Replication Errors and Error Robustness: When Positive Complementarities Are Negative

2018 ◽  
Vol 2018 (1) ◽  
pp. 15661
Author(s):  
Dirk Martignoni
Keyword(s):  
Replication Errors ◽  
Error Robustness

scholarly journals 3′ → 5′ Exonucleases of DNA Polymerases ϵ and δ Correct Base Analog Induced DNA Replication Errors on Opposite DNA Strands in Saccharomyces cerevisiae

Genetics ◽  
1996 ◽  
Vol 142 (3) ◽  
pp. 717-726 ◽  
Author(s):  
Polina V Shcherbakova ◽  
Youri I Pavlov
Keyword(s):  
Dna Replication ◽  
Dna Polymerases ◽  
Replication Errors ◽  
Dna Strands ◽  
Base Analog ◽  
Chromosome Iii ◽  
Dna Strand ◽  
Dna Replication Errors ◽  
Yeast Mutants ◽  
Lagging Strand

Abstract The base analog 6-N-hydroxylaminopurine (HAP) induces bidirectional GC → AT and AT → GC transitions that are enhanced in DNA polymerase ϵ and δ 3′ → 5′ exonuclease-deficient yeast mutants, pol2-4 and pol3-01, respectively. We have constructed a set of isogenic strains to determine whether the DNA polymerases δ and ϵ contribute equally to proofreading of replication errors provoked by HAP during leading and lagging strand DNA synthesis. Site-specific GC → AT and AT → GC transitions in a Pol→, pol2-4 or pol3-01 genetic background were scored as reversions of ura3 missense alleles. At each site, reversion was increased in only one proofreading-deficient mutant, either pol2-4 or pol3-01, depending on the DNA strand in which HAP incorporation presumably occurred. Measurement of the HAP-induced reversion frequency of the ura3 alleles placed into chromosome III near to the defined active replication origin ARS306 in two orientations indicated that DNA polymerases ϵ and δ correct HAP-induced DNA replication errors on opposite DNA strands.

scholarly journals A systematic CRISPR screen defines mutational mechanisms underpinning signatures caused by replication errors and endogenous DNA damage

Nature Cancer ◽  
2021 ◽  
Author(s):  
Xueqing Zou ◽  
◽  
Gene Ching Chiek Koh ◽  
Arjun Scott Nanda ◽  
Andrea Degasperi ◽  
...  
Keyword(s):  
Dna Damage ◽  
Replication Errors ◽  
Crispr Screen

scholarly journals Regulation of Mitotic Homeologous Recombination in Yeast: Functions of Mismatch Repair and Nucleotide Excision Repair Genes

Genetics ◽  
2000 ◽  
Vol 154 (1) ◽  
pp. 133-146 ◽  
Author(s):  
Ainsley Nicholson ◽  
Miyono Hendrix ◽  
Sue Jinks-Robertson ◽  
Gray F Crouse
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Mismatch Repair ◽  
Nucleotide Excision Repair ◽  
Excision Repair ◽  
Mitotic Recombination ◽  
Inverted Repeats ◽  
Replication Errors ◽  
Nucleotide Excision ◽  
Homeologous Recombination ◽  
Repair Genes

Abstract The Saccharomyces cerevisiae homologs of the bacterial mismatch repair proteins MutS and MutL correct replication errors and prevent recombination between homeologous (nonidentical) sequences. Previously, we demonstrated that Msh2p, Msh3p, and Pms1p regulate recombination between 91% identical inverted repeats, and here use the same substrates to show that Mlh1p and Msh6p have important antirecombination roles. In addition, substrates containing defined types of mismatches (base-base mismatches; 1-, 4-, or 12-nt insertion/deletion loops; or 18-nt palindromes) were used to examine recognition of these mismatches in mitotic recombination intermediates. Msh2p was required for recognition of all types of mismatches, whereas Msh6p recognized only base-base mismatches and 1-nt insertion/deletion loops. Msh3p was involved in recognition of the palindrome and all loops, but also had an unexpected antirecombination role when the potential heteroduplex contained only base-base mismatches. In contrast to their similar antimutator roles, Pms1p consistently inhibited recombination to a lesser degree than did Msh2p. In addition to the yeast MutS and MutL homologs, the exonuclease Exo1p and the nucleotide excision repair proteins Rad1p and Rad10p were found to have roles in inhibiting recombination between mismatched substrates.

scholarly journals Reduced survival in patients with stage-I non-small-cell lung cancer associated with DNA-replication errors

