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Molecular Mechanisms for Repair of DNA

Overview of attention for book
Cover of 'Molecular Mechanisms for Repair of DNA'

Table of Contents

  1. Altmetric Badge
    Book Overview
  2. Altmetric Badge
    Chapter 1 Repairable Damage in DNA: Overview
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    Chapter 2 The Nature of the Alkylation Lesion in Mammalian Cells
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    Chapter 3 “Excision” of Bases from DNA Methylated by Carcinogens in Vivo and Its Possible Significance in Mutagenesis and Carcinogenesis
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    Chapter 4 Alkali-Labile Lesions in DNA from Cells Treated with Methylating Agents, 4-Nitroquinoline-N-oxide, or Ultraviolet Light
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    Chapter 5 Apurinic and Apyrimidinic Sites in DNA
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    Chapter 6 Maintenance of DNA and Repair of Apurinic Sites
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    Chapter 7 DNA Turnover and Strand Breaks in Escherichia coli
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    Chapter 8 Excision-Repair of γ-Ray-Damaged Thymine in Bacterial and Mammalian Systems
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    Chapter 9 Formation of Dimers in Ultraviolet-Irradiated DNA
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    Chapter 10 An Enzymatic Assay for Pyrimidine Dimers in DNA
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    Chapter 11 Enzymatic Photoreactivation: Overview
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    Chapter 12 Kinetics of Photoreactivation
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    Chapter 13 Purifying the Escherichia coli Photoreactivating Enzyme
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    Chapter 14 The Human Leukocyte Photoreactivating Enzyme
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    Chapter 15 Photorepair of RNA
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    Chapter 16 Dark Repair in Bacteriophage Systems: Overview
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    Chapter 17 Enzymic Mechanism of Excision-Repair in T4-Infected Cells
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    Chapter 18 The Repair of Ultraviolet Damage by Phage T4: The Role of the Early Phage Genes
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    Chapter 19 Repair of Heteroduplex DNA in Bacteriophage T4
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    Chapter 20 Recovery of Phage λ from Ultraviolet Damage
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    Chapter 21 Enzymology of Excision-Repair in Bacteria: Overview
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    Chapter 22 The Escherichia coli UV Endonuclease (Correndonuclease II)
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    Chapter 23 Endonuclease II of Escherichia coli
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    Chapter 24 Endonuclease III: An Endonuclease from Escherichia coli That Introduces Single Polynucleotide Chain Scissions in Ultraviolet-Irradiated DNA
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    Chapter 25 An Escherichia coli Endonuclease Which Acts on X-Irradiated DNA
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    Chapter 26 Substrate Specificity of Micrococcus luteus UV Endonuclease and Its Overlap with DNA Photolyase Activity
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    Chapter 27 Two Temperature-Sensitive polA Mutants: An Approach to the Role in Vivo of DNA Polymerase I
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    Chapter 28 The Role of DNA Polymerase I in Excision-Repair
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    Chapter 29 Involvement of Escherichia coli DNA Polymerase-I-Associated 5′→3′ Exonuclease in Excision-Repair of UV-Damaged DNA
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    Chapter 30 Exonuclease VII of Escherichia coli
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    Chapter 31 Enzymatic Repair of UV-Irradiated DNA in Vitro
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    Chapter 32 Repair Replication in Permeabilized Escherichia Coli
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    Chapter 33 Requirement for uvrAB Function for Postirradiation DNA Synthesis in Vitro
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    Chapter 34 DNA Polymerase II-Dependent DNA Synthesis in Toluenized Bacillus subtilis Cells
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    Chapter 35 Repair by Genetic Recombination in Bacteria: Overview
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    Chapter 36 Genetic Exchanges Induced by Structural Damage in Nonreplicating Phage λ DNA
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    Chapter 37 The Beginning of an Investigation of the Role of recF in the Pathways of Metabolism of Ultraviolet-Irradiated DNA in Escherichia coli
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    Chapter 38 The Degradation of Duplex DNA by the recBC DNase of Escherichia coli
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    Chapter 39 Analysis of Temperature-Sensitive recB and recC Mutations
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    Chapter 40 Recombination and Postreplication Repair
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    Chapter 41 Ultraviolet-Light-Induced Incorporation of Bromodeoxyuridine into Parental DNA of an Excision-Defective Mutant of Escherichia coli
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    Chapter 42 Distribution of Pyrimidine Dimers During Postreplication Repair in UV-Irradiated Excision-Deficient Cells of Escherichia coli K12
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    Chapter 43 Experiments on the Filling of Daughter-Strand Gaps During Postreplication Repair
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    Chapter 44 Postreplication Repair Gap Filling in an Escherichia coli Strain Deficient in dnaB Gene Product
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    Chapter 45 Involvement of uvrD, exrA, and recB Genes in the Control of the Postreplicational Repair Process
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    Chapter 46 Replication and Expression of Constructed Plasmid Chimeras in Transformed Escherichia coli—A Review
  48. Altmetric Badge
    Chapter 47 Relationships Among Repair, Mutagenesis, and Survival: Overview
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    Chapter 48 SOS repair hypothesis: phenomenology of an inducible DNA repair which is accompanied by mutagenesis.
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    Chapter 49 Thermal Enhancement of Ultraviolet Mutability in a dnaB uvrA Derivative of Escherichia coli B/r: Evidence for Inducible Error-Prone Repair
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    Chapter 50 lexB: A New Gene Governing Radiation Sensitivity and Lysogenic Induction in Escherichia coli K12
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    Chapter 51 Indirect Suppression of Radiation Sensitivity of a recA − Strain of Escherichia coli K12
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    Chapter 52 The Two-Lesion Hypothesis for UV-Induced Mutation in Relation to Recovery of Capacity for DNA Replication
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    Chapter 53 The Effect of Genes Controlling Radiation Sensitivity on Chemical Mutagenesis in Yeast
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    Chapter 54 Influence of Repair on the Specificity of Ultraviolet-Induced Reversion of an Ochre Allele of the Structural Gene for Iso-1- cytochrome c
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    Chapter 55 The Role of DNA Polymerase I in Genetic Recombination and Viability of Escherichia coli
  57. Altmetric Badge
    Chapter 56 The Role of the rec Genes in the Viability of Escherichia coli K12
Attention for Chapter 48: SOS repair hypothesis: phenomenology of an inducible DNA repair which is accompanied by mutagenesis.
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About this Attention Score

