section: Resultssupporting

confidence: 54%

“…Above the bars are indicated the position of the [Rin ++ ] amino acid changes described in this publication. Below the bars are indicated the position of amino acid changes previously isolated as reducing the capacity of the UmuD′C complex to promote SOS mutagenesis (Woodgate et al ., 1994; McLenigan et al ., 1998; Ohta et al ., 1999).…”

Section: Resultsmentioning

confidence: 99%

Specific amino acid changes enhance the anti‐recombination activity of the UmuD′C complex

Sommer

Coste

Bailone

2000

Molecular Microbiology

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“…Mechanistically, damaged bases and stalled replication forks are bound by RecA protein and this RecA becomes activated as a nuclease specific for several targets including the LexA repressor. Among the approximately 20 genes that are under LexA control are umu C and umu D. umu D is further processed by activated RecA and together these three proteins facilitate mutagenic synthesis (Ohta et al 1999). This mutagenic synthesis is immediately beneficial to cell survival because it allows synthesis over sites that lack normal base-pairing information.…”

Section: Developmental and Physiological Themes In Evolutionmentioning

confidence: 99%

Hereditary stability and variation in evolution and development

Thaler

1999

Evolution and Development

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SUMMARY Evolution and development are both lineage processes but are often conceptualized as occurring by different and mutually exclusive mechanisms. It is conventionally asserted that evolution occurs via the random generation of diversity and the subsequent survival of those that pass selection. On the other hand, development is too often presented as proceeding via the unfolding of a deterministic program encoded in the DNA sequence. In biology, universal generalizations are rare and dogmas are often wrong for particular cases. Deterministic mechanisms contribute some of the new DNA sequences that subsequently become substrates for natural selection. Conversely, stochastic and selective mechanisms are intrinsic to development, and also to maintenance of the immune, and possibly, nervous systems. Cancer appears to be another process that straddles distinctions between evolutionary and developmental modes of hereditary change and stabilization. DNA sequence changes are an essential feature of many cancers, but there are also aspects of the disease similar to developmental lineage gone awry. The literature suggests that the cellular changes that give rise to cancer occur by mechanisms commonly associated with both evolutionary and developmental lineage pathways.

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“…The current recognized repertoire of Escherichia coli DNA repair genes has been compiled in screens carried out over a period of nearly four decades (Clark and Margulies, 1965;Howard-Flanders, 1968;Konrad, 1977;Volkert and Nguyen, 1984;Kolodner et al, 1985;Modrich, 1987;Mahdi and Lloyd, 1989;Ohta et al, 1999). Screens to identify genes involved in radiation resistance were part of these efforts.…”

Section: Introductionmentioning

confidence: 99%

Escherichia coli radD (yejH) gene: a novel function involved in radiation resistance and double‐strand break repair

Chen

Byrne

Wood

et al. 2015

Molecular Microbiology

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Summary A transposon insertion screen implicated the yejH gene in the repair of ionizing radiation-induced damage. The yejH gene, which exhibits significant homology to the human transcription-coupled DNA repair gene XPB, is involved in the repair of double strand DNA breaks. Deletion of yejH significantly sensitized cells to agents that cause double strand breaks (ionizing radiation, UV radiation, ciprofloxacin). In addition, deletion of both yejH and radA hypersensitized the cells to ionizing radiation, UV, and ciprofloxacin damage, indicating that these two genes have complementary repair functions. The ΔyejH ΔradA double deletion also showed a substantial decline in viability following an induced double-strand DNA break, of a magnitude comparable to the defect measured when the recA, recB, recG, or priA genes are deleted. The ATPase activity and C-terminal zinc finger motif of yejH play an important role in its repair function, as targeted mutant alleles of yejH did not rescue sensitivity. We propose that yejH be re-named radD, reflecting its role in the DNA repair of radiation damage.

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Mutations Affecting the Ability of the Escherichia coli UmuD′ Protein To Participate in SOS Mutagenesis

Cited by 33 publications

References 38 publications

Specific amino acid changes enhance the anti‐recombination activity of the UmuD′C complex

Specific amino acid changes enhance the anti‐recombination activity of the UmuD′C complex

Hereditary stability and variation in evolution and development

Escherichia coli radD (yejH) gene: a novel function involved in radiation resistance and double‐strand break repair

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