1997 ◽  
Vol 74 (3) ◽  
pp. 330-334 ◽  
Author(s):  
Rafael Rosell ◽  
Alex Pifarré ◽  
Mariano Monzó ◽  
Julio Astudillo ◽  
M. Paz López-Cabrerizo ◽  
...  
Keyword(s):  
Lung Cancer ◽  
Dna Replication ◽  
Small Cell Lung Cancer ◽  
Cell Lung Cancer ◽  
Small Cell ◽  
Stage I ◽  
Small Cell Lung ◽  
Replication Errors ◽  
Dna Replication Errors

RNA replication errors and the evolution of virus pathogenicity and virulence

2014 ◽  
Vol 9 ◽  
pp. 143-147 ◽  
Author(s):  
Isabel S Novella ◽  
John B Presloid ◽  
R Travis Taylor
Keyword(s):  
Rna Replication ◽  
Replication Errors

Replication Errors

2001 ◽  
pp. 1676-1677
Author(s):  
B.A. Bridges
Keyword(s):  
Replication Errors

scholarly journals The “false-positive” conundrum in the NTP 2-year rodent cancer study database

2018 ◽  
Vol 2 ◽  
pp. 239784731877283 ◽  
Author(s):  
Carr J. Smith ◽  
Thomas A. Perfetti
Keyword(s):  
Mutation Rate ◽  
Ames Test ◽  
Cellular Proliferation ◽  
Tumor Site ◽  
Routes Of Administration ◽  
Replication Errors ◽  
Background Mutation Rate ◽  
High Doses ◽  
Dna Replication Errors ◽  
Rats And Mice

In 1990, Ames and Gold described a conundrum of “too many carcinogens” among chemicals tested in rodent bioassays. Their proposed nongenotoxic carcinogenic mechanism was amplification of the background mutation rate via cytotoxicity induced by high doses of the test chemicals, thereby leading to increases in reparative cellular proliferation rates. Recently, we have statistically and mechanistically analyzed the entire 594-study (470 final reports) NTP 2-year rodent cancer database to better understand the conundrum posed by Ames and Gold. Our analysis provides several lines of evidence that support the contention of Ames and Gold. First, across different routes of administration, relatively phylogenetically similar rats and mice are nonetheless discordant for the development of tumors at similar organ sites. Tumor site concordance across sex within species is higher than tumor site concordance across species. Second, many chemicals negative in the Ames test nonetheless induce tumors in either rats or mice. Third, 11 out of 58 chemicals tested by the inhalation route induce lung tumors in mice and not rats, are negative in the Ames test, and exhibit hyperplasia. In 2017, Tomasetti et al. provided evidence for the clinical relevance in humans of the Ames and Gold mechanism regarding amplification of the background mutation rate by demonstrating that the majority of human tumors result from accumulated mutations due to DNA replication errors.

Established and Novel Mechanisms Leading to de novo Genomic Rearrangements in the Human Germline

2020 ◽  
Vol 160 (4) ◽  
pp. 167-176 ◽  
Author(s):  
Atsushi Hattori ◽  
Maki Fukami
Keyword(s):  
Structural Changes ◽  
De Novo ◽  
Time Window ◽  
Review Article ◽  
Early Embryogenesis ◽  
Genomic Rearrangements ◽  
Dna Breaks ◽  
Replication Errors ◽  
Double Strand Dna Breaks ◽  
Nonallelic Homologous Recombination

During gametogenesis, the human genome can acquire various de novo rearrangements. Most constitutional genomic rearrangements are created through 1 of the 4 well-known mechanisms, i.e., nonallelic homologous recombination, erroneous repair after double-strand DNA breaks, replication errors, and retrotransposition. However, recent studies have identified 2 types of extremely complex rearrangements that cannot be simply explained by these mechanisms. The first type consists of chaotic structural changes in 1 or a few chromosomes that result from “chromoanagenesis (an umbrella term that covers chromothripsis, chromoanasynthesis, and chromoplexy).” The other type is large independent rearrangements in multiple chromosomes indicative of “transient multifocal genomic crisis.” Germline chromoanagenesis (chromothripsis) likely occurs predominantly during spermatogenesis or postzygotic embryogenesis, while multifocal genomic crisis appears to be limited to a specific time window during oogenesis and early embryogenesis or during spermatogenesis. This review article introduces the current understanding of the molecular basis of de novo rearrangements in the germline.

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