2017
DOI: 10.1074/jbc.m116.758599
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Direct Visualization of RNA-DNA Primer Removal from Okazaki Fragments Provides Support for Flap Cleavage and Exonucleolytic Pathways in Eukaryotic Cells

Abstract: Edited by Patrick SungDuring DNA replication in eukaryotic cells, short singlestranded DNA segments known as Okazaki fragments are first synthesized on the lagging strand. The Okazaki fragments originate from ϳ35-nucleotide-long RNA-DNA primers. After Okazaki fragment synthesis, these primers must be removed to allow fragment joining into a continuous lagging strand. To date, the models of enzymatic machinery that removes the RNA-DNA primers have come almost exclusively from biochemical reconstitution studies … Show more

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Cited by 45 publications
(52 citation statements)
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“…In the wt strain, median expansion size corresponded to 47 triplets49. The rad27 knockout was different: median expansion size was 32 repeats, and Kolmogorov-Smirnov (KS) comparison confirms a significant difference from the wt strain ( P <0.001), which agrees with known flap size in FEN1 knockouts54. The expansion scale in near-catalytic-dead (D179A) and 4E Rad27 mutants lies between the wt and knockout mutant: the median is 40 repeats and KS shows significant difference from wt ( P <0.05).…”
Section: Resultssupporting
confidence: 70%
“…In the wt strain, median expansion size corresponded to 47 triplets49. The rad27 knockout was different: median expansion size was 32 repeats, and Kolmogorov-Smirnov (KS) comparison confirms a significant difference from the wt strain ( P <0.001), which agrees with known flap size in FEN1 knockouts54. The expansion scale in near-catalytic-dead (D179A) and 4E Rad27 mutants lies between the wt and knockout mutant: the median is 40 repeats and KS shows significant difference from wt ( P <0.05).…”
Section: Resultssupporting
confidence: 70%
“…However, the same mutations also increase repeat contraction rates (183, 289, 307, 309, 310, 312-314, 316 -318), a phenomenon that cannot be explained by the flap incorporation model. A more general model suggests that in the absence of fully functional Rad27 or Dna2, the genomewide accumulation of long ssDNA species (314,320,321), such as flaps or gaps, titrates the ssDNA-binding protein replication protein A (RPA) from the repetitive regions (322). Due to the lack of RPA, transiently formed ssDNA within the repetitive tracts is likely to equilibrate into DNA secondary structures, which trigger repeat instability ( Fig.…”
Section: Role Of Okazaki Fragment Processing In Repeat Instabilitymentioning
confidence: 99%
“…Dna2 or Rad27) is required for cells to progress 234 through S-phase. We reasoned that the requirement for endonucleolytic Okazaki fragment flap 235 processing during S-phase could arise from the accumulation of a small number of long, 236 unprocessed flaps that might persist in CLB2-RAD27 CLB2-DNA2 cells (Liu et al, 2017). These 237 long flaps could deplete cellular RPA pools, leading to checkpoint-mediated cell cycle arrest 238 (Byun et al, 2005) and/or catastrophic failure of replication (Toledo et al, 2013).…”
Section: Ypd Ypgalmentioning
confidence: 99%