  • In the top 25% of all research outputs scored by Altmetric
  • High Attention Score compared to outputs of the same age (97th percentile)

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Chapter title
SOS repair hypothesis: phenomenology of an inducible DNA repair which is accompanied by mutagenesis.
Chapter number 48
Book title
Molecular Mechanisms for Repair of DNA
Published in
Basic life sciences, January 1975
DOI 10.1007/978-1-4684-2895-7_48
Pubmed ID
1103845
Book ISBNs
978-1-4684-2897-1, 978-1-4684-2895-7
Authors

M Radman, Miroslav Radman, Radman, Miroslav

Abstract

A hypothesis was proposed several years ago that Escherichia coli posses an inducible DNA repair system ("SOS repair") which is also responsible for induced mutagenesis. Some characteristics of the SOS repair are (1) it is induced or activated following damage to DNA, (2) it requires do novo protein synthesis, (3) It requires several genetic functions of which the best-studied are recA+ and lex+ of E. coli, and (4) the physiological and genetic requirements for the expression of SOS repair are suspiciously similar to those necessary for the prophage induction. The SOS repair hypothesis has already served as the working hypothesis for many experiments, some of which are briefly reviewed. Also, some speculations are presented to stimulate further discussions and experimental tests.

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X Demographics

X Demographics

The data shown below were collected from the profile of 1 X user who shared this research output. Click here to find out more about how the information was compiled.
 Mendeley readers

Mendeley readers

The data shown below were compiled from readership statistics for 190 Mendeley readers of this research output. Click here to see the associated Mendeley record.

Geographical breakdown

Country Count As %
United Kingdom 2 1%
Chile 1 <1%
Australia 1 <1%
France 1 <1%
India 1 <1%
Denmark 1 <1%
Unknown 183 96%

Demographic breakdown

Readers by professional status Count As %
Student > Ph. D. Student 36 19%
Student > Master 31 16%
Student > Bachelor 29 15%
Researcher 19 10%
Student > Doctoral Student 10 5%
Other 26 14%
Unknown 39 21%
Readers by discipline Count As %
Biochemistry, Genetics and Molecular Biology 62 33%
Agricultural and Biological Sciences 45 24%
Immunology and Microbiology 15 8%
Medicine and Dentistry 6 3%
Chemistry 5 3%
Other 12 6%
Unknown 45 24%
Attention Score in Context

Attention Score in Context

This research output has an Altmetric Attention Score of 12. This is our high-level measure of the quality and quantity of online attention that it has received. This Attention Score, as well as the ranking and number of research outputs shown below, was calculated when the research output was last mentioned on 28 July 2023.
All research outputs
#2,677,483
of 22,783,848 outputs
Outputs from Basic life sciences
#1
of 18 outputs
Outputs of similar age
#427
of 20,043 outputs
Outputs of similar age from Basic life sciences
#1
of 2 outputs
Altmetric has tracked 22,783,848 research outputs across all sources so far. Compared to these this one has done well and is in the 88th percentile: it's in the top 25% of all research outputs ever tracked by Altmetric.
So far Altmetric has tracked 18 research outputs from this source. They receive a mean Attention Score of 2.6. This one scored the same or higher as 17 of them.
Older research outputs will score higher simply because they've had more time to accumulate mentions. To account for age we can compare this Altmetric Attention Score to the 20,043 tracked outputs that were published within six weeks on either side of this one in any source. This one has done particularly well, scoring higher than 97% of its contemporaries.
We're also able to compare this research output to 2 others from the same source and published within six weeks on either side of this one. This one has scored higher than all of them

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