Ryan L. Frisch scite author profile

Mechanisms of DNA repair and mutagenesis are defined on the basis of relatively few proteins acting on DNA, yet the identities and functions of all proteins required are unknown. Here, we identify the network that underlies mutagenic repair of DNA breaks in stressed Escherichia coli and define functions for much of it. Using a comprehensive screen, we identified a network of ≥93 genes that function in mutation. Most operate upstream of activation of three required stress responses (RpoS, RpoE, and SOS, key network hubs), apparently sensing stress. The results reveal how a network integrates mutagenic repair into the biology of the cell, show specific pathways of environmental sensing, demonstrate the centrality of stress responses, and imply that these responses are attractive as potential drug targets for blocking the evolution of pathogens.

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Engineered proteins detect spontaneous DNA breakage in human and bacterial cells

Shee

Cox

et al. 2013

118

177

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Spontaneous DNA breaks instigate genomic changes that fuel cancer and evolution, yet direct quantification of double-strand breaks (DSBs) has been limited. Predominant sources of spontaneous DSBs remain elusive. We report synthetic technology for quantifying DSBs using fluorescent-protein fusions of double-strand DNA end-binding protein, Gam of bacteriophage Mu. In Escherichia coli GamGFP forms foci at chromosomal DSBs and pinpoints their subgenomic locations. Spontaneous DSBs occur mostly one per cell, and correspond with generations, supporting replicative models for spontaneous breakage, and providing the first true breakage rates. In mammalian cells GamGFP—labels laser-induced DSBs antagonized by end-binding protein Ku; co-localizes incompletely with DSB marker 53BP1 suggesting superior DSB-specificity; blocks resection; and demonstrates DNA breakage via APOBEC3A cytosine deaminase. We demonstrate directly that some spontaneous DSBs occur outside of S phase. The data illuminate spontaneous DNA breakage in E. coli and human cells and illustrate the versatility of fluorescent-Gam for interrogation of DSBs in living cells.DOI: http://dx.doi.org/10.7554/eLife.01222.001

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Stress‐induced mutation via DNA breaks in Escherichia coli: A molecular mechanism with implications for evolution and medicine

et al. 2012

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Evolutionary theory assumed that mutations occur constantly, gradually, and randomly over time. This formulation from the “modern synthesis” of the 1930s was embraced decades before molecular understanding of genes or mutations. Since then, our labs and others have elucidated mutation mechanisms activated by stress responses. Stress-induced mutation mechanisms produce mutations, potentially accelerating evolution, specifically when cells are maladapted to their environment, that is, when they are stressed. The mechanisms of stress-induced mutation that are being revealed experimentally in laboratory settings provide compelling models for mutagenesis that propels pathogen–host adaptation, antibiotic resistance, cancer progression and resistance, and perhaps much of evolution generally. We discuss double-strand-break-dependent stress-induced mutation in Escherichia coli. Recent results illustrate how a stress response activates mutagenesis and demonstrate this mechanism's generality and importance to spontaneous mutation. New data also suggest a possible harmony between previous, apparently opposed, models for the molecular mechanism. They additionally strengthen the case for anti-evolvability therapeutics for infectious disease and cancer.

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The NAD⁺-dependent Sir2p histone deacetylase is a negative regulator of chromosomal DNA replication

Pappas¹,

Frisch²,

Weinreich³

2004

Genes Dev.

105

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The establishment of DNA synthesis during the S phase is a multistep process that occurs in several stages beginning in late mitosis. The first step is the formation of a large prereplicative complex (pre-RC) at individual replication origins and occurs during exit from mitosis and entry into G1 phase. To better understand the genetic requirements for pre-RC formation, we selected chromosomal suppressors of a temperature-sensitive cdc6-4 mutant defective for pre-RC assembly. Loss-of-function mutations in the chromatin-modifying genes SIR2, and to a lesser extent in SIR3 and SIR4, suppressed the cdc6-4 temperature-sensitive lethality. This suppression was independent of the well-known silencing roles for the SIR proteins at the HM loci, at telomeres, or at the rDNA locus. A deletion of SIR2 uniquely rescued both the DNA synthesis defect of the cdc6-4 mutant and its severe plasmid instability phenotype for many origins. A SIR2 deletion suppressed additional initiation mutants affecting pre-RC assembly but not mutants that act subsequently. These findings suggest that Sir2p negatively regulates the initiation of DNA replication through a novel mechanism and reveal another connection between proteins that initiate DNA synthesis and those that establish silent heterochromatin in budding yeast.[Keywords: DNA replication; SIR2; deacetylase] Supplemental material is available at http://www.genesdev.org.

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Ryan L. Frisch

Identity and Function of a Large Gene Network Underlying Mutagenic Repair of DNA Breaks

Engineered proteins detect spontaneous DNA breakage in human and bacterial cells

Stress‐induced mutation via DNA breaks in Escherichia coli: A molecular mechanism with implications for evolution and medicine

The NAD⁺-dependent Sir2p histone deacetylase is a negative regulator of chromosomal DNA replication

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Ryan L. Frisch

Identity and Function of a Large Gene Network Underlying Mutagenic Repair of DNA Breaks

Engineered proteins detect spontaneous DNA breakage in human and bacterial cells

Stress‐induced mutation via DNA breaks in Escherichia coli: A molecular mechanism with implications for evolution and medicine

The NAD+-dependent Sir2p histone deacetylase is a negative regulator of chromosomal DNA replication

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The NAD⁺-dependent Sir2p histone deacetylase is a negative regulator of chromosomal DNA